etr-5000 eaton transformer relay

ETR-5000 EATON TRANSFORMER RELAYInstruction Manual for Installing, Operating, and Maintaining the ETR-5000

IM02602013E Rev. NEW

IM02602013E ETR-5000

Application Overview

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ETR-5000

Typical Single Line Diagram

Winding Side 2 Winding Side 1

IRIGSNTP

URTD Assembly

50PW1

51PW1

50XW1

51XW1

49

67P

67XW1

67R

87GD

87

59M

27M

27A

46W1

47

81

32

50RW1

51RW1

87H

87GDH

51QW1

50BFW1

TCMW1

ZIW1

ExtOilTemp

ExtTemp

1-3

RTD

SP

Ext DI

SOTFCLPU

BWW2

BWW1

Control52W1

Control52W2

24

TCMW2

50PW2

51PW2

46W2

50RW2

51RW2

51QW2

50BFW2

ZIW2

59A

Recorders

WaveformEventFaultTrend

Programmable Logic

Ext Prot 1-4

LOP

Phase VTs and Ground VT connection can be made to either side of the transformer.

standardOption

Metering, Statistics and DemandCurrent and Volt.:

Unbalance, %THD and THDFund. and RMS, min./max./avg.

phasors and angles, Thermal Replica, Differential, Energy,

Power: Fund. and RMSMVA, Mwatt, Mvar, PF

Analog Inputs and Outputs

IH2W1

IH2W1

ETR-5000 IM02602013E

Key Features, Functions, and Benefits.........................................................................................8General Description......................................................................................................................................... 8Features........................................................................................................................................................... 9

Comments on the Manual.............................................................................................................12What Is Included with the Device................................................................................................................... 16Storage.......................................................................................................................................................... 16Important Information .................................................................................................................................... 16Symbols......................................................................................................................................................... 17General Conventions..................................................................................................................................... 22

Installation and Wiring..................................................................................................................23Three-Side-View............................................................................................................................................ 23Overview of Slots - Assembly Groups............................................................................................................24

Device............................................................................................................................................. 26Device Planning............................................................................................................................................. 26Device Planning Parameters of the Device....................................................................................................26Slot X1: Power Supply Card with Digital Inputs..............................................................................................29Slot X2: Relay Output Card - Zone Interlock..................................................................................................32Slot X3: CT W1- Current Transformer Measuring Inputs...............................................................................34Slot X4: CT W2 - Current Transformer Measuring Inputs..............................................................................35Slot X5: Multi-Input Output-Card.................................................................................................................... 43Slot X6: Voltage Transformer Measuring Inputs.............................................................................................48Slot X100: Ethernet Interface......................................................................................................................... 54Slot X101: URTD Interface............................................................................................................................. 55Slot X103: Data Communication.................................................................................................................... 56Slot X104: IRIG-B00X and Supervision Contact............................................................................................60X120 - PC Interface....................................................................................................................................... 61

Input, Output, and LED Settings..................................................................................................64Digital Input Configuration.............................................................................................................................. 64DI-8P X.......................................................................................................................................................... 65Wired Inputs (Aliases).................................................................................................................................... 67Relay Output Contact Configuration...............................................................................................................71RO-4ZI X - Settings........................................................................................................................................ 74RO-4 X Settings............................................................................................................................................. 88Analog Outputs.............................................................................................................................................. 97Analog Inputs............................................................................................................................................... 100LED Configuration........................................................................................................................................ 111The »System OK (Operational) « LED.........................................................................................................114LED Settings................................................................................................................................................ 114

Front Panel..................................................................................................................................127Basic Menu Control...................................................................................................................................... 132PowerPort-E Keyboard Commands.............................................................................................................133

PowerPort-E.................................................................................................................................135Installation of PowerPort-E........................................................................................................................... 135Uninstalling PowerPort-E............................................................................................................................. 135Setting Up the Serial Connection PC - Device.............................................................................................136Loading of Device Data When Using PowerPort-E......................................................................................147Restoring Device Data When Using PowerPort-E........................................................................................147Backup and Documentation When Using PowerPort-E...............................................................................148Off-line Device Planning Via PowerPort-E...................................................................................................149

Signal Sources............................................................................................................................150Measuring Values........................................................................................................................153

Read Out Measured Values......................................................................................................................... 153Current - Measured Values.......................................................................................................................... 154Differential Current - Measured Values........................................................................................................157Voltage - Measured Values.......................................................................................................................... 157Power - Measured Values............................................................................................................................ 160

Energy Counter...........................................................................................................................161Global Parameters of the Energy Counter Module.......................................................................................161Direct Commands of the Energy Counter Module........................................................................................161Signals of the Energy Counter Module (States of the Outputs)....................................................................161

Statistics......................................................................................................................................163

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IM02602013E ETR-5000

Read Out Statistics...................................................................................................................................... 163Statistics (Configuration).............................................................................................................................. 163Direct Commands........................................................................................................................................ 164Global Protection Parameters of the Statistics Module................................................................................164States of the Inputs of the Statistics Module................................................................................................166Signals of the Statistics Module................................................................................................................... 167Counters of the Module Statistics................................................................................................................. 167Standard Statistic Values............................................................................................................................. 167

System Alarms.............................................................................................................................174Demand Management................................................................................................................................. 174Peak Demand.............................................................................................................................................. 176Min. and Max. Values................................................................................................................................... 176THD Protection............................................................................................................................................ 176Device Planning Parameters of the Demand Management.........................................................................176Signals of the Demand Management (States of the Outputs)......................................................................176Global Protection Parameter of the Demand Management..........................................................................177States of the Inputs of the Demand Management........................................................................................179

Resets.......................................................................................................................................... 180Manual Acknowledgment............................................................................................................................. 181Manual Acknowledgment Via PowerPort-E..................................................................................................181External Acknowledgments.......................................................................................................................... 181External Acknowledge Via PowerPort-E.......................................................................................................182External LED - Acknowledgment Signals.....................................................................................................182Manual Resets............................................................................................................................................. 191Manual Resets Via PowerPort-E.................................................................................................................. 191Reset to Factory Defaults............................................................................................................................. 191

Status Display..............................................................................................................................193Status Display Via PowerPort E................................................................................................................... 193

Operating Panel (HMI).................................................................................................................194Special Parameters of the Panel.................................................................................................................. 194Direct Commands of the Panel.................................................................................................................... 194Global Protection Parameters of the Panel..................................................................................................194

Recorders....................................................................................................................................195Waveform Recorder..................................................................................................................................... 195Fault Recorder............................................................................................................................................. 202Event Recorder............................................................................................................................................ 206Trend Recorder............................................................................................................................................ 208

Communication Protocols..........................................................................................................213Modbus®..................................................................................................................................................... 213IEC 61850.................................................................................................................................................... 218

Time Synchronization.................................................................................................................225SNTP........................................................................................................................................................... 229IRIG-B00X................................................................................................................................................... 233

Parameters...................................................................................................................................237Parameter Definitions.................................................................................................................................. 237Adaptive Parameters Via HMI...................................................................................................................... 240Operational Modes (Access Authorization)..................................................................................................252Password..................................................................................................................................................... 253Changing of Parameters - Example.............................................................................................................254Changing of Parameters When Using the PowerPort-E - Example.............................................................255Protection Parameters ................................................................................................................................ 257Setting Groups............................................................................................................................................. 257Comparing Parameter Files Via PowerPort-E..............................................................................................267Converting Parameter Files Via PowerPort-E..............................................................................................268Program Mode............................................................................................................................................. 268

Device Parameters......................................................................................................................270Date and Time............................................................................................................................................. 270Version......................................................................................................................................................... 270Version Via PowerPort-E.............................................................................................................................. 270TCP/IP Settings........................................................................................................................................... 271Direct Commands of the System Module.....................................................................................................271

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ETR-5000 IM02602013E

Global Protection Parameters of the System...............................................................................................272System Module Input States........................................................................................................................ 274System Module Signals................................................................................................................................ 274Special Values of the System Module..........................................................................................................275

System Parameters.....................................................................................................................276General System Parameters........................................................................................................................ 276Generator Specific System Parameters.......................................................................................................276Voltage Depending System Parameters......................................................................................................277Current Depending System Parameters......................................................................................................278

Blocking....................................................................................................................................... 279Permanent Blocking..................................................................................................................................... 279Temporary Blocking..................................................................................................................................... 279To Activate or Deactivate the Tripping Command of a Protection Module....................................................281Activate, Deactivate Respectively to Block Temporary Protection Functions...............................................282

Protection (Prot) Module............................................................................................................284How to Block All Protective and Supervisory Functions................................................................................284Direct Commands of the Protection Module.................................................................................................291Global Protection Parameters of the Protection Module...............................................................................291Protection Module Input States.................................................................................................................... 291Protection Module Signals (Output States)..................................................................................................291Protection Module Values............................................................................................................................. 292

Switchgear/Breaker – Manager..................................................................................................293Single Line Diagram..................................................................................................................................... 293Import of a Single Line Diagram................................................................................................................... 293Transfer of the Single Line Diagram into the Device....................................................................................293Export of a Single Line Diagram.................................................................................................................. 293Switchgear Configuration............................................................................................................................. 294Switchgear Wear......................................................................................................................................... 324Control - Example: Switching of a Breaker...................................................................................................330

Protective Elements....................................................................................................................33487 - Differential Protection............................................................................................................................ 33487 GD - Restricted Ground Fault Protection................................................................................................36087GDH - High Set Restricted Ground Fault Protection................................................................................363Directional Feature – Phase Current............................................................................................................36750P/67P- DEFT Overcurrent Protection.......................................................................................................37051P/67P - INV Overcurrent-Protection.........................................................................................................37651Q - Negative-Sequence Overcurrent Protection.......................................................................................391IH2 – Inrush Blocking................................................................................................................................... 399Directional Features for Measured (IX) Ground Fault Elements 50X/51X....................................................40350X/67X DEFT Measured Ground Fault Protection.....................................................................................40651X/67X INV Measured Ground Fault Protection.........................................................................................411Directional Features for Calculated (IR) Ground Fault Elements 50R/51R..................................................41850R/67R DEFT Calculated Ground Fault Protection....................................................................................42151R/67R INV Calculated Ground Fault Protection.......................................................................................42624 - Volts/Hertz............................................................................................................................................ 432ZI - Zone Interlocking................................................................................................................................... 43849 - Thermal Overload Protection................................................................................................................44946 - Current Unbalance Protection...............................................................................................................456SOTF - Switch Onto Fault Protection...........................................................................................................462CLPU - Supervision Module Cold Load Pickup............................................................................................46627M - Undervoltage Protection..................................................................................................................... 47359M - Overvoltage Protection....................................................................................................................... 47827A - Auxiliary Undervoltage Protection.......................................................................................................48359A - Auxiliary Overvoltage Protection.........................................................................................................48859N - Neutral Overvoltage........................................................................................................................... 49247 - Voltage Unbalance Protection...............................................................................................................49481O/U, 81R, 78V Frequency Protection.......................................................................................................50032 - Power Protection................................................................................................................................... 52132V - Reactive Power Protection................................................................................................................. 53155A and 55D................................................................................................................................................ 541ExP - External Protection............................................................................................................................. 542Ext Temp Superv – External Temperature Supervision................................................................................546

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IM02602013E ETR-5000

Ext Oil Temp – External Oil Temperature Protection....................................................................................550Sudden Pressure Protection........................................................................................................................ 554

Supervision..................................................................................................................................56050BF – Breaker Failure Supervision............................................................................................................560CTS – Current Transformer Supervision......................................................................................................57774TC - Trip Circuit Monitoring...................................................................................................................... 581LOP – Loss of Potential............................................................................................................................... 586Self Supervision........................................................................................................................................... 590

RTD Protection Module...............................................................................................................592General – Principle Use............................................................................................................................... 592Device Planning Parameters of the RTD Temperature Protection Module...................................................594Global Protection Parameters of the RTD Temperature Protection Module.................................................594Setting Group Parameters of the RTD Temperature Protection Module......................................................594RTD Temperature Protection Module Input States.......................................................................................605RTD Temperature Protection Module Signals (Output States).....................................................................606RTD Temperature Protection Module Counter Values..................................................................................608

URTDII Module Interface.............................................................................................................609Principle – General Use............................................................................................................................... 609URTDII Module Fiber Optic Connection to the Protective Device................................................................609Wiring RTDs to the URTDII Module.............................................................................................................610Direct Commands of the URTD Module.......................................................................................................613Global Protection Parameters of the URTD Module.....................................................................................614URTD Signals (Output States)..................................................................................................................... 615URTD Module Statistics............................................................................................................................... 615URTD Measured Values.............................................................................................................................. 616

Programmable Logic...................................................................................................................618General Description..................................................................................................................................... 618Programmable Logic at the Panel................................................................................................................622Programmable Logic Via PowerPort-E.........................................................................................................622

Commissioning...........................................................................................................................648Commissioning/Protection Test.................................................................................................................... 648Decommissioning – Removing the Plug from the Relay..............................................................................649

Service and Commissioning Support........................................................................................650Maintenance Mode...................................................................................................................................... 650Principle – General Use............................................................................................................................... 650Before Use................................................................................................................................................... 651How to Use the Maintenance Mode.............................................................................................................651Forcing the Relay Output Contacts..............................................................................................................653Disarming the Relay Output Contacts..........................................................................................................653Forcing RTDs*............................................................................................................................................. 654Forcing Analog Outputs*.............................................................................................................................. 655Forcing Analog Inputs*................................................................................................................................. 656Failure Simulator (Sequencer)*.................................................................................................................... 656

Technical Data.............................................................................................................................671Climatic Environmental Conditions...............................................................................................................671Degree of Protection EN 60529................................................................................................................... 671Routine Test................................................................................................................................................. 671Housing........................................................................................................................................................ 671Current and Ground Current Measurement.................................................................................................671Voltage and Residual Voltage Measurement................................................................................................673Frequency Measurement............................................................................................................................. 673Voltage Supply............................................................................................................................................. 673Power Consumption..................................................................................................................................... 673Display......................................................................................................................................................... 673Front Interface RS232.................................................................................................................................. 674Analog Outputs............................................................................................................................................ 674Analog Inputs............................................................................................................................................... 674Real Time Clock........................................................................................................................................... 675Digital Inputs................................................................................................................................................ 675Relay Output Contacts................................................................................................................................. 676Supervision Contact (SC)............................................................................................................................. 676Time Synchronization IRIG-B00X................................................................................................................. 676

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ETR-5000 IM02602013E

Zone Interlocking......................................................................................................................................... 676RS485*........................................................................................................................................................ 677Fiber Optic*.................................................................................................................................................. 677URTD-Interface*.......................................................................................................................................... 677Boot Phase.................................................................................................................................................. 677

Standards.....................................................................................................................................678Approvals..................................................................................................................................................... 678Design Standards........................................................................................................................................ 678High Voltage Tests (IEC 60255-6)................................................................................................................678EMC Immunity Tests.................................................................................................................................... 678EMC Emission Tests.................................................................................................................................... 679Environmental Tests..................................................................................................................................... 679Mechanical Tests......................................................................................................................................... 680

Specifications..............................................................................................................................681Specifications of the Real Time Clock..........................................................................................................681Time Synchronization Tolerances................................................................................................................. 681Specifications of the Measured Value Acquisition........................................................................................682Protection Elements Accuracy..................................................................................................................... 685

Appendix......................................................................................................................................691Instantaneous Current Curves (Phase)........................................................................................................697Time Current Curves (PHASE).................................................................................................................... 698Instantaneous Current Curves (Ground Current Calculated).......................................................................710Instantaneous Current Curves (Ground Current Measured).........................................................................711Time Current Curves (Ground Current)........................................................................................................712

Assignment List..........................................................................................................................724

407ab8d5570d303391a378338248d5018659cfa8d3dfa39459427cd5961c7bfc

RMS Handoff: 0File: D:\Sebastian\p4\ETR-5000\cd\_mainline\generated\ETR-5000_user_manual_eaton_en.odt

This manual applies to devices (version):

Version 2.0.h

Build: 16930

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IM02602013E ETR-5000

Key Features, Functions, and Benefits• Flexible phase and ground differential protection for two winding transformers, large motors and

generators.• Complete protection, and control in a single compact case to reduce panel space, wiring and costs.• Integral test function reduces maintenance time and expense.• Zone selective interlocking improves coordination and tripping time, and saves money compared to a

traditional bus differential scheme.• Reduce trouble shooting time and maintenance costs- Trip and event recording in non-volatile memory

provides detailed information for analysis and system restoration. 6000 cycles of waveform capture aids in post fault analysis (viewable using Powerport-E software)

• Minimum replacement time- Removable terminal blocks ideal for industrial environments• Front RS-232 port and Powerport-E software provides local computer access and User-friendly windows

based interface for relay settings, configuration, and data retrieval.• Breaker open/close from relay faceplate or remotely via communications.• Fast an easy troubleshooting, improved maintenance procedures and increased device security.

Provides detailed traceability for system configuration changes• Relays self-diagnostics and reporting improves uptime and troubleshooting.• Breaker trip circuit monitoring improves the reliability of the breaker operation.

General DescriptionEaton’s ETR-5000 transformer protection relay is a multi-functional, microprocessor-based relay for two winding transformers of all voltage levels. The ETR-5000 provides phase and ground percentage restrained differential protection using a variable dual slope characteristic with phase, negative, residual, and neutral overcurrent elements for backup protection. It can also be used to provide restrained differential protection to large motors and generators.

The ETR-5000 transformer protection relay has removable terminal blocks, and it has Modbus-RTU communications as standard; and an optional Ethernet port for Modbus-TCP communications or IEC-61850. The ETR-5000 transformer protection relay provides complete current, voltage, and frequency protection in a single compact case. The relay has eight current inputs rated for either 5 amperes or 1 ampere to monitor both sides of the transformers. The CTs can be connected in Wye in both sides of the transformer; the relay automatically compensates for the connection of the transformer, and CT mismatch errors. The relay has four voltage inputs. Three of the voltage inputs are to be connected to the 3-phase power voltage for voltage protection and for metering. They can be connected in wye-ground or open delta configuration. The fourth voltage is for independent single-phase undervoltage/overvoltage protection. The unit is User programmable for 60 Hz or 50 Hz operation.

The maintenance mode password protected soft key, can be used for arc flash mitigation to change to an alternate settings group, set to have instantaneous elements only. The multiple setting groups can also be changed, via communications or a digital input. Flash memory is used for the programming and all settings are stored in nonvolatile memory.

An integral keypad and display is provided for direct User programming and retrieval of data without the need of a computer.14 programmable LEDs provide quick indication of relay status. A front port is provided for direct computer connection. An RS-485 communication port on the back is standard for local area networking using Modbus-RTU. An optional Ethernet port and protocols are available.

The ETR-5000 transformer protection relay includes programmable logic functions. Logic gates and timers may be defined and arranged for customized applications. With the programmable logic control functions you can simplify the complexity of your starting schemes by eliminating timers and auxiliary relays. The ETR-5000 transformer protection relay has mass memory for data storage and a real-time clock with 1 ms time resolution. The relay will log 300 sequence of event records, 20 detailed trip logs, minimum/maximum values, load profiles, breaker wear information and oscillography data.

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ETR-5000 IM02602013E

The ETR-5000 has eight programmable binary inputs, 4 normally opened and 4 Form C heavy duty outputs and one Form C signal alarm relay. The relay has the option of 2 Zone Interlocks or 1 Zone Interlock and 2 Analog Inputs and 2 Analog Outputs. The relay can be powered from 19 Vdc to 300 Vdc or 40 Vac to 250 Vac auxiliary power. The unit also comes with a test mode to force outputs and simulate currents, to facilitate the commissioning of the unit.

Features

Protection Features

• Differential Protection• Dual-slope percentage restrained current differential with magnetizing inrush and overexcitation blocking

(87R)• Unrestrained current differential (87H)• Restricted ground fault/Ground Differential (87GD)• Phase overcurrent (elements can be assigned to either side of the transformer):• Four instantaneous elements with timers ( 50P[1], 50P[2], 50P[3], and 50P[4] )• Four inverse time overcurrent elements (51P[1], 51P[2], 51P[3] and 51P[4])• 11 standard curves• Inrush Blocking• Instantaneous or time delay reset• Negative sequence phase overcurrent (elements can be assigned to either side of the transformer):• 2 inverse time overcurrent elements (51Q[1], and 51Q[2])• 11 standard curves• Instantaneous or time delay reset• Ground overcurrent (elements can be assigned to either side of the transformer):• Two instantaneous measured elements with timers (50X[1], and 50X[2])• Two instantaneous calculated elements with timers (50R[1], and 50R[2])• Two inverse time overcurrent measured elements (51X[1], and 51X[2])• Two inverse time overcurrent calculated elements (51R[1], and 51R[2])• 11 standard curves• Instantaneous or time delay reset• Current unbalance and sequence protection (46[1], 46[2]).• Phase voltage unbalance and sequence protection (47[1], 47[2]).• Main 3-phase under/overvoltage (27M[1], 27M[2], 59M[1], 59M[2])• Auxiliary single-phase under/overvoltage (27A[1], 27A[2], 59A[1], 59A[2])• 6 Frequency elements that can be assigned to: over frequency, under frequency, rate of change, or

vector surge (81[1], 81[2], 81[3], 81[4], 81[5], 81[6])• Apparent and displacement power factor (55A[1], 55A[2], 55D[1], 55D[2])• Forward and Reverse Watts (32[1], 32[2], 32[3])• Forward and Reverse Vars (32V[1], 32V[2], 32V[3])• Two breaker failure elements (50BF[1], and 50BF[2]).• Phase transformer overload protection (49)• Switch onto fault protection• Cold load pickup• Zone interlocking for bus protection (87B).

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IM02602013E ETR-5000

Metering Features

• Amperes: Positive, negative and zero sequence.• Ampere demand.• Volts: Positive, negative and zero sequence.• Phase angles.• Volt-amperes and VA demand.• Watts and kW demand.• kWh (forward, reverse, net).• Vars and kvar demand.• kvarh (lead, leg and net).• Power factor.• Frequency.• % THD V and I.• Magnitude THD V and I.• Minimum/maximum recording.• Trending (load profile over time)• Minimum/maximum recording• Temperature with remote URTD module

Monitoring Features

• Trip coil monitor for both primary and secondary breakers.• Breaker wear primary and secondary (accumulated interrupted current).• Oscillography (6000 cycles total).• Fault data logs (up to 20 events).• Sequence of events report (up to 300 events).• Clock (1 ms time stamping).

Control Functions

• Breaker open/close both breakers• Remote open/close• Programmable I/O• Programmable LEDs• Multiple setting groups.• Cold load pickup.• CT supervision

Communication Features

• Local HMI.• Password protected.• Addressable.• IRIG-B• Local communication port.• Remote communication port:

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ETR-5000 IM02602013E

• RS-232• RS-485• Protocols:• Modbus-RTU• Modbus-TCP (Optional)• IEC-61850 (Optional)• Configuration software.

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IM02602013E ETR-5000

Comments on the ManualThis manual gives a general explanation of the tasks of device planning, parameter setting, installation, commissioning, operation, and maintenance of the Eaton devices.

The manual serves as reference document for:

• Engineers in the protection field;• Commissioning engineers;• Personnel dealing with the setting, testing, and maintenance of protection and control devices; and• Well trained personnel involved in electrical installations and power stations.

All functions concerning the type code will be defined. Should there be a description of any functions, parameters, or inputs/outputs that do not apply to the device in use, please ignore that information.

All details and references are explained to the best of our knowledge and are based on our experience and observations.

This manual describes the full featured versions of the devices, including all options.

All technical information and data included in this manual reflect their state at the time this document was issued. Eaton Corporation reserves the right to carry out technical modifications in line with further development without changing this manual and without previous notice. Therefore no claim can be brought based on the information and descriptions included in this manual.

Text, graphics, and formulas do not always apply to the actual delivery scope. The drawings and graphics are not true to scale. Eaton Corporation does not accept any liability for damage and operational failures caused by operating errors or disregarding the directions of this manual.

No part of this manual is allowed to be reproduced or passed on to others in any form, unless Eaton Corporation has issued advanced approval in writing.

This User manual is part of the delivery scope when purchasing the device. In case the device is passed on (sold) to a third party, the manual has to be passed on as well.

Any repair work carried out on the device requires skilled and competent personnel with verifiable knowledge and experienced with local safety regulations and have the necessary experience with working on electronic protection devices and power installations.

IMPORTANT DEFINITIONS

The symbol/word combinations detailed below are designed to call the User's attention to issues that could affect User safety and well being as well as the operating life of the device.

DANGER indicates a hazardous situation which, if not avoided, will result in death or serious injury.

WARNING indicates a hazardous situation which, if not avoided, could result in death or serious injury.

CAUTION, used with the safety alert symbol, indicates a hazardous situation which, if not avoided, could result in minor or moderate injury.

CAUTION, without the safety alert symbol, is used to address practices not related to personal injury.

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ETR-5000 IM02602013E

NOTICE is used to address information and practices not related to personal injury.

FOLLOW INSTRUCTIONS

Read this entire manual and all other publications pertaining to the work to be performed before installing, operating, or servicing this equipment. Practice all plant and safety instructions and precautions. Failure to follow the instructions can cause personal injury and/or property damage.

PROPER USE

Any unauthorized modifications to or use of this equipment outside its specified mechanical, electrical, or other operating limits may cause personal injury and/or property damage, including damage to the equipment. Any such unauthorized modifications: (1) constitute "misuse" and/or "negligence" within the meaning of the product warranty, thereby excluding warranty coverage for any resulting damage; and (2) invalidate product certifications or listings.

The programmable devices subject to this manual are designed for protection and also control of power installations and operational devices that are fed by voltage sources with a fixed frequency, i.e. fixed at 50 or 60 Hertz. They are not intended for use with Variable Frequency Drives. The devices are further designed for installation in low voltage (LV) compartments of medium voltage (MV) switchgear panels or in de-centralized protection panels. The programming and settings have to meet all requirements of the protection concept (of the equipment that is to be protected). The User must ensure that the device will properly recognize and manage (e.g.: switch off the breaker) on the basis of User selected programming and settings all operational conditions (failures). Before starting any operation and after any modification of the programming/settings, make a documented proof that the programming and settings meet the requirements of the protection concept.

Typical applications for this product family/device line are for example:

• Feeder protection;

• Mains protection;

• Transformer Protection and

• Machine protection.

This device is not designed for any usage beyond these applications. This applies also to the use as a partly completed machinery. The manufacturer cannot be held liable for any resulting damage. The User alone bears the risk if this device is used for any application for which it was not designed. As to the appropriate use of the device: the technical data specified by Eaton Corporation has to be met.

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IM02602013E ETR-5000

OUT-OF-DATE PUBLICATION

This publication may have been revised or updated since this copy was produced. To verify that you have the latest revision, be sure to check the Eaton Corporation website:

www. e aton.com

The latest versions of most publications are available at this site.

If the User's publication is not found on the web site, please contact Eaton Customer Support to get the latest copy.

ELECTROSTATIC DISCHARGE AWARENESS

All electronic equipment is sensitive to electrostatic discharge, some components more than others. To protect these components from electrostatic damage, the User must take special precautions to minimize or eliminate electrostatic discharges.

Follow these precautions when working with or near the device.

1. Before performing maintenance on the electronic device, discharge the static electricity on your body to ground by touching and holding a grounded metal object (pipes, cabinets, equipment, etc.).

2. Avoid the build-up of static electricity on your body by not wearing clothing made of synthetic materials. Wear cotton or cotton-blend materials as much as possible because these do not store static electric charges as much as synthetics.

3. Keep plastic, vinyl, and Styrofoam materials (such as plastic or Styrofoam cups, cup holders, cigarette packages, cellophane wrappers, vinyl books or folders, plastic bottles, and plastic ash trays) away from the device, the modules, and the work area as much as possible.

4. Do not remove any printed circuit board (PCB) from the device cabinet unless absolutely necessary. If you must remove the PCB from the device cabinet, follow these precautions:

• Do not touch any part of the PCB except the edges.

• Do not touch the electrical conductors, the connectors, or the components with conductive devices or with your hands.

• When replacing a PCB, keep the new PCB in the plastic, anti-static protective bag it comes in until you are ready to install the PCB. Immediately after removing the old PCB from the device cabinet, place it in the anti-static protective bag.

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ETR-5000 IM02602013E

Eaton Corporation reserves the right to update any portion of this publication at any time. Information provided by Eaton Corporation is believed to be correct and reliable. However, no responsibility is assumed by Eaton Corporation unless otherwise expressly undertaken.

© Eaton Corporation, 2012. All Rights Reserved.

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IM02602013E ETR-5000

What Is Included with the DeviceThe device package includes all connection terminals, except communication connectors, but does not include the fastening material. Please check the package for completeness upon delivery.

Device Package Contents:

• 1 – Protective Relay;• 1 – Mount (Standard or Projection);• 1 – Quick Start Guide; and• 2 – CDs

Disk 1 - Contains the User's Manual, Modbus Register Maps, IEC 61850 Communication Documentation, Wiring Diagrams, and Device Model (Template) for Off-line Parameter Setting;

Disk 2 - Contains PowerPort-E and Quality Manager software applications.

Disk1 contains the device templates. The device templates MUST BE installed to allow PowerPort-E to configure a device off-line.

Please make sure the product label, wiring diagram, type code, and materials and description pertain to this device. If you have any doubts, please contact Eaton Corporation's Customer Service Department.

StorageThe devices must not be stored outdoors. If stored, it must be stored in an area with temperature and humidity control (see the Technical Data section contained in this manual).

Important Information

In line with the customer’s requirement, the devices are combined in a modular way (in compliance with the order code). The terminal assignment of the device can be found on the top of the device (wiring diagram). In addition, it can be found within the Appendix of this manual (see Wiring Diagrams).

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ETR-5000 IM02602013E

Symbols

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tern

al m

essa

ge

Func

tiona

l des

crip

tion:

If th

e se

tting

va

lue

"IG.B

lock

at V

G=0

" is

set t

o "in

activ

e", t

he o

utpu

t 1 is

act

ive

and

outp

ut 2

is in

activ

e. If

the

setti

ng v

alue

"IG

.Blo

ck a

t VE=

0" is

set

to "a

ctive

", th

e ou

tput

2 is

act

ive a

nd th

e ou

tput

1

is in

activ

e.

Prot

.I di

r fw

d

AR.t-

D

0t-D

φ

"φ"=

Elem

ents

with

com

plex

func

tions

"g

ray-

box"

.

Inac

tive

Activ

e

Bkr.L

atch

edO

ptio

n/fe

atur

es to

be

real

ised

in th

e fu

ture

.

Para

met

er o

f a M

odul

e-In

put w

ith a

Se

lect

ionL

ist/D

ropD

own.

An

(1..n

) si

gnal

/out

put f

rom

the

list o

r a p

re-

defin

ed v

alue

can

be

sele

cted

.1.

.n, A

ssig

nmen

t Lis

t

<Nam

e>

1..n

, VeE

nabl

e

No a

ssig

nmen

t,1..n

No

assi

gnm

ent

1

<Nam

e>

1..n

, Ass

ignm

ent L

ist

Para

met

er o

f a M

odul

e-In

put (

with

sp

ecia

l val

ues)

: An

(1..n

) out

put f

rom

the

list w

ill be

ass

igne

d to

the

inpu

t "<

nam

e>.id

entif

ier".

If th

e pa

ram

eter

is

set t

o "It

emN

ull",

an

"inac

tive"

-sig

nal w

ill be

giv

en o

ut.

Lim

it va

lue

mon

itorin

g wi

th th

ree

anal

og in

put v

alue

s. C

ompa

res

3 an

alog

val

ues

with

the

set l

imit;

out

put

valu

es a

re th

ree

diffe

rent

bin

ary

valu

es a

s a

resu

lt of

the

com

paris

ion.

If

the

anal

og s

igna

l exc

eeds

the

limit

I/In

, the

cor

resp

ondi

ng o

utpu

t sig

nal

beco

mes

"1".

I/ In

IA IB IC

<20%

VnV

Lim

it va

lue

mon

itorin

g (C

ompa

red

to

a fix

ed v

alue

). C

ompa

res

a va

lue

with

th

e fix

ed s

et li

mit;

out

put v

alue

is

bina

ry a

s a

resu

lt of

the

com

paris

ion.

If

the

signa

l exc

eeds

the

limit,

the

corre

spon

ding

out

put s

igna

l bec

omes

"1

".

Ada

ptiv

e Pa

ram

eter

Sele

ctio

n Li

st

<Nam

e>

Dire

ct C

omm

and

IM02602013E ETR-5000

18 www.eaton.com

And

Or

Neg

ated

Inpu

t

Neg

ated

Out

put

Band

-pas

s (fi

lter)

IH1

Band

-pas

s (fi

lter)

IH2

Quo

tient

of A

nalo

g Va

lues

t1

Del

ay T

imer

1

Bkr.t

-Trip

Cm

d

t

Anal

og V

alue

s

AND

S

Q

R1

Q

a bc d

RS fl

ip-fl

opa

b c

d0

0 U

ncha

nged

0 1

0 1

1 0

1 0

1 1

0 1

Tim

e st

age:

A "1

" at t

he

inpu

t sta

rts th

e el

emen

t. If

the

time

<nam

e>.t

is

expi

red,

the

outp

ut b

ecom

es

"1" t

oo. T

he ti

me

stag

e w

ill be

rese

t by

"0" a

t the

inpu

t. Th

us th

e ou

tput

will

be s

et to

"0

" at t

he s

ame

time.

Tim

e st

age

min

imum

pul

se

widt

h: T

he p

ulse

wid

th

<nam

e>.t

will b

e st

arte

d if

a "1

" is

feed

to th

e in

put.

By

star

ting

<nam

e>.t,

the

outp

ut b

ecom

es "1

". If

the

time

is e

xpire

d, th

e ou

tput

be

com

es "0

" ind

epen

dent

fro

m th

e in

put s

igna

l.

IH1

IH2

Exclu

sive

-XR

Anal

og V

alue

C

ompa

rato

r

+ R+

Incr

emen

tR

Rese

t

Edge

trig

gere

d co

unte

r

IH2

IH1OR

XOR

Inve

rting

t2

t1: S

witc

h O

n D

elay

t2: S

witc

h O

ff D

elay

Del

ay T

imer

t1t2

t1t2 C

ount

er

ETR-5000 IM02602013E

www.eaton.com 19

22

Inpu

t Sig

nal

Out

put S

igna

l

2Na

me.

Activ

e

3N

ame.

Blo

Trip

Cm

d

4Na

me.

Activ

e

5IH

2.Bl

o Ph

ase

A

6IH

2.Bl

o Ph

ase

B

7IH

2.Bl

o Ph

ase

C

8IH

2.Bl

o IG

9N

ame.

Fau

lt in

Pro

ject

ed D

irect

ion

10N

ame.

Fau

lt in

Pro

ject

ed D

irect

ion

10a

Prot

-50

R -

Dire

ctio

n D

etec

tion

10b

Prot

-50

X -D

irect

ion

Det

ectio

n

14 15Na

me.

Trip

Cm

d

1Pr

ot.A

vaila

ble

Plea

se R

efer

to D

iagr

am: B

lock

ings

Plea

se R

efer

to D

iagr

am: B

lock

ings

**

Plea

se R

efer

to D

iagr

am: P

rot

Plea

se R

efer

to D

iagr

am: T

rip B

lock

ings

Plea

se R

efer

to D

iagr

am: I

H2

Plea

se R

efer

to D

iagr

am: I

H2

Plea

se R

efer

to D

iagr

am: I

H2

Plea

se R

efer

to D

iagr

am: I

H2

Plea

se R

efer

to D

iagr

am: D

irect

ion

Dec

isio

n Ph

ase

over

curre

nt

Plea

se R

efer

to D

iagr

am: D

irect

ion

Dec

isio

n G

roun

d Fa

ult

Plea

se R

efer

to D

iagr

am: D

irect

ion

Dec

isio

n G

roun

d Fa

ult

Plea

se R

efer

to D

iagr

am: D

irect

ion

Dec

isio

n G

roun

d Fa

ult

Nam

e.Pi

ckup

Each

pic

kup

of a

mod

ule

(exc

ept f

rom

su

perv

isio

n m

odul

es b

ut in

clud

ing

BF) w

ill le

ad to

a g

ener

al p

icku

p (c

olle

ctiv

e pi

ckup

).

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed

prot

ectio

n m

odul

e wi

ll le

ad to

a g

ener

al tr

ip.

17b

Nam

e.Tr

ip P

hase

B

18

Nam

e.Tr

ip P

hase

C

19

Nam

e.Tr

ipCm

d

16

Nam

e.Tr

ip P

hase

A

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

16a

Nam

e.Tr

ip P

hase

A

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

16b

Nam

e.Tr

ip P

hase

A

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e w

ill le

ad to

a g

ener

al tr

ip.

17

Nam

e.Tr

ip P

hase

B

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e w

ill le

ad to

a g

ener

al tr

ip.

17a

Nam

e.Tr

ip P

hase

B

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e w

ill le

ad to

a g

ener

al tr

ip.

19a

Nam

e.Tr

ipC

md

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e w

ill le

ad to

a g

ener

al tr

ip.

19b

Nam

e.Tr

ipC

md

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e w

ill le

ad to

a g

ener

al tr

ip.

19c

Nam

e.Tr

ipC

md

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e w

ill le

ad to

a g

ener

al tr

ip.

19d

Nam

e.Tr

ipC

md

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e w

ill le

ad to

a g

ener

al tr

ip.

18a

Nam

e.Tr

ip P

hase

C

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

18b

Nam

e.Tr

ip P

hase

C

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e w

ill le

ad to

a g

ener

al tr

ip.

11VT

S.Pi

ckup

Plea

se R

efer

to D

iagr

am: V

TS

12a

VTS

.Pic

kup

12b

12c

VTS.

VTS.

LOP

Blo

Plea

se R

efer

to D

iagr

am: V

TS

VTS

.VTS

.LO

P B

loPl

ease

Ref

er to

Dia

gram

: VTS

Plea

se R

efer

to D

iagr

am: V

TS

IM02602013E ETR-5000

20 www.eaton.com

34Bk

r.Pos

CLO

SE

35Bk

r.Pos

OP

EN

33Bk

r.Sta

te

Plea

se R

efer

to D

iagr

am: B

kr.B

kr M

anag

er

Plea

se R

efer

to D

iagr

am: B

kr.B

kr M

anag

er

Plea

se R

efer

to D

iagr

am: B

kr.B

kr M

anag

er

36Bk

r.Pos

Inde

term

37B

kr.P

os D

istu

rb

Plea

se R

efer

to D

iagr

am: B

kr.B

kr M

anag

er

Plea

se R

efer

to D

iagr

am: B

kr.B

kr M

anag

er

20N

ame.

Trip

Pha

se A

21N

ame.

Trip

Pha

se B

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

22N

ame.

Trip

Pha

se C

23N

ame.

Trip

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

e wi

ll lea

d to

a g

ener

al tr

ip.

25N

ame.

Pick

up IB

26b

Nam

e.Pi

ckup

IC

27N

ame.

Pick

up

28Na

me.

Pick

up P

hase

A

29Na

me.

Pick

up P

hase

B

24N

ame.

Pick

up IA

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctive

pic

kup)

.

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctive

pic

kup)

.

30Na

me.

Pick

up P

hase

C

31N

ame.

Pick

up

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctive

pic

kup)

.

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctive

pic

kup)

.

32Pr

ot.B

lo T

ripC

md

24a

Nam

e.Pi

ckup

IA

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctive

pic

kup)

.

24b

Nam

e.Pi

ckup

IA

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

25a

Nam

e.Pi

ckup

IB

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctive

pic

kup)

.

25b

Nam

e.Pi

ckup

IB

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

26N

ame.

Pick

up IC

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

26a

Nam

e.Pi

ckup

IC

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

27a

Nam

e.Pi

ckup

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive g

ener

al p

icku

p (c

olle

ctiv

e pi

ckup

).

27b

Nam

e.Pi

ckup

Eac

h ph

ase

sele

ctive

pic

kup

of a

mod

ule

(I, IG

, V, V

X

depe

ndin

g on

the

devic

e ty

pe) w

ill le

ad to

a p

hase

se

lect

ive

gene

ral p

icku

p (c

olle

ctiv

e pi

ckup

).

27c

Nam

e.Pi

ckup

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

se

lect

ive g

ener

al p

icku

p (c

olle

ctiv

e pi

ckup

).

27d

Nam

e.Pi

ckup

Each

pha

se s

elec

tive

pick

up o

f a m

odul

e (I,

IG, V

, VX

depe

ndin

g on

the

devi

ce ty

pe) w

ill le

ad to

a p

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Ex

FF G

VT

ETR-5000 IM02602013E

www.eaton.com 21

41Bk

r.Pro

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SE

42Bk

r.CLO

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log

Valu

esAn

In[1

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AnIn

[2].V

alue

AnIn

[n].V

alue

IM02602013E ETR-5000

General Conventions

22 www.eaton.com

»Parameters are indicated by right and left double arrow heads and written in italic.«

»SIGNALS are indicated by right and left double arrow heads and small caps.«

[Paths are indicated by brackets.]

Software and Device names are written in italic.

Module and Instance (Element) names are displayed italic and underlined.

»Pushbuttons, Modes, and Menu entries are indicated by right and left double arrow heads .«

1 2 3 Image References (Squares)

.

ETR-5000 IM02602013E

Installation and WiringThree-Side-View

Depending on the connection method of the communication system used, the needed space (depth) differs. If, for instance, a D-Sub-Plug is used, it has to be added to the depth dimension.

Even when the auxiliary voltage is switched-off, unsafe voltages remain at the device connections.

Outline Projection Mount - Door Cut-out

The housing must be carefully grounded. Connect a ground cable (AWG 12-10 [4 to 6 mm2] / 15 In-lb [1.7 Nm]) to the housing, using the screw that is marked with the ground symbol (at the rear side of the device).

The power supply card needs a separate ground connection (AWG 14 [2.5 mm2] / 5-7 In-lb [0.56-0.79 Nm]) at terminal X1.

DO NOT over-tighten the mounting nuts of the relay (0.164 X32 ). Check the torque by means of a torque wrench (1.7 Nm [15 In-lb]). Over-tightening the mounting nuts could cause personal injury or damage the relay.

www.eaton.com 23

IM02602013E ETR-5000

Outline Standard Mount - Door Cut-out



Overview of Slots - Assembly Groups

In line with the customers' requirement, the devices are combined in a modular way (in compliance with the order code). In each of the slots, an assembly/group may be integrated. In the following diagram, the terminal assignment of the individual assembly/groups are shown. The exact installation/placement of the individual modules can be determined from the connection diagram attached to the top of your device.

24 www.eaton.com

ETR-5000 IM02602013E

Overview of Slots

Housing B2

Schematic Diagram



Grounding



www.eaton.com 25

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103

Slot3 Slot4 Slot5 Slot6Slot1 Slot2

X101

IM02602013E ETR-5000

DeviceETR-5000

Device PlanningThe ETR-5000 relay has multiple functions. Depending on the particular application, the User may not need all the available functions. The device planning provides the User a means to enable the functions needed and disable those not needed at the top level so the User will not see the unused functions in the menu tree and all the corresponding events, signals, etc.

For example, if the User deactivates a protection function, all parameter branches related to that function will be hidden from the parameters. All corresponding events, signals, etc. will also be deactivated. Due to this device capability, the parameter trees become very transparent and only show the active functions.

It MUST be taken into account that by deactivating any device function, the User also changes the functionality of the device. For example, if the User cancels the directional feature of the overcurrent protections, then the device no longer trips in a directional way but merely in a non-directional way.

Any time a device function is deactivated or activated, the device should be tested to insure its correct functioning for the application.

The manufacturer does not accept liability for any personal or material damage as a result of incorrect planning.

Contact your Eaton Customer Service representative for more information.

Beware of the inadvertent deactivating of protective functions/modules.

If the User is deactivating modules within the device planning, all parameters of those modules will be set on default.

If the User is activating one of these modules, again, all parameters of those reactivated modules will be set on default.

If the protective device is equipped with Zone Interlocking, overcurrent and ground current elements are needed to trigger the Zone Interlocking function. Therefore, some overcurrent and ground current elements cannot be deactivated if the device is equipped with Zone Interlocking.

Device Planning Parameters of the Device

Parameter Description Options Default Menu Path

Hardware Variant 1

Optional Hardware Extension »A« 8 DI, 9 RO, 2 ZI, IRIG, URTD, »B« 8 DI, 9 RO, ZI, 2 AnOut, 2 AnIn, IRIG, URTD

8 DI, 9 RO, ZI, 2 AnOut, 2 AnIn, IRIG, URTD

[ETR-5000]

26 www.eaton.com

ETR-5000 IM02602013E


Hardware Variant 2

Optional Hardware Extension »0« W1: Default Ground Current - W2: Default Ground Current , »1« W1: Sensitive Ground Current - W2: Default Ground Current , »2« W1: Default Ground Current - W2: Sensitive Ground Current, »3« W1: Sensitive Ground Current - W2: Sensitive Ground Current

W1: Default Ground Current - W2: Default Ground Current

[ETR-5000]

Communication

Communication »B« RS 485: Modbus RTU, »H« Ethernet: IEC61850, »I« RS 485 + Ethernet: Modbus RTU + Modbus TCP

»I« RS 485 + Ethernet: Modbus RTU + Modbus TCP

[ETR-5000]

Printed Circuit Board

Printed Circuit Board »A« Standard, »B« Conformal Coating

»A« Standard

[ETR-5000]

There are two mounts available for the ETR-5000: a Standard Mount and a Projection Mount. To order the ETR-5000 with a Standard Mount, append the device code with a zero (0). To order the ETR-5000 with a Pro-jection Mount, append the device code with a one (1). Refer to the table for details of the available device op-tions.

* Consult factory for the availability of variants.

** Ground current measurement:

Four (4) variants are needed for DY / YY / YD /DD application in case of using the sensitive ground current variant.

In the U.S. market, DY connection is normally needed.

There are two mounts available for the ETR-5000: a Standard Mount and a Projection Mount. To order the ETR-5000 with a Standard Mount, append the device code with a zero (0). To order the ETR-5000 with a Pro-jection Mount, append the device code with a one (1). Refer to the table below for details of the available device options.

ETR-5000 Eaton Transformer Differential Relay with Voltage Supervision Removable Terminals

ETR-5000 A 0 B A 1

Choose from the following options.


Hardware Option 1

8 DI, 9 Outputs, Removable Terminals, 2 Times Zone Interlocking, URTD Interface IRIG-B.

A

8 DI, 9 Outputs, 2 AI + 2AO, Removable Terminals, B

www.eaton.com 27

IM02602013E ETR-5000


1 Zone Interlocking, URTD interface IRIG-B.

Hardware Option 2

Phase Current 5A/1A, W1/W2 Ground Current 5A/1A, Power Supply Range: 19-300 Vdc, 40-250 Vac.

0 (Zero)

Phase Current 5A/1A, W1/W2 Sensitive Ground Current 0.5A/0.1A, Power Supply Range: 19-300 Vdc, 40-250 Vac.

1

Phase Current 5A/1A, W1 Ground Current 5A/1A, W2 Sensitive Ground Current 0.5A/0.1A, Power Supply Range: 19-300 Vdc, 40-250 Vac.

2

Phase Current 5A/1A, W1 Sensitive Ground Current 0.5A/0.1A, W2 Ground Current 5A/1A, Power Supply Range: 19-300 Vdc, 40-250 Vac.

3

Communication Options

Modbus RTU (RS-485) B

IEC-61850* H

Modbus-RTU + Modbus-TCP I

Conformal Coating Options

None A

Conformal Coated Circuit Boards B

Mounting Options

Standard Mount 0 (Zero)

Projection Panel Mount 1

* Consult the factory for the availability of variants.

Ordering InformationThe catalog number identification table defines the electrical characteristics and operation features included in the ETR-5000. For example, if the catalog number were ETR-5000A0BA1, the device would have the following:

ETR-5000

(A) - 8 DI, 9 Outputs, Removable Terminals, 2 Times Zone Interlocking, URTD Interface IRIG-B.

(0) - Phase Current 5A/1A, Ground Current 5A/1A, Power Supply Range: 19-300 Vdc, 40-250 Vac.

28 www.eaton.com

ETR-5000 IM02602013E

(B) - Modbus-RTU (RS-485)

(A) - Without Conformal Coating

(1) - Projection Panel Mount

Slot X1: Power Supply Card with Digital InputsRear Side of the Device (Slots)

The type of power supply card and the number of digital inputs on it used in this slot is dependent on the ordered device type. The different variants have a different scope of functions.

Available assembly groups in this slot:

• (DI8-X1): This assembly group comprises a wide-range power supply unit; and two non-grouped digital inputs and six (6) digital inputs (grouped).

The available combinations can be gathered from the ordering code.

DI-8 X - Power Supply and Digital Inputs

Make sure that the tightening torque is 5-7 In-lb [0.56-0.79 Nm].

This assembly group comprises:

• A wide-range power supply unit;• Two non-grouped digital inputs; and• Six (6) digital inputs, grouped.

www.eaton.com 29

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

IM02602013E ETR-5000

Auxiliary Voltage Supply

• The auxiliary voltage inputs (wide-range power supply unit) are non-polarized. The device can be powered with an AC or DC control voltage.

Digital Inputs

For each digital input group, the related voltage input range has to be configured. Wrong switching thresholds can result in malfunctions/wrong signal transfer times.

The digital inputs are provided with different switching thresholds (that are configurable) (two AC and five DC in-put ranges). The following switching levels can be defined:

• 24 Vdc;• 48 Vdc • 60 Vdc;• 110/120 Vac/dc; and• 230/240 Vac/dc.

If a voltage >80% of the set switching threshold is applied at the digital input, the state change is recognized (logically “1”). If the voltage is below 40% of the set switching threshold, the device detects logically “0”.

When using DC supply, the negative potential has to be connected to the common terminal (COM1, COM2, COM3 - please see the terminal marking).

30 www.eaton.com

ETR-5000 IM02602013E

Terminal Marking

Pin Assignment

www.eaton.com 31

V+

V-

FE

COM1

DI1

COM2

DI2

DI3

DI4

DI5

DI6

DI7

DI8

COM3

Do not use

DI-8P X

COM3

N.C.

Do not use

13

24

56

78

910

1112

1314

1516

1718

Power Supply

12345678

FE

9101112

COM1

131415161718

V+ Power Supply

DI1COM2DI2COM3

DI3DI4DI5DI6DI7DI8

COM

Do not useDo not use

V-

X?.

N.C.

IM02602013E ETR-5000

Slot X2: Relay Output Card - Zone Interlock

Rear Side of the Device (Slots)

The type of card in this slot is dependent on the ordered device type. The different variants have a different scope of functions.


• (RO-4Z X2): Assembly Group with four Relay Output Contacts (two Form A and two Form C) and Zone Interlocking.


RO-ZI X - Relay Output Contacts and Zone Interlock

The Relay Output Contacts are potential-free contacts. In the Assignment/Relay Output Contacts section, the assignment of the Relay Output Contacts is specified. The changeable signals are listed in the Assignment List section.


Please carefully consider the current carrying capacity of the Relay Output Contacts. Please refer to the Technical Data.

32 www.eaton.com

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

ETR-5000 IM02602013E

Terminal Marking

Pin Assignment

www.eaton.com 33

Do not use

Do not use

RO3 CMN

RO3 N.O.

RO3 N.C.

13

24

56

78

910

1112

1314

1516

1718

RO-4Z X

RO1 N.O.

RO2 N.O.

COM

OUT

IN

COM

RO4 CMN

RO4 N.O.

RO4 N.C.

123456789

101112131415161718

RO3

X?.Do not useDo not use

COM

OUT

IN

COM

RO4

RO1

RO2

IM02602013E ETR-5000

Slot X3: CT W1- Current Transformer Measuring InputsRear Side of the Device (Slots)

This slot contains the current transformer measuring inputs for winding side 1 of the transformer.

This slot contains the current transformer measuring inputs. Depending on the order code, this might be a standard current measuring card or a sensitive ground current measuring card.


• (TI-4 X3): Standard ground current measuring card.

• (TIS-4 X3): Sensitive Ground current measuring card.


34 www.eaton.com

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

ETR-5000 IM02602013E

Slot X4: CT W2 - Current Transformer Measuring InputsRear side of the device (Slots)

This slot contains the current transformer measuring inputs for the winding side 2 of the transformer.


• (TI-4 X4): Standard ground current measuring card.

4thCT on CT Line only to be used for 87/87GD


TI X- Standard Phase and Ground Current Measuring Input Card

A current measuring card is provided with four (4) current measuring inputs: three for measuring the phase currents and one for measuring of the ground current. Each of the current measuring inputs has a measuring input for 1 A and 5 A.

The input for ground current measuring either can be connected to a zero sequence current transformer or, alternatively, it is possible to connect the summation current path of the phase current transformer to this input (residual connection).

Current transformers have to be earth grounded on their secondary side.

www.eaton.com 35

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

IM02602013E ETR-5000

Interrupting the secondary circuits of current transformers causes hazardous voltages.

The secondary side of the current transformers have to be short circuited before the current circuit to the device is opened.

The current measuring inputs may exclusively be connected to current measuring transformers (with galvanic separation).

• Do not mix the inputs (1 A/5 A).

• Make sure the transformer ratios and the power of the CTs are correctly rated. If the rating of the CTs is not correct (overrated), then the normal operational conditions may not be recognized. The pickup value of the measuring unit amounts to approximately 3% of the rated current of the device. Also, the CTs need a current greater than approximately 3% of the rated current to ensure sufficient accuracy.

Example: For a 600 A CT (primary current), any currents below 18 A cannot be detected.

• Overloading can result in destruction of the measuring inputs or faulty signals. Overloading means that, in case of a short circuit, the current carrying capacity of the measuring inputs could be exceeded.

Make sure that the tightening torque is 17.7 In-lb [2 Nm].

36 www.eaton.com

ETR-5000 IM02602013E

Terminal Markings

Pin Assignment

TIS X – Phase and Sensitive Ground Current Measuring Card

The sensitive ground current measuring card is provided with four (4) current measuring inputs: three for measuring the phase currents and one for measuring of the sensitive ground current. (The sensitive Ground current Input has different technical data. Please refer to chapter Technical Data.).

The input for ground current measuring either can be connected to a zero sequence current transformer or, alternatively, it is possible to connect the summation current path of the phase current transformer to this input (residual connection).

www.eaton.com 37

IA-1A

IA-N

IA-5A

IB-1A

IB-N

IC-1A

IC-N

IC-5A

IX-1A

IX-N

IX-5A

IB-5A

1

2

3

4

5

6

7

8

10

11

9

12

123456789

101112

IA

1A

5A

N

IB

1A

5A

N

IC

1A

5A

N

IX

1A

5A

N

X?.

IM02602013E ETR-5000

Current transformers have to be earth grounded on their secondary side.

Interrupting the secondary circuits of current transformers causes hazardous voltages.

The secondary side of the current transformers have to be short circuited before the current circuit to the device is opened.


Make sure that the tightening torque is 17.7 In-lb [2 Nm].

• Do not interchange the inputs (1 A/5 A)

• Make sure the transformation ratios and the power of the CTs are correctly rated. If the rating of the CTs is not right (overrated), then the normal operational conditions may not be recognized. The pickup value of the measuring unit amounts approx. 3% of the rated current of the device. Also the CTs need a current greater than approx 3% of the rated current to ensure sufficient accuracy. Example: For a 600 A CT (primary current) any currents below 18 A cannot be detected any more.

• Overloading can result in destruction of the measuring inputs or faulty signals. Overloading means that in case of a short-circuit the current-carrying capacity of the measuring inputs could be exceeded.

38 www.eaton.com

ETR-5000 IM02602013E

Terminal Markings

Pin Assignment

Common CT Wiring Configurations

Check the installation direction.

It is imperative that the secondary sides of measuring transformers be grounded.


www.eaton.com 39

IA-1A

IA-N

IA-5A

IB-1A

IB-N

IC-1A

IC-N

IC-5A

IX-1A

IX-N

IX-5A

IB-5A

1

2

3

4

5

6

7

8

10

11

9

12

123456789

101112

IA

1A

5A

N

IB

1A

5A

N

IC

1A

5A

N

IX

1A

5A

N

X?.

IM02602013E ETR-5000

CT secondary circuits must always to be low-burdened or short-circuited during operation.

For current and voltage sensing function external wired and appropriate current and voltage transformer shall be used, based on the required input measurement ratings. Those devices provide the necessary insulation functionality.

All current measuring inputs can be provided with 1 A or 5 A nominal. Make sure that the wiring is correct.

Sensitive Ground Current Measurement

The proper use of sensitive current measuring inputs is the measurement of small currents like they could occur in isolated and high resistance grounded networks.

Due to the sensitiveness of these measuring inputs, do not use them for the measurement of ground short circuit currents like they occur in solidly earthed networks.

If a sensitive measuring input should be used for the measurement of ground short circuit currents, it has to be ensured, that the measuring currents are transformed by a matching transformer according to the technical data of the protective device.

CT Connection Options

The current transformers may be connected in several ways, and the specified configuration affects the way system measurements are made and results computed. The computation of the residual current IR, is dependent on the system configuration setting for the CT connection. The configurations resulting from the setting options are shown as well as the calculated IR residual current.

40 www.eaton.com

ETR-5000 IM02602013E

3-phase, 3-wire IG Calculated

www.eaton.com 41

A B C

IA

IB

IC

1X3.

23456789

101112

Three-phase Current Measurement; Inom Secondary = 5 A.

IA

1A

5A

N

IB

1A

5A

N

IC

1A

5A

N

IX

1A

5A

N

IB'

IC'

IA'

IR calc = IA + IB + IC = IG

IM02602013E ETR-5000

3-phase, 3-wire IG Measured

42 www.eaton.com

A B C

IB'IA

IC'

IB

IC

IA' 1X3.

23456789

101112

Three-phase Current Measurement; Inom Secondary = 1 A.Ground Current Measuring via Zero Sequence CT ; IGnom Secondary = 1 A.

IX'

IA

1A

5A

N

IB

1A

5A

N

IC

1A

5A

N

IX

1A

5A

N

Warning!The shielding at the dismantled end of the line has to be put through the zero sequence current transformer and has to be grounded at the cable side.

Zero Sequence Current Transformer: Measures the ground current (sum of the three phase currents). Can be used for measuring the ground current in isolated and compensated networks. The shield is to be returned through the zero sequence current transformer.

IX meas = IG

IR calc = IA + IB + IC

ETR-5000 IM02602013E

Slot X5: Multi-Input Output-CardRear Side of the Device (Slots)

The type of card in this slot is dependent on the ordered device type. The different variants have a different scope of functions.


• (DI8 X5 and RO4 X5): Assembly Group with eight digital inputs and four relay output contacts.

• (AN IO2 RO4 X5): Assembly Group with two analog inputs and two analog outputs and four relay output contacts.


DI8 X- Digital Inputs

This module is provided with 8 grouped digital inputs. In chapter [Device parameter/Digital Inputs] the assignment of the digital inputs is specified.

Make sure that the tightening torque is 0.56-0.79 Nm [5-7 In-lb].

The ground terminal has to be connected to the »-pole« when using DC supply.

www.eaton.com 43

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

IM02602013E ETR-5000

For each digital input group the related voltage input range has to be configured. Wrong switching thresholds can result in malfunctions/wrong signal transfer times.

Via the »assignment list« the states of the digital inputs are assigned to the module inputs (e.g. I[1]).

The digital inputs are provided with different switching thresholds (can be configured) (two AC and five DC input ranges). For each group the following switching thresholds can be defined:

• 24V DC;• 48V DC / 60V DC;• 110 V AC/DC; and• 230 V AC/DC.

If a voltage >80% of the set switching threshold is applied at the digital input, the state change is recognized (physically “1”). If the voltage is below 40% of the set switching threshold, the device detects physically “0”.

RO-4X - Relay Output Contacts




44 www.eaton.com

ETR-5000 IM02602013E

Terminal Marking

Pin Assignment

www.eaton.com 45

COM1

DI1

DI2

DI3

DI4

DI5

DI6

DI7DI8

COM1

RO1

RO2

RO3

RO4

13

24

56

78

910

1112

1314

1516

1718

1X?.

23456789

101112131415161718

RO1

RO2

RO3

RO4

COM1

DI1DI2

DI3

DI4

DI5

DI6

DI7

DI8

COM1

IM02602013E ETR-5000

AN I02 X - Analog Inputs and Outputs

There are 2 Analog Input and 2 Analog Output channels that are configurable to either 0-20 mA, 4-20 mA, or 0-10 V. Each of the channels can be independently programmed to either of these three input/output modes.

For details on the Analog Inputs/Outputs, please refer to the Technical Data.

Analog inputs:• 2 analog inputs with one common potential. Each input has its own common terminal.• The mode of each input can be individually selected between current or voltage input.• In current mode the measuring range is 0-20 mA.• In current mode the input resistor is 500 Ohm.• In voltage mode the measuring range is 0-10 V.• In voltage mode the input resistor is 100 kOhm.• The accuracy is 0.5 % of the nominal value 20 mA/10 V.• The test voltage of the inputs (one group) against other electrical groups and earth is 2.5 kV.

Analog outputs:• 2 analog outputs with one common potential. Each output has its own common terminal.• The mode of each output can be individually selected between current or voltage output.• In current mode the output range is 0-20 mA.• In current mode the maximum load resistance is 1 kOhm.• In voltage mode the output range is 0-10 V.• In voltage mode the outputs are short circuit proof.• The accuracy is 0.5 % of the nominal value 20 mA/10 V.• The test voltage of the outputs (one group) against other electrical groups and earth is 2.5 kV.

Wiring:• Shielded cable is recommended.• The test voltage against earth is 1.0 kV and against other electrical groups 2.5 kV.

HF-Shield:• The terminals of the HF shield should be used, when connecting the shield to earth on both sides of the

cable is not possible. On one side of the cable the shield has to be directly connected to earth.

Make sure that the tightening torque is 0.56-0.79 Nm [5-7 In-lb].

For details on the Analog Inputs or Outputs please refer to the Technical Data.

RO-4X - Relay Output Contacts




46 www.eaton.com

ETR-5000 IM02602013E

Terminals

Electro-mechanical Assignment

www.eaton.com 47

13

24

56

78

910

1112

1314

1516

1718

AnOut 1 COM

AnOut 1

AnOut 2

AnOut 2 COMHF ShieldAnIn 1

AnIn 2AnIn 1 COM

AnIn 2 COM

HF Shield

RO1

RO2

RO3

RO4

123456789

101112131415161718

X?.

AnOut 1 COM

AnOut 1

AnOut 2AnOut 2 COMHF ShieldAnIn 1

AnIn 2AnIn 1 COM

AnIn 2 COM

HF Shield

RO1

RO2

RO3

RO4

IM02602013E ETR-5000

Slot X6: Voltage Transformer Measuring InputsRear Side of the Device (Slots)

This slot contains the voltage transformer measuring inputs.

Voltage Measuring Inputs

The device is provided with 4 voltage measuring inputs. Three for measuring the mains voltages (»VAB«, »VBC« , »VCA« - in case of Open Delta) or phase-to-neutral voltages (»VA«, »VB«, »VC« in case of Wye). The fourth measuring input is to be used for »VX«.

Make sure that the tightening torque is 1.2-1-6 Nm [11-15 In-lb].

The rotating field of your power supply system has to be taken in to account. Make sure that the voltage transformers are wired correctly.

For the Open Delta connection the system parameter »Main VT con« has to be set to »Open Delta«.

For the Wye connection the system parameter »Main VT con« has to be set to »Wye«.

Please refer to the Technical Data.

48 www.eaton.com

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

ETR-5000 IM02602013E

Terminal Marking

Pin Assignment

Common VT Wirings

Check the installation direction of the VTs.

It is imperative that the secondary sides of measuring transformers be grounded.

For current and voltage sensing function, externally wired and appropriate current and voltage transformer must be used, based on the required input measurement ratings. Those devices provide the necessary insulation functionality.

www.eaton.com 49

VA.112

63

78

54

VA.2

VB.1

VB.2

VC.1

VC.2

VX1.1

VX1.2

12345678

VX

VC/VCA

VB/VBC

VA/VAB

X?.

IM02602013E ETR-5000

VT Check Measuring Values

Connect a three-phase measuring voltage equal to the rated voltage to the relay.

Take the connection of the measuring transformers (open delta/Wye connection) into account.

Now adjust the voltage values in the nominal voltage range with the corresponding nominal frequencies that are not likely to cause over-voltage or under-voltage trips.

Compare the values shown in the device display with the readings of the measuring instruments. The deviation must be according to the specifications in the Technical Data section.

VT Wye

50 www.eaton.com

A B C

VABVBC

VCA

VAVBVC

VA'

A

C

B

NVB' VC'

VAB'

VBC'

VCA'1

X?.

2345678

Three-phase voltage measurement - wiring of the measurement inputs: "Wye"

VX

VC/VCA

VB/VBC

VA/VAB

ETR-5000 IM02602013E

VT Open Delta

www.eaton.com 51

A B C

VABVBC

VCA

A

C

BVAB'

VBC'

VCA'1

X?.

2345678

Two-phase voltage measurement - wiring of the measuring inputs: "Open Delta"

VX

VC/VCA

VB/VBC

VA/VAB

IM02602013E ETR-5000

Typical External Sensing Connections

DY Transformer with Phase Differential Protection and Ground Differential Protection on W1 only.

52 www.eaton.com

1X4.

23456789

101112

IA

1A

5AN

IB

1A5A

N

IC

1A5A

N

IX

1A5A

N

CBA

Positive Power

A B C

A B C

1X6.

2345678

VX

VC/VCA

VB/VBC

VA/VAB

1X3.

23456789

101112

IA

1A5AN

IB

1A5AN

IC

1A5A

N

IX

1A5A

N

CBA

Win

ding

2W

indi

ng 1

W2

W1

VT

Win

ding

Sid

e=W

1C

T W

indi

ng S

ide1

CT

Win

ding

Sid

e2

CT Winding Side2

CT Winding Side1

VX W

indi

ng S

ide=

W1

ETR-5000 IM02602013E

DY Transformer with Phase Differential Protection, REF on W1 and VT on W2 (Open Delta)

www.eaton.com 53

1X4.

23456789

101112

IA

1A5AN

IB

1A5AN

IC

1A5A

N

IX

1A5A

N

CBA

Positive Power

A B C

A B C

1X3.

23456789

101112

IA

1A

5AN

IB

1A5AN

IC

1A5A

N

IX

1A5A

N

CBA

Win

ding

2W

indi

ng 1

W2

W1

VT W

indi

ng S

ide=

W2

CT

Win

ding

Sid

e1C

T W

indi

ng S

ide2

CT Winding Side2

CT Winding Side1

1X6.

2345678

VX

VC/VCA

VB/VBC

VA/VAB

IM02602013E ETR-5000

Slot X100: Ethernet InterfaceRear Side of the Device (Slots)

An Ethernet interface may be available depending on the device type ordered.


Ethernet - RJ45

Terminal Marking

54 www.eaton.com

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

1 8

TxD

+

TxD

–

RxD

+

N.C

.

N.C

.

RxD

–

N.C

.

N.C

.

ETR-5000 IM02602013E

Slot X101: URTD InterfaceRear side of the device (Slots)

If the device is equipped with an URTD interface is dependent on the ordered device type.


Interface for the URTD Module

The Universal Resistance-Temperature Detector (URTD) module has to be connected to the protective device at the special fiber optic interface (1 optical slave).

Terminal MarkingInterface for the External URTD Module Interface Ext. URTD Module

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X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

IM02602013E ETR-5000

Slot X103: Data CommunicationRear Side of the Device (Slots)

The data communication interface in the X103 slot is dependent on the ordered device type. The scope of functions is dependent on the type of data communication interface.


• RS485 Terminals


56 www.eaton.com

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

ETR-5000 IM02602013E

RS485 - Modbus® RTU


Terminal Marking

Pin Assignment

The Modbus® connection cable must be shielded. The shielding has to be fixed at the screw that is marked with the ground symbol at the rear side of the device.

The communication is Half Duplex.

www.eaton.com 57

64 5321

R1R2

R1

+5V GND

R1 = 560 ΩR2 = 120 Ω

B(+)

A(-)

Protective RelayH

F Sh

ield

1X

103

2 3 4 5 6

B(+)

A(-)

+5V GND

560

Ω

560Ω120Ω

Protective Relay

HF

Shi

eld

IM02602013E ETR-5000

Wiring Example: Device in the Middle of the Bus

Wiring Example: Device at the End of the BUS (Using the Integrated Terminal Resistor)

58 www.eaton.com

64 5321

+5V GND

R1 = 560 ΩR2 = 120 Ω

Protective Relay

B(+)

A(-)

R1R2

R1

HF

Shie

ld

64 5321

+5V GND

R1 = 560 ΩR2 = 120 Ω

Protective Relay

B(+)

B(+)*

A(-)

A(-)*

R1R2

R1

HF

Shie

ld

ETR-5000 IM02602013E

Shielding Options (2-wire + Shield)

Shielding Options (3-wire + Shield)

www.eaton.com 59

1 32 4 5 6

TR-P

1 32 4 5 6

TR-P

1 32 4 5 6

TR-P

1 32 4 5 6

TR-P

Shield at bus master side connected to earth termination

resistors used

Shield at bus device side connected to earth termination

resistors used


resistors not used


resistors not used

B(+)

A(-)

B(+)

A(-)

B(+)

A(-)

B(+)

A(-)

TR-N

TR-N

TR-N

TR-N

Com

mon

Com

mon

Com

mon

Com

mon

HF S

hiel

d

HF

Shie

ld

HF S

hiel

d

HF S

hiel

d

2.2nFinternal

2.2nFinternal

2.2nFinternal

2.2nFinternal


resistors used


resistors used


resistors not used


resistors not used

1 32 4 5 6

TR-P

2.2nFinternal

1 32 4 5 6

TR-P

2.2nF(internal)

1 32 4 5 6

TR-P

1 32 4 5 6

TR-P

B(+)

A(-)

B(+)

A(-)

B(+)

A(-)

B(+)

A(-)

TR-N

TR-N

TR-N

TR-N

Com

mon

Com

mon

Com

mon

Com

mon

HF S

hiel

d

HF

Shie

ld

HF S

hiel

d

HF S

hiel

d

2.2nF(internal)

2.2nF(internal)

IM02602013E ETR-5000

Slot X104: IRIG-B00X and Supervision ContactRear Side of the Device (Slots)

This comprises the IRIG-B00X and the System contact (Supervision Contact).

System Contact and IRIG-B00X


Terminals

60 www.eaton.com

X1 X2 X3

X100 X102

X5 X6

X104

X4

X103


X101

1X1

04 2 3 4 5SC

IRIG

-B+

IRIG

-B-

ETR-5000 IM02602013E

Pin Assignment for Device

The Supervision Contact (SC) closes after the boot phase of the device if the protection is working. This Super-vision Contact (SC) will open if an internal device error has occurred (please refer to the Self Supervision sec-tion).

The System-OK contact (SC relay) cannot be configured. The system contact is a Form “C” contact that picks up when the device is free from internal faults. While the device is booting up, the System OK relay (SC) re-mains dropped-off (unenergized). As soon as the system is properly started, the System Contact picks up and the assigned LED “Operational” is activated accordingly (please refer to the Self Supervision section).

X120 - PC InterfaceThe interface is a 9-pole D-Sub at all device fronts.

Pin Assignment

Assignment of the Null Modem Cable

Assignment of the fully wired, null modem cable.

Dsub -9 (Female) Signal Dsub -9 (Female) Signal2 RxD 3 TxD3 TxD 2 RxD4 DTR 6,1 DSR, DCD6,1 DSR, DCD 4 DTR7 RTS 8 CTS

www.eaton.com 61

X1041 32 4 5

SC

N.C

.

SC N

.O.

SC

CM

N

IRIG

-B+

IRIG

-B-

1 DCD

2 RxD

3 TxD

4 DTR

5 GND

6 DSR

7 RTS

8 CTS

Housing shielded

9 RI

51

6 9

IM02602013E ETR-5000

Dsub -9 (Female) Signal Dsub -9 (Female) Signal8 CTS 7 RTS5 GND (Ground) 5 GND (Ground)9 Ring Signal 9 Ring Signal

The connection cable must be shielded.

62 www.eaton.com

ETR-5000 IM02602013E

Control Wiring Diagram

Below is the recommended control wiring schematic for the ETR-5000.

Wiring Diagrams

Please refer to the file “etr-5000_wiring_diagrams.pdf” on your manual CD.

www.eaton.com 63

X1-2

X1-13

X1-14

Protective Device

X2-8

X1-3

X1-9

X2-9

PowerSupply

86T

52-1a

52-2a

87T

-DC +DC

86Tb

X1-6

X2-3

TCM = Trip Coil Monitor

X1-5

X2-4

TCM

+DC

86T

50/51/1152-1a

52-1TC-DC

X1-8

X2-5

X1-7

X2-6

TCM

+DC

86T

50/51/1152-2a

52-2TC-DC

a

a

IM02602013E ETR-5000

Input, Output, and LED Settings

Digital Input ConfigurationThe State of the Digital Inputs can be checked within menu:

[Operations/Status Display/Name of the assembly group (e.g. DI-8X)]

The Digital Inputs can be configured within menu:

[Device Para/Digital Inputs/Name of the assembly group (e.g. DI-8X)/Group X]

Set the following parameters for each of the digital inputs:

• »Nominal voltage«;

• »Debouncing time«: A state change will only be adopted by the digital input after the debouncing time has expired; and

• »Inverting« (where necessary).

The debouncing time will be started each time the state of the input signal alternates.

In addition to the debouncing time that can be set via software, there is always a hardware debouncing time (approx 12 ms) that cannot be turned of.

64 www.eaton.com

State of the Digital Input.

Inverting

Input Signal

Nom Voltage

DI Slot X.DI x XOR

Debouncing Time

t

0

ETR-5000 IM02602013E

DI-8P XName of the Assembly group:DI-8P X1

Device Parameters of the Digital Inputs on DI-8P X

Parameter Description Setting Range Default Menu Path

Nom Voltage Nominal voltage of the digital inputs 24 V dc, 48 V dc, 60 V dc, 110/120 Vdc, 230/240 Vdc, 110/120 Vac, 230/240 Vac

110/120 Vdc [Device Para/Digital Inputs/DI-8P X1/Group 1]

Inverting 1 Inverting the input signals. Inactive, Active

Inactive [Device Para/Digital Inputs/DI-8P X1/Group 1]

Debouncing Time 1

A change of the state of a digital input will only be recognized after the debouncing time has expired (become effective). Thus, transient signals will not be misinterpreted.

No Debouncing Time, 20 ms, 50 ms, 100 ms

20 ms [Device Para/Digital Inputs/DI-8P X1/Group 1]

Nom Voltage Nominal voltage of the digital inputs 24 Vdc, 48 Vdc, 60 Vdc, 110/120 Vdc, 230/240 Vdc, 110/120 Vac, 230/240 Vac




Debouncing Time 2




Nom Voltage Nominal voltage of the digital inputs 24 Vdc, 48 Vdc, 60 Vdc, 110/120 Vdc, 230/240 Vdc, 110/120 Vac, 230/240 Vac




Debouncing Time 3




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IM02602013E ETR-5000




Debouncing Time 4






Debouncing Time 5






Debouncing Time 6






Debouncing Time 7






Debouncing Time 8




Digital Inputs Output Signals on DI-8P X

Name Description

DI 1 Signal: Digital InputDI 2 Signal: Digital InputDI 3 Signal: Digital InputDI 4 Signal: Digital InputDI 5 Signal: Digital Input

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ETR-5000 IM02602013E

Name Description

DI 6 Signal: Digital InputDI 7 Signal: Digital InputDI 8 Signal: Digital Input

Wired Inputs (Aliases)Available Elements:Wired Inputs

The module WiredInputs allows to alias Digital Inputs. By means of the menu [Device Para/WiredInputs] the User can assign specific functions on digital inputs.

Alias Example: The 52a contact will be assigned/connected to Digital input1 (DI1). Once the 52a is aliased (linked) on the DI1, the signal »WiredInput.52A« can be used instead of the DI1 signal for further processing within the protective relay. That means, from now on any state changes of the Digital Input1 will we represented by the »WiredInput.52A« signal.

Global Protection Parameter of the Wired Inputs Wired


Bkr Trouble Breaker Trouble -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8

-.- [Device Para/Wired Inputs]

52a M1 Main 1 Breaker Closed -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


52b M1 Main 1 Breaker Open -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


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IM02602013E ETR-5000


TOCa M1 Main 1 Breaker Connected -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


43/10 M1 Main 1 Breaker Selected To Trip -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


52a M2 Main 2 Breaker Closed -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


52b M2 Main 2 Breaker Open -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


TOCa M2 Main 2 Breaker Connected -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


43/10 M2 Main 2 Breaker Selected To Trip -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


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ETR-5000 IM02602013E


52a T Tie Breaker Closed -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


52b T Tie Breaker Open -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


TOCa T Tie Breaker Connected -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


43/10 T Tie Breaker Selected To Trip -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


43 M System In Manual -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


43 A System in Auto -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


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IM02602013E ETR-5000


43 P1 Preferred Source 1 -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


43 P2 Preferred Source 2 -.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8


States of the Inputs of the Wired Inputs Module

Name Description Assignment Via

Bkr Trouble-I Breaker Trouble [Device Para/Wired Inputs]

52a M1-I State of the module input: Main 1 Breaker Closed

[Device Para/Wired Inputs]

52b M1-I State of the module input: Main 1 Breaker Open


TOCa M1-I State of the module input: Main 1 Breaker Connected


43/10 M1-I State of the module input: Main 1 Breaker Selected To Trip


52a M2-I State of the module input: Main 2 Breaker Closed


52b M2-I State of the module input: Main 2 Breaker Open


TOCa M2-I State of the module input: Main 2 Breaker Connected


43/10 M2-I State of the module input: Main 2 Breaker Selected To Trip


52a T-I State of the module input: Tie Breaker Closed


52b T-I State of the module input: Tie Breaker Open


TOCa T-I State of the module input: Tie Breaker Connected


43/10 T-I State of the module input: Tie Breaker Selected To Trip


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ETR-5000 IM02602013E


43 M-I State of the module input: System In Manual


43 A-I State of the module input: System in Auto [Device Para/Wired Inputs]

43 P1-I State of the module input: Preferred Source 1


43 P2-I State of the module input: Preferred Source 2


Relay Output Contact ConfigurationThe State of the Relay Output Contacts can be checked within menu:

[Operations/Status Display/Name of the assembly group (e.g. RO-XX)]

The Relay Output Contacts can be configured within menu:

[Device Para/Relay Outputs/Name of the assembly group (e.g. RO-XX)]

Set the following parameters for each of the relay output contacts.

• Up to seven (7) signals from the »assignment list« (OR-connected).

The states of the module outputs and the signals (e.g. states of protective functions) can be assigned to the relay output contacts. The relay output contacts are “dry-type“ contacts.

• Each of the assigned signals can be inverted.

• The (collective) state of the relay output contacts can be inverted.

• By the Operating Mode it can be determined whether the relay output works in Normally »De-Energized« or »Normally Energized« principle.

• Each relay output contact can be set as »Latched« (Latched = active or inactive). A latched relay output contact will return to it's latched position after a loss of power to the protective device. A latched relay output contact will keep it´s position as long as it has not been reset and as long as the power supply feeds the protective relay. In the case of a loss of power to the protective device, the relays will return to the latched position once the power is restored to the protective device (latched = relay output contacts have a memory). A latched state of a relay output contact always needs to be reset after a power loss even if the assignments are taken away (if the assignments are reprogrammed).

• Latched = inactive«:If the latching function is »inactive«, the relay output and, respectively, the relay output contact will adopt the state of those pickups that were assigned.

• »Latched = active«:If the latching function is »active«, the state of the relay output and, respectively, the relay output contact that was set by the pickups will be stored (they have a memory that needs to be reset).

The relay output contact can only be acknowledged after reset of those signals that hadinitiated the setting of the relay and after expiration of the »t-OFF delay«.

• At signal changes, the minimal latching time (»t-OFF delay«) ensures that the relay will be maintained as picked-up or released for at least this period.

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IM02602013E ETR-5000

72 www.eaton.com

Ass

ignm

ent 1

Inve

rting

1

Assi

gnm

ent 2

Inve

rting

2

Assi

gnm

ent 3

Inve

rting

3

Assi

gnm

ent 4

Inve

rting

4

Assi

gnm

ent 5

Inve

rting

5

OR

Inact

ive

Act

ive

Latc

hedAssi

gnm

ent 6

Inve

rting

6

Assi

gnm

ent 7

Inve

rting

7

Inve

rting

OR

OR

AND

Stat

e of

the

Rel

ay

Out

put

Ackn

owle

dge

-HM

IAc

know

ledg

e-1.

.n, A

ssig

nmen

t List

Ackn

owle

dge-

Com

m

XOR

XOR

XOR

XOR

XOR

XOR

XOR

XOR

OR

Switc

h O

ff De

lay

0t-O

ff De

lay

S

Q

R1

Q

XOR

Nor

m D

e-e

ner

g

Norm

Ener

g

Ope

ratin

g M

ode

ETR-5000 IM02602013E

If the relay output contacts are configured as »Latched=active«, they will keep their position even if there is a power outage within the power supply of the protective device.

If the relay output contacts are configured as »Latched=active«, they will also retain their position even if they are reprogrammed in another way. This also applies if the relay output contacts are set to »Latched is set to inactive«. Resetting a relay output contact that has latched a signal will always require an acknowledgment.

The »System OK Relay« (watchdog) cannot be configured.

Acknowledgment Options

Relay output contacts can be acknowledged:

• Via the push-button »C« at the operating panel;

• If »Latched is active«, each relay output contact can be acknowledged by a signal (for example: It could be reset by the state of a digital input);

• Via the module »Ex Acknowledge« where all relay output contacts can be acknowledged at once if the signal for external acknowledgment that was selected from the »Assignment list« becomes true (e.g.: the state of a digital input); and

• Via Communication (Comm), all relay output contacts can be acknowledged at once.

Relay output contacts can be set by force or disarmed (for commisioning support, please refer to the “Service/Disarming the Relay Output Contacts“ and “Service/Forcing the Relay Output Contacts“ sections).

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IM02602013E ETR-5000

RO-4ZI X - SettingsRO-4Z X2 ,RO-4Z X5

RO-4 X5

Direct Commands of RO-4ZI X


DISARMED This is the second step, after the "DISARMED Ctrl" has been activated, that is required to DISARM the relay output contacts. This will DISARM those relay output contacts that are currently not latched and that are not timing out. CAUTION! RELAYS DISARMED in order to safely perform maintenance while eliminating the risk of taking an entire process off-line. (Note: Zone Interlocking and Supervision Contact cannot be disarmed). YOU MUST ENSURE that the relays are ARMED AGAIN after maintenance.

Only available if: DISARMED Ctrl = Active

Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED/RO-4Z X2]

Force all Outs By means of this function the normal Relay Output State can be overwritten (forced). The relay can be set from normal operation (relay works according to the assigned signals) to "force energized" or "force de-energized" state. Forcing all relay output contacts of an entire assembly group has precedence to forcing a single relay output.

Normal, De-Energized, Energized

Normal [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Force RO/RO-4Z X2]

Force ZI RO Signal: Forced Zone Interlocking OUT Normal, De-Energized, Energized


RO-4Z X2: Force RO1RO-4Z X5: Force RO2

By means of this function the normal Relay Output State can be overwritten (forced). The relay can be set from normal operation (relay works according to the assigned signals) to "force energized" or "force de-energized" state.







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ETR-5000 IM02602013E






Force RO4 By means of this function the normal Relay Output State can be overwritten (forced). The relay can be set from normal operation (relay works according to the assigned signals) to "force energized" or "force de-energized" state.



Global Protection Parameters of RO-4ZI X


Operating Mode

Operating Mode Norm De-energ, Norm Energ

Norm De-energ [Device Para/Relay Outputs/RO-4Z X2/RO 1]

t-Off Delay Switch Off Delay 0.00 – 300.00 s 0.2 s [Device Para/Relay Outputs/RO-4Z X2/RO 1]

Latched Defines whether the Relay Output will be latched when it picks up.

Inactive, Active

Inactive [Device Para/Relay Outputs/RO-4Z X2/RO 1]

Acknowledgment

Acknowledgment Signal - An acknowledgment signal (that acknowledges the corresponding Relay Output) can be assigned to each Relay Output. The acknowledgment-signal is only effective if the parameter "Latched" is set to active.

Only available if: Latched = Active

1..n, Assignment List -.- [Device Para/Relay Outputs/RO-4Z X2/RO 1]

Inverting Inverting of the Relay Output. Inactive, Active


Assignment 1 Assignment 1..n, Assignment List RO-4Z X2: Bkr[1].TripCmdRO-4Z X5: -.-

[Device Para/Relay Outputs/RO-4Z X2/RO 1]

Inverting 1 Inverting of the state of the assigned signal. Inactive, Active


Assignment 2 Assignment 1..n, Assignment List -.- [Device Para/Relay Outputs/RO-4Z X2/RO 1]

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Operating Mode




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Inactive, Active


Acknowledgment






Assignment 1 Assignment 1..n, Assignment List RO-4Z X2: Bkr[2].TripCmdRO-4Z X5: -.-














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Operating Mode





Inactive, Active


Acknowledgment






Assignment 1 Assignment 1..n, Assignment List RO-4Z X2: 87.TripCmdRO-4Z X5: -.-




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Assignment 2 Assignment 1..n, Assignment List RO-4Z X2: 87H.TripCmdRO-4Z X5: -.-




Assignment 3 Assignment 1..n, Assignment List RO-4Z X2: 87GD[1].TripCmdRO-4Z X5: -.-




Assignment 4 Assignment 1..n, Assignment List RO-4Z X2: 87GDH[1].TripCmdRO-4Z X5: -.-




Assignment 5 Assignment 1..n, Assignment List RO-4Z X2: 87GD[2].TripCmdRO-4Z X5: -.-




Assignment 6 Assignment 1..n, Assignment List RO-4Z X2: 87GDH[2].TripCmdRO-4Z X5: -.-







Operating Mode



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Inactive, Active


Acknowledgment


















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DISARMED Ctrl

Enables and disables the disarming of the relay output contacts. This is the first step of a two step process, to inhibit the operation or the relay output contacts. Please refer to "DISARMED" for the second step.

Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED/RO-4Z X2]

Disarm Mode CAUTION! RELAYS DISARMED in order to safely perform maintenance while eliminating the risk of taking an entire process off-line. (Note: Zone Interlocking and Supervision Contact cannot be disarmed). YOU MUST ENSURE that the relays are ARMED AGAIN after maintenance.

Permanent, Timeout

Permanent [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED/RO-4Z X2]

t-Timeout DISARM

The relays will be armed again after expiring of this time.

Only available if: Mode = Timeout DISARM

0.00 – 300.00 s 0.03 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED/RO-4Z X2]

Force Mode By means of this function the normal Relay Output States can be overwritten (forced) in case that the Relay Output is not in a disarmed state. The relays can be set from normal operation (relay works according to the assigned signals) to "force energized" or "force de-energized" state.

Permanent, Timeout

Permanent [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Force RO/RO-4Z X2]

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t-Timeout Force

The Output State will be set by force for the duration of this time. That means, for the duration of this time, the Relay Output does not show the state of the signals that are assigned on it.


0.00 – 300.00 s 0.03 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Force RO/RO-4Z X2]

Input States of RO-4ZI X


RO1.1 Module Input State: Assignment [Device Para/Relay Outputs/RO-4Z X2/RO 1]







Ack signal RO 1 Module Input State: Acknowledgment signal for the Relay Output. If latching is set to active, the Relay Output can only be acknowledged if those signals that initiated the setting are fallen back and the hold time is expired.



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Signals of RO-4ZI X

Name Description

ZI OUT Signal: Zone Interlocking OUTRO 1 Signal: Relay OutputRO 2 Signal: Relay OutputRO 3 Signal: Relay OutputRO 4 Signal: Relay OutputDISARMED! Signal: CAUTION! RELAYS DISARMED in order to safely perform

maintenance while eliminating the risk of taking an entire process off-line. (Note: Zone Interlocking and Supervision Contact cannot be disarmed). YOU MUST ENSURE that the relays are ARMED AGAIN after maintenance

Outs forced Signal: The State of at least one Relay Output has been set by force. That means that the state of at least one Relay is forced and hence does not show the state of the assigned signals.

Additional Input States of the Relay Output Contacts


RO1.1 Module Input State: Assignment [Device Para/Relay Outputs/RO-4 X5/RO 1]







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[Device Para/Relay Outputs/RO-4 X5/RO 1]













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Additional Signals of the Relay Output Contacts

Name Description

RO 1 Signal: Relay OutputRO 2 Signal: Relay OutputRO 3 Signal: Relay OutputRO 4 Signal: Relay OutputDISARMED! Signal: CAUTION! RELAYS DISARMED in order to safely perform


Outs forced Signal: The State of at least one Relay Output has been set by force. That means that the state of at least one Relay is forced and hence does not show the state of the assigned signals.

RO-4 X Settings

Direct Commands of RO-4 X


DISARMED This is the second step, after the "DISARMED Ctrl" has been activated, that is required to DISARM the relay output contacts. This will DISARM those relay output contacts that are currently not latched and that are not timing out. CAUTION! RELAYS DISARMED in order to safely perform maintenance while eliminating the risk of taking an entire process off-line. (Note: Zone Interlocking and Supervision Contact cannot be disarmed). YOU MUST ENSURE that the relays are ARMED AGAIN after maintenance.

Only available if: DISARMED Ctrl = Active

Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED/RO-4 X5]

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Force all Outs By means of this function the normal Relay Output State can be overwritten (forced). The relay can be set from normal operation (relay works according to the assigned signals) to "force energized" or "force de-energized" state. Forcing all relay output contacts of an entire assembly group has precedence to forcing a single relay output.


Normal [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Force RO/RO-4 X5]













Device Parameters of RO-4 X


Operating Mode


Norm De-energ [Device Para/Relay Outputs/RO-4 X5/RO 1]

t-Off Delay Switch Off Delay 0.00 – 300.00 s 0.2 s [Device Para/Relay Outputs/RO-4 X5/RO 1]


Inactive, Active

Inactive [Device Para/Relay Outputs/RO-4 X5/RO 1]

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Acknowledgment



1..n, Assignment List -.- [Device Para/Relay Outputs/RO-4 X5/RO 1]



Assignment 1 Assignment 1..n, Assignment List -.- [Device Para/Relay Outputs/RO-4 X5/RO 1]















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Operating Mode





Inactive, Active


Acknowledgment










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Operating Mode




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Inactive, Active


Acknowledgment



















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Operating Mode





Inactive, Active


Acknowledgment












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DISARMED Ctrl

Enables and disables the disarming of the relay output contacts. This is the first step of a two step process, to inhibit the operation or the relay output contacts. Please refer to "DISARMED" for the second step.

Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED/RO-4 X5]

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Disarm Mode CAUTION! RELAYS DISARMED in order to safely perform maintenance while eliminating the risk of taking an entire process off-line. (Note: Zone Interlocking and Supervision Contact cannot be disarmed). YOU MUST ENSURE that the relays are ARMED AGAIN after maintenance.

Permanent, Timeout

Permanent [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED/RO-4 X5]

t-Timeout DISARM

The relays will be armed again after expiring of this time.


0.00 – 300.00 s 0.03 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED/RO-4 X5]


Permanent, Timeout

Permanent [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Force RO/RO-4 X5]

t-Timeout Force



0.00 – 300.00 s 0.03 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Force RO/RO-4 X5]

Analog OutputsAvailable Elements:AnOut[1] ,AnOut[2]

The E-Series relays can be programmed to output for three different ranges of either 0- 20mA, 4- 20 mA, or 0-10 Volts.

These outputs can be configured by the User to represent the status of User programmed parameters that are available from the relay. The User will find the configuration menu for this feature under the [Device Para/ Analog Outputs] menu option. Here the User can define to which parameter the output will correlate. As with any parameter, a password is required to configure this feature.

To program this feature, the User will select the Analog Outputs option under the main menu item “Device PARA”. Then select the wrench icon which will allow the assignment of the output to a parameter monitored by the relay.

The available signals, that can be assigned onto the analog outputs are shown in the “List of Analog Outputs”.

Once the assignment has been made, the User can select the expected range of the parameter that will correlate to the analog output. The User will be required to enter a “Range min”, and “Range max”. The “Range min” will determine the value at which e.g. 4 mA will be transmitted by the relay. Likewise, the “Range max” value will determine the value that will result in the transmission of a 20 mA output. The same applies when the output is configured to 0- 10 Volts.

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Global Protection Parameters of the Analog Outputs


Assignment Assignment 1..n, AnalogOutputList AnOut[1]: VT.fAnOut[2]: -.-

[Device Para/Analog Outputs/AnOut[1]]

Range Adjustable range 0...20 mA, 4...20 mA, 0...10 V

0...20 mA [Device Para/Analog Outputs/AnOut[1]]

Range max Adjustable range maximum. -999999.00 - 999999.00°C 1.00°C [Device Para/Analog Outputs/AnOut[1]]

Range min Adjustable range minimum. -999999.00 - 999999.00°C 0.00°C [Device Para/Analog Outputs/AnOut[1]]

Force Mode For commissioning purposes or for maintenance, Analog Outputs can be set by force. By means of this function the normal Analog Outputs can be overwritten (forced).

Permanent, Timeout

Permanent [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Outputs/AnOut[1]]

t-Timeout Force

The Analog Output Value will be set by force for the duration of this time. That means for the duration of this time the Analog Output does not show the value of the signals that are assigned on it.

Only available if: Force Mode = Active

0.00 – 300.00 s 0.03 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Outputs/AnOut[1]]

Direct Commands of the Analog Outputs


Function Permanent activation or deactivation of module/element.

Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Outputs/AnOut[1]]

Force Value By means of this function the Analog Output Value can be overwritten (forced).

0.00 - 100.00% 0% [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Outputs/AnOut[1]]

Signals of the Analog Outputs

Name Description

Force Mode For commissioning purposes or for maintenance, Analog Outputs can be set by force. By means of this function the normal Analog Outputs can be overwritten (forced).

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List of the Analog Outputs

Name Description

-.- No assignmentVT.f Measured Value: FrequencyVT.VAB RMS Measured value: Phase-to-phase voltage (RMS)VT.VBC RMS Measured value: Phase-to-phase voltage (RMS)VT.VCA RMS Measured value: Phase-to-phase voltage (RMS)VT.VA RMS Measured value: Phase-to-neutral voltage (RMS)VT.VB RMS Measured value: Phase-to-neutral voltage (RMS)VT.VC RMS Measured value: Phase-to-neutral voltage (RMS)VT.VX meas RMS Measured value (measured): VX measured (RMS)VT.VR calc RMS Measured value (calculated): VR (RMS)VT.VAB THD Measured value (calculated): VAB Total Harmonic Distortion VT.VBC THD Measured value (calculated): VBC Total Harmonic Distortion VT.VCA THD Measured value (calculated): VCA Total Harmonic Distortion VT.VA THD Measured value (calculated): VA Total Harmonic Distortion VT.VB THD Measured value (calculated): VB Total Harmonic Distortion VT.VC THD Measured value (calculated): VC Total Harmonic Distortion CT W1.IA RMS Measured value: Phase current (RMS)CT W1.IB RMS Measured value: Phase current (RMS)CT W1.IC RMS Measured value: Phase current (RMS)CT W1.IX meas RMS Measured value (measured): IX (RMS)CT W1.IR calc RMS Measured value (calculated): IR (RMS)CT W1.IA THD Measured Value (Calculated): IA Total Harmonic Current CT W1.IB THD Measured Value (Calculated): IB Total Harmonic Current CT W1.IC THD Measured Value (Calculated): IC Total Harmonic Current CT W2.IA RMS Measured value: Phase current (RMS)CT W2.IB RMS Measured value: Phase current (RMS)CT W2.IC RMS Measured value: Phase current (RMS)CT W2.IX meas RMS Measured value (measured): IX (RMS)CT W2.IR calc RMS Measured value (calculated): IR (RMS)CT W2.IA THD Measured Value (Calculated): IA Total Harmonic Current CT W2.IB THD Measured Value (Calculated): IB Total Harmonic Current CT W2.IC THD Measured Value (Calculated): IC Total Harmonic Current 49.Thermal Cap Used Measured value: Thermal Capacity UsedURTD.W1-A Measured Value: Winding TemperatureURTD.W1-B Measured Value: Winding TemperatureURTD.W1-C Measured Value: Winding TemperatureURTD.W2-A Measured Value: Winding Temperature

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Name Description

URTD.W2-B Measured Value: Winding TemperatureURTD.W2-C Measured Value: Winding TemperatureURTD.Amb1 Measured Value: Ambient TemperatureURTD.Amb2 Measured Value: Ambient TemperatureURTD.Aux1 Measured Value: Auxiliary TemperatureURTD.Aux2 Measured Value: Auxiliary TemperatureURTD.Aux3 Measured Value: Auxiliary TemperatureURTD.Aux4 Measured Value: Auxiliary TemperatureURTD.RTD Max Maximum temperature of all channels.RTD.Hottest WD W1 Hottest winding on side W1RTD.Hottest WD W2 Hottest winding on side W2ECr.Syst VA RMS Measured VAs (RMS)ECr.Syst W RMS Measured Watts. Active power (P- = Fed Active Power, P+ =

Consumpted Active Power) (RMS)ECr.Syst VAr RMS Measured VARs. Reactive power (Q- = Fed Reactive Power, Q+ =

Consumpted Reactive Power) (RMS)ECr.Apt PF Measured Value (Calculated): 55A - Apparent Power FactorECr.Disp PF Measured Value (Calculated): 55D - Displacement Power FactorECr.VAh Net Net VA HoursECr.Wh Net Net Watt HoursECr.Wh Fwd Positive Active Power is consumed active energy ECr.Wh Rev Negative Active Power (Fed Energy)ECr.VArh Net Net VAr HoursECr.VArh Lag Positive Reactive Power is consumed Reactive EnergyECr.VArh Lead Negative Reactive Power (Fed Energy)

Analog InputsThese inputs can be configured by the User to represent the status of external analog values that are fed to the relay.

Using Analog Inputs is a two step procedure. The User has to configure the Measuring Elements and the Analog Protection Elements. Each Analog Input (hardware) is represented by one Measuring Element (named AnIn[x]). That means the number of Measuring Elements is equal to the number of analog inputs. The User can set for each Measuring Element the type of input (e.g. 4...20 mA). The Measuring Element will provide, based on this setting, analog values. The values that are provided by the Measuring Elements have to be assigned onto the Analog Protection Elements in order to feed them. Hence one Measuring Element can be assigned on multiple Analog Protection Elemtents. The number and names of the Analog Protection Elements are depending on the ordered device.

Examples for Analog Input Elements.

• Generator Protection Device (Example): FldC[n] - DC Field Current.• Motor Protection Device (Example): Spd[n] – Speed. • Transformer Protection Device (Example) TapV[n] - Tap Voltage.

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Each Analog Input Element is available as an Alarm and as a Trip Element.

The Configuration comprises:

Step 1 (please see section “Setting the Measuring Elements”): The first step is to set within the [Device Parameters] the type of input for each available Analog Input (Measuring Element). That means determining, what kind of measuring values will be provided by each analog input (e.g. 4...20 mA).

Step 2 (please see section “Configuring the Analog Protection Elements”): Configuring an Analog Protection Element means: Activating the "Trip and/or Alarm-Element" within the [Device Planning]. After that, the Element has to be configured within the [Protection Parameters].

Step 1 - Setting the Measuring Elements

The User can set the type of input within the [Device Para/ Analog Inputs] menu option.

• 0...20 mA• 4...20 mA• 0...10 V

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Step 2 - Configuring the Analog Protection Elements

Within the Protection Parameters [Protection Para/Global Para/Analog Inputs], the User has to select the Measuring element/Analog Input, that feeds the Analog Protection Element. The User also has to set a threshold and a tripping delay time for the Analog Protection Element. The number and Names of the Analog Input Functions that are available depend on the ordered device.

Also the Pickup Mode can be selected between »over« and »under«. The setting »over« means the relay picks up, when the analog measuring value exceeds the set threshold. The setting »under« means the relay picks up, when the analog measuring value falls below the set threshold. When the Input Type 4...20 mA is selected, the relay provides a Broken Wire Supervision. When a wire is broken, a broken wire alarm will be issued and alarm and trip commands of the Analog Protection Elements will be inhibited.

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Analog Protection Alarm Elements

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Analog Protection Trip Elements

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Measuring Elements

AnIn[1] ,AnIn[2]

Signals (Output States) of the Analog Measuring Elements

Name Description

Broken wire Signal: Broken wire. This signal is only valid, if the analog input is used in the 4..20 mA mode.

Input forced The value of analog Input has been set by force. That means that the value of the analog Input is forced and does not represent the real measured value.

Direct Commands of the Analog Measuring Elements



Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Inputs/AnIn[1]]

Force Value By means of this function the Analog Input Value can be overwritten (forced).

0.00 - 100.00% 0% [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Inputs/AnIn[1]]

Global Protection Parameters of theAnalog Measuring Elements


Updateinterv Adjustable time between value updates 0.00 – 5 s 0.04 s [Device Para/Analog Inputs/AnIn[1]]

Mode The threshold depends to the mode/ mA or V

0...20 mA, 4...20 mA, 0...10V

0...20 mA [Device Para/Analog Inputs/AnIn[1]]

Conversion Time

Conversion time needed by the ADC to sample input values.

0.00 – 0.5 s 0.01 s [Device Para/Analog Inputs/AnIn[1]]

Force Mode For commissioning purposes or for maintenance. Analog Inputs can be set by force. By means of this function the normal Analog Inputs can be overwritten (forced).

Permanent, Timeout

Permanent [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Inputs/AnIn[1]]

t-Timeout Force

The Analog Input Value will be set by force for the duration of this time. That means for the duration of this time the Analog Input does not show the value of the signals that are assigned on it.

Only available if: Force Mode = Active

0.00 – 300.00 s 0.03 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Inputs/AnIn[1]]

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Values of the Analog Measuring Elements

Value Description Menu Path

Value Measured value of the Input in percent [Operation/Measured Values/Analog Inputs]

List of the Available Measuring Inputs

Name Description

-.- No assignmentAnIn[1].Value Measured value of the Input in percentAnIn[2].Value Measured value of the Input in percent

Analog Alarm Protection Elements

Pres[2] ,Tmp1[2] ,Tmp2[2] ,Vibr[2] ,VBat[2] ,TapV[2] ,AnaP[2]

Inputs of the Analog Alarm Elements


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Analog Inputs/Pres[2]]


Signals (Output States) of the Analog Alarm Elements

Name Description

Active Signal: ActiveExBlo Signal: External BlockingPickup Signal: PickupAlarm Alarm

Setting Group Parameters of the Analog Alarm Elements



Inactive, Active

Inactive [Protection Para/<1..4>/Analog Inputs/Pres[2]]

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ExBlo Fc Activate (allow) or inactivate (disallow) blocking of the module/element. This parameter is only effective if a signal is assigned to the corresponding global protection parameter. If the signal becomes true, those modules/elements are blocked that are configured "ExBlo Fc=active".

Inactive, Active


Blo TripCmd Permanent blocking of the Trip Command of the module/element.

Inactive, Active


Pickup Threshold 0.1 - 100.0% 20% [Protection Para/<1..4>/Analog Inputs/Pres[2]]

t Tripping delay 0.00 – 10.00 s 1 s [Protection Para/<1..4>/Analog Inputs/Pres[2]]

Device Planning Parameters of the Analog Alarm Elements


Mode Mode Do not use, Use

Pres[2]: UseTmp1[2]: UseTmp2[2]: Do not useVibr[2]: Do not useVBat[2]: Do not useTapV[2]: Do not useAnaP[2]: Use

[Device Planning]

Global Protection Parameters of the Analog Alarm Elements


ExBlo1 External blocking of the module, if blocking is activated (allowed) within a parameter set and if the state of the assigned signal is true.

1..n, Assignment List -.- [Protection Para/Global Prot Para/Analog Inputs/Pres[2]]



Measuring Input

Measuring Input 1..n, AnalogOutputList -.- [Protection Para/Global Prot Para/Analog Inputs/Pres[2]]

Pickup Mode Pickup Mode Over, Under

Over [Protection Para/Global Prot Para/Analog Inputs/Pres[2]]

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Analog Trip Protection Elements

Pres[1] ,Tmp1[1] ,Tmp2[1] ,Vibr[1] ,VBat[1] ,TapV[1] ,AnaP[1]

Inputs of the Analog Trip Elements




ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command

[]

Signals (Output States) of the Analog Trip Elements

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: PickupTrip Signal: TripTripCmd Signal: Trip Command

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Setting Group Parameters of the Analog Trip Elements



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc

Activate (allow) or inactivate (disallow) blocking of the module/element. This parameter is only effective if a signal is assigned to the corresponding global protection parameter. If the signal becomes true, those modules/elements are blocked that are configured "ExBlo TripCmd Fc=active".

Inactive, Active


Pickup Threshold 0.1 - 100.0% 20% [Protection Para/<1..4>/Analog Inputs/Pres[1]]

t Tripping delay 0.00 – 10.00 s 1 s [Protection Para/<1..4>/Analog Inputs/Pres[1]]

Device Planning Parameters of the Analog Trip Elements



Pres[1]: UseTmp1[1]: UseTmp2[1]: Do not useVibr[1]: Do not useVBat[1]: Do not useTapV[1]: Do not useAnaP[1]: Use

[Device Planning]

Global Protection Parameters of the Analog Trip Elements




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ExBlo TripCmd External blocking of the Trip Command of the module/the element, if blocking is activated (allowed) within a parameter set and if the state of the assigned signal is true.


Measuring Input

Measuring Input 1..n, AnalogOutputList -.- [Protection Para/Global Prot Para/Analog Inputs/Pres[1]]

Pickup Mode Pickup Mode Over, Under

Over [Protection Para/Global Prot Para/Analog Inputs/Pres[1]]

LED ConfigurationThe LEDs can be configured within menu:

[Device Para/LEDs/Group X]

Attention must be paid to insure that there are no overlapping functions due to double or multiple LED assignment of colors and flashing codes.

If LEDs are configured as »Latched=active«, they will keep (return to) their blink code and color even if there is a power outage within the power supply of the protective device.

If the LEDs are configured as »Latched=active«, they will also retain their blink code and color even if the LEDs are reprogrammed in another way. This also applies if the LEDs are set to »Latched = inactive«. Resetting a LED that has latched a signal will always require an acknowledgment.

This chapter contains information on the LEDs that are placed on the left hand side of the display (Group A).

If your device is also equipped with LEDs on the right hand side of the display (Group B), the analog information in this chapter is valid. The only difference between “Group A” and “Group B” is within the menu paths.

Via the »INFO« push-button, it is always possible to display the current pickups and alarm texts that are assigned to an LED. Please refer to the Navigation section for a description of the »INFO« push-button functionality.

Set the following parameters for each LED.

• »Latching (self holding function)«: If »Latching« is set to »Active«, the state that is set by the pickups will be stored until it is reset. If »Latching« is set to »Inactive«, the LED always adopts the state of those

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pickups that were assigned.

• »acknowledgment«: Signal that will reset the LED.

• »LED active color«: LED lights up in this color when at least one of the allocated functions is valid (red, red-flashing, green, green flashing, off).

• »LED inactive color«: LED lights up in this color when none of the allocated functions is valid (red, red-flashing, green, green flashing, off).

• »Assignment 1...n« Apart from the LED for System OK (Operational), each LED can be assigned up to five functions (e.g. pickups) out of the »Assignment list«.

• »Inverting an Assignment 1...n«: This will invert the input signal.

Acknowledgment Options

LEDs can be acknowledged by:

• The push-button »C« at the operating panel;

• A signal from the »LED Reset list« (e.g. digital inputs or communication signals) (If »Latched = active«);

• The »Ex Acknowledge« module - all LEDs can be acknowledged at once, if the signal for external acknowledgment becomes true (e.g.: the state of a digital input); and

• Communication (Comm) - all LEDs can be acknowledged at once.

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The »System OK (Operational) « LEDThis LED flashes green while the device is booting. After booting is complete, the LED for System OK (Operational) lights up in green signaling that the protection (function) is »activated«. If, however, in spite of successful booting, or after the third unsuccessful reboot caused by the self supervision module, the Operational LED (System OK) flashes in red or is solidly illuminated in red, please contact your Eaton Corporation Customer Service Representative (also see the Self Supervision section).

The Operational LED (System OK) cannot be configured.

LED SettingsLEDs group A ,LEDs group B

Device Parameters of the LEDs


Latched Defines whether the LED will be latched when it picks up.

Inactive, Active

Inactive [Device Para/LEDs/LEDs group A/LED 1]

Ack signal Acknowledgment signal for the LED. If latching is set to active the LED can only be acknowledged if all signals that initiated the setting of the LED are no longer present.

Dependency Only available if: Latched = Active

1..n, Assignment List -.- [Device Para/LEDs/LEDs group A/LED 1]

LED Active Color

The LED lights up in this color if the state of the OR-assignment of the signals is true.

Green, Red, Red flash, Green flash, -

LEDs group A: Red flashLEDs group B: Red

[Device Para/LEDs/LEDs group A/LED 1]

LED Inactive Color

The LED lights up in this color if the state of the OR-assignment of the signals is false.


LEDs group A: -LEDs group B: Green


Assignment 1 Assignment 1..n, Assignment List LEDs group A: 50P[1].PickupLEDs group B: Bkr[1].Pos CLOSE




Assignment 2 Assignment 1..n, Assignment List LEDs group A: 51P[1].PickupLEDs group B: -.-


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Assignment 3 Assignment 1..n, Assignment List LEDs group A: 50R[1].PickupLEDs group B: -.-








Assignment 5 Assignment 1..n, Assignment List LEDs group A: 51Q[1].PickupLEDs group B: -.-





Inactive, Active





LED Active Color



LEDs group A: Red flashLEDs group B: Red


LED Inactive Color



LEDs group A: -LEDs group B: Green


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Assignment 1 Assignment 1..n, Assignment List LEDs group A: 51P[3].PickupLEDs group B: Bkr[2].Pos CLOSE




Assignment 2 Assignment 1..n, Assignment List LEDs group A: 51X[2].PickupLEDs group B: -.-








Assignment 4 Assignment 1..n, Assignment List -.- [Device Para/LEDs/LEDs group A/LED 2]







Inactive, Active

LEDs group A: ActiveLEDs group B: Inactive





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LED Active Color



LEDs group A: RedLEDs group B: Red flash


LED Inactive Color



- [Device Para/LEDs/LEDs group A/LED 3]

Assignment 1 Assignment 1..n, Assignment List LEDs group A: 50P[1].TripCmdLEDs group B: 87.H2,H4,H5 Blo




Assignment 2 Assignment 1..n, Assignment List LEDs group A: 51P[1].TripCmdLEDs group B: 87.Blo H2




Assignment 3 Assignment 1..n, Assignment List LEDs group A: 50R[1].TripCmdLEDs group B: 87.Blo H4




Assignment 4 Assignment 1..n, Assignment List LEDs group A: 51R[1].TripCmdLEDs group B: 87.Blo H5




Assignment 5 Assignment 1..n, Assignment List LEDs group A: 51Q[1].TripCmdLEDs group B: -.-




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Inactive, Active

Active [Device Para/LEDs/LEDs group A/LED 4]




LED Active Color



Red [Device Para/LEDs/LEDs group A/LED 4]

LED Inactive Color




Assignment 1 Assignment 1..n, Assignment List LEDs group A: 51P[3].TripCmdLEDs group B: 27M[1].TripCmd




Assignment 2 Assignment 1..n, Assignment List LEDs group A: 51X[2].TripCmdLEDs group B: 27A[1].TripCmd




Assignment 3 Assignment 1..n, Assignment List LEDs group A: 51R[2].TripCmdLEDs group B: 59M[1].TripCmd




Assignment 4 Assignment 1..n, Assignment List LEDs group A: -.-LEDs group B: 59A[1].TripCmd




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Inactive, Active





LED Active Color




LED Inactive Color




Assignment 1 Assignment 1..n, Assignment List LEDs group A: 87.TripCmdLEDs group B: 81[1].TripCmd




Assignment 2 Assignment 1..n, Assignment List LEDs group A: 87H.TripCmdLEDs group B: 81[3].TripCmd




Assignment 3 Assignment 1..n, Assignment List LEDs group A: -.-LEDs group B: 81[5].TripCmd




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Inactive, Active





LED Active Color




LED Inactive Color




Assignment 1 Assignment 1..n, Assignment List LEDs group A: 87GD[1].TripCmdLEDs group B: 24[1].TripCmd




Assignment 2 Assignment 1..n, Assignment List LEDs group A: 87GDH[1].TripCmdLEDs group B: -.-


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Inactive, Active

LEDs group A: ActiveLEDs group B: Inactive





LED Active Color



LEDs group A: RedLEDs group B: Green flash


LED Inactive Color




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Assignment 1 Assignment 1..n, Assignment List LEDs group A: Prot.TripLEDs group B: Sys.Maint Mode Active
















LED Input States


LED1.1 Module Input State: LED [Device Para/LEDs/LEDs group A/LED 1]

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Acknow Sig 1 Module Input State: Acknowledgment Signal (only for automatic acknowledgment).











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Front PanelThe following illustration applies to protective devices with a small display:

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1 2 3

5

76 8 10

RS232 Interface (PowerPort-E Connection)

ACK/RST-keyINFO Key (Signals/Messages)

Control

Softkeys

DisplayLED »System OK« Programmable LEDs

9

OK-key

4

Programmable LEDs

ProtectiveDevice

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The following illustration applies to protective devices with a large display:

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1 2 3

5

68 7 10

Control

Softkeys

DisplayLED »System OK« Programmable LEDs

9

OK-key

4

Programmable LEDs

ProtectiveDevice

INFO Key (Signals/Messages)

ACK/RST-keyRS232 Interface (PowerPort-E Connection)

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Item Graphic Name Description

1

(Example for an insert)

Group A: Programmable LEDs

Basically, there are 14 programmable LEDs (7 on the left, 7 on the right side)provided for User to configure. The choice for each programmable LED can be any signal from the global assignment list, which includes all internal operation states of each function activated. Based on the application need, up to 14 (but not necessarily all) programmable LEDs can be activated. By properly configuring some or all 14 LEDs, the User will be able to view the relay's overall operation and some critical information immediately and intuitively without having to access any menu.

2 LED »System OK«

Should the LED »System OK« flash red during operation, contact Customer Support immediately.

3 Display Via the display, the User can view operational data and edit the parameters.

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4

(Example for an insert)

Group B: Programmable LEDs

Basically, there are 14 programmable LEDs (7 on the left, 7 on the right side)provided for User to configure. The choice for each programmable LED can be any signal from the global assignment list, which includes all internal operation states of each function activated. Based on the application need, up to 14 (but not necessarily all) programmable LEDs can be activated. By properly configuring some or all 14 LEDs, the User will be able to view the relay's overall operation and some critical information immediately and intuitively without having to access any menu.

5 Softkeys The function of the »SOFTKEYS« changes. Their active functions appear on the bottom line of the display.

Possible functions are:

• Navigation;

• Parameter decrement/increment;

• Scrolling up/down a menu page;

• Moving to a digit; and

• Change into the parameter setting mode »Wrench Symbol«.

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6 INFO Key (Signals/Messages)

Looking through the present LED assignment. The Direct Select key can be activated at any time. If the INFO key is actuated again, the User will leave the LED menu.

Here only the first assignments of the LEDs will be shown. Every three seconds the »SOFTKEYs« will be shown (flashing).

Displaying the Multiple Assignments

If the INFO key is pressed, only the first assignments of any LED is shown. Every three seconds the »SOFTKEYs« will be shown (flashing).

If there is more than one signal assigned to an LED (indicated by three dots), the User can check the state of the multiple assignments by proceeding as follows.

In order to show all (multiple) assignments, select an LED by means of the »SOFTKEYs« »up« and »down«.

Via the »Softkey« »right«, call up a sub-menu of this LED that gives the User detailed information on the state of all signals assigned to this LED. An arrow symbol points to the LED whose assignments are currently displayed.

Via the »SOFTKEYs« »up« and »down«, the User can call up the next / previous LED.

In order to leave the LED menu, press the »SOFTKEY« »left« multiple times.

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7 »ACK/RST- Key« Used to abort changes and to acknowledge messages as well as resetting counters.

In order to reset, press the Softkey »Wrench« and enter the password.

The User can exit the reset menu by pressing the Softkey »Arrow-left«

8 RS232 Interface (PowerPort-E Connection)

Connection to the computer/software PowerPort-E is done via the RS232 interface.

9 »OK Key« When using the »OK« key, parameter changes are temporarily stored. If the »OK« key is pressed again, those changes are stored indefinitely.

10 »CTRL Key« Access to the Control menu (not available in all devices)

Basic Menu ControlThe graphic User interface is equivalent to a hierarchical structured menu tree. For access to the individual sub-menus, the »SOFTKEYS«/Navigation Keys are used. The function of the »SOFTKEYS« can be found near the bottom of the display.

Softkey Description• Via »SOFTKEY« »Up«, the User will be taken to the prior menu point/one parameter up by

scrolling upwards.• Via »SOFTKEY« »Left«, the User will be taken one step back.

• Via »SOFTKEY« »Down«, the User will be taken to the next menu point/one parameter down by scrolling downwards.

• Via »SOFTKEY« »Right«, the User will be taken to a sub-menu.

• Via »SOFTKEY« »Top of List«, the User will be taken directly to the top of a list.

• Via »SOFTKEY« »Bottom of List«, the User will be taken directly to the end of a list.

• Via »SOFTKEY« »+«, the related digit will be incremented. (Continuous pressure -> fast).

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Softkey Description• Via »SOFTKEY« »-«, the related digit will be decremented. (Continuous pressure -> fast)

• Via »SOFTKEY« »Left«, the User will be taken one digit to the left.

• Via »SOFTKEY« »Right«, the User will be taken one digit to the right.

• Via »SOFTKEY« »Parameter Setting«, the User will call up the parameter setting mode.

• Via »SOFTKEY« »Delete«, data will be deleted.

• Fast forward scrolling is possible via »SOFTKEY« »Fast forward«

• Fast backward scrolling is possible via »SOFTKEY« »Fast backward«

In order to return to the main menu, just keep pressing the Softkey »Arrow-Left« until you arrive at the »Main Menu».

PowerPort-E Keyboard CommandsThe User can control PowerPort-E alternatively by means of keyboard commands (instead of the mouse).

Key Description

á Move up within the navigation tree or parameter list.

â

Move down within the navigation tree or parameter list.

ß

Collapse the tree item or select a folder on a higher level.

à Expands the tree item or selects a sub-folder.

Numpad + Expands the tree item.

Numpad - Collapses the tree item.

Home Moves to the top of the active window.

End Moves to the bottom of the active window.

Ctrl+O Opens the file opening dialog. Allows browsing through the file system for an existing device file.

Ctrl+N Creates a new parameter file by means of a template.

Ctrl+S Saves the actual loaded parameter file.

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Key Description

F1 Displays the on-line help information.

F2 Loads device data.

F5 Reloads the displayed data of a device.

Ctrl+F5 Enables the automatic refresh.

Ctrl+Shift+T Moves back to the navigation window.

Ctrl+F6 Walks through the tabular forms (detail windows).

Page á Moves to the previous value (parameter setting).

Page â Moves to the next value (parameter setting).

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PowerPort-EPowerPort-E is software that is used to configure a device and read data from a device. PowerPort-E provides the following:

• Menu controlled parameter setting including validity checks;• Off-line configuration of all relay types;• Reading and evaluation of statistical data and measuring values;• Commissioning Support (Forcing Relays, Disarming Relays);• Display of the device status; and• Fault analysis via event and fault recorder.

PowerPort-E 3.0 or higher supports reading parameter files generated by older versions of PowerPort-E. Parameter files generated by PowerPort-E 3.0 and higher cannot be read by older versions of PowerPort-E.

Installation of PowerPort-E

Port 52152 must not be blocked by a Firewall. If it is, the connection will be blocked.

If the Windows Vista User Access Control pops up while installing PowerPort-E, please “Allow” all installation requirements concerning PowerPort-E.

System Requirements: Windows 2000, Windows XP, Windows Vista, or Windows 7).

To install PowerPort-E:

• Double-click on the installation file with the left mouse button.

• Confirm by pressing the »Continue« button in the INFO frame.

• Select an installation path or confirm the standard installation path by mouse click on the »Continue« button.

• Confirm the entry for the suggested installation folder by mouse click on the »Continue« button.

• Start the installation process by mouse click on the »Install« button.

• Finish the installation procedure by mouse click on the »Complete« button.

If the suggested installation folder was chosen in the procedure above, the User can now call up the program via

[Start > Programs > Eaton Relays> PowerPort-E].

Uninstalling PowerPort-EVia the [Start>System Control >Software] menu, the PowerPort-E application can be uninstalled from the com-puter.

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Setting Up the Serial Connection PC - Device

Set Up a Connection Via Serial Interface Under Windows 2000

After installation of the software, the »Connection PC/Notebook to the Device« has to be initially configured so that the User is able to read device data or re-write them into the device by means of the PowerPort-E application.

To connect the device to the User's PC/notebook, a special null modem cable is needed (no serial cable!- -please refer to the section »Null Modem Cable«).

If the PC/notebook does not have a serial interface, the User will need a special USB-to-serial-adapter. If the USB-to-serial-adapter is correctly installed, communication with the device can be established using the CD provided (see the next section).

The connection of the PC/notebook to the device MUST NOT be protected/encrypted via a smartcard.

If the network connection wizard asks to encrypt the connection via a smartcard or not, please choose »Do not use the smartcard«.

Setting Up/Configuring the Connection

• Connect the PC/notebook with the device via a null modem cable.

• Start the PowerPort-E application.

• Select the menu point »Device Connection« in the »Settings« menu.

• Click on »Serial Connection«.

• Click the »Settings« button.

• When initially setting up the connection, a dialog window appears with the information that, so far, a direct connection with your protection device has not been established. Click on »Yes«.

• If, to this point, a location has not been set up on your PC, your location information has to be put in. Confirm the pop-up window »Telephone and Modem Options« with »OK«.

• The Windows network connection assistant appears after the location information is set up. Select the connection type »Establish direct connection to another computer«.

• Select the serial interface (COM-Port) where the device shall be connected.

• Select »To be used for all Users« in the »Availability of the connection« window.

• Do not change the connection name appearing in window »Name of the connection« and click the button »Complete«.

• Finally, you arrive again in the window »Device Installation« from where you started establishing the connection. Confirm the adjustments by clicking the »OK« button.

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Due to a problem in Windows 2000, it is possible that the automatically made communication settings are not correctly adopted. In order to overcome this problem, proceed as follows after setting up the serial connection.


• Select »Serial Connection«.

• Click on the »Settings« button.

• Change the register card to »General«.

• Ensure that »Communication cable between two computers Com X« is selected in the »Drop Down Menu«. X = the interface number where the User has connected the null modem cable.

• Click the »Configure« button.

• Ensure that the »Hardware Flowing Control« is activated.

• Ensure that a baud rate »115200« is selected.

Set Up a Serial Connection Via Serial Interface Under Windows XP

After installation of the software, the »Connection PC/Notebook to the Device« has to be initially configured so that the User is able to read device data or re-write them into the device by means of the PowerPort-E application.

To connect the device to the User's PC/notebook, a special null modem cable is needed (no serial cable!- -please refer to the section »Null Modem Cable«).

If the PC/notebook does not have a serial interface, the User will need a special USB-to-serial-adapter. If the USB-to-serial-adapter is correctly installed, communication with the device can be established using the CD provided (see the next section).

Setting Up/Configuring the Connection

• Connect your PC/notebook with the device via a null modem cable.

• Start the PowerPort-E application.


• Click on »Serial Connection«.


• When initially setting up the connection, a dialog window appears with the information that, so far, a direct connection with your protection device has not been established. Click on »Yes«.

• If, to this point, a location has not been set up on your PC, your location information has to be put in. Confirm the following pop-up window »Telephone and Modem Options« by selecting »OK«.

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• The Windows network connection assistant appears after the location information is set up. Select the connection type »Establish direct connection to another computer«.

• Select the serial interface (COM-Port) where the device will be connected.

• Select »To be used for all Users« in the »Availability of the connection« window.

• Do not change the connection name appearing in the »Name of the connection« window and click the »Complete« button.

• Finally, you arrive again in the »Device Installation« window where you started establishing the connection. Confirm the adjustments by clicking the »OK« button.

Set up a Connection Via Serial Interface Under Windows Vista or Windows 7

Establishing the connection between PowerPort-E and the device is a three step procedure.

1. Installing PowerPort-E (the application itself)

2. Installing a (virtual) modem (that is a precondition for TCP/IP communication via a null modem cable)/(to be done within the Windows Phone and Modem dialog).

3. Establishing a network connection between PowerPort-E and the device (to be done within PowerPort-E).

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RS232

Parameter Setting and Evaluation via Serial/RS232

PowerPort-E

Protective Relay

Device Example

ETR-5000 IM02602013E

1. Installation of PowerPort-E (the application itself).

• Refer to the “Installation of PowerPort-E” (earlier in this section).

2. Installation of the (virtual) modem.

• Open the Windows Start menu and type “Phone and Modem” and RETURN.• This opens the “Phone and Modem” Dialog.• Go to the »Modem« tab.• Click on the »Add« button.• The Hardware Wizard window “Install New Modem” pops up.• Set the check box “Don´t detect my modem; I will select it from a list”.• Click on the »Next« button.• Select Communications cable between two computers.• Click on the »Next« button.• Choose the correct COM-Port.• Click on the »Next« button.• Click on the »Finish« button.• Select the new added modem and click on the »Properties« button.• Go to the »General« tab.• Click on the »Change settings« button.• Go to the »Modem« tab.• Within the Drop-Down Menu, set the correct baud rate = 115200.• Close this dialog with the »OK« button.• Close the Phone and Modem dialog with the »OK« button.• You have to reboot your computer now!

3. Establishing a network connection between PowerPort-E and the device.

• Connect the device to the PC/notebook via a correct null modem cable.• Run PowerPort-E.• Call up »Device Connection« within the menu »Device Connection«.• Click on the »Settings« button.• A connection wizard will pop up asking you How do you want to connect.• Choose »Dial-up«.• The telephone number must not be empty. Please enter any number (e.g. 1).• The User name and password can be ignored.• Click on the »OK« button.

Establishing the Serial Connection Via a USB-/RS232-Adapter

If your PC/notebook does not have an RS-232 interface, an USB-/RS232-Adapter+Null Modem Cable can be used.

Only an adapter approved by Eaton Corporation may be used. First install the adapter (with the related driver that you can find on the CD) and then establish the connection (PowerPort-E => Device). The adapters must support very high speed data transfer.

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USB/RS232 Cable Assemblies:

Style Number Description

66B2214G01 Null Modem Cable66B2214G02 USB to RS232 Adapter66B2214G03 Null modem and USB to RS232 Adapter

Set-up a Connection Via Ethernet - TCP/IP

Warning: Mixing up IP Addresses

(In case there is more than one protective device within the TCP/IP network or establishing an unintentional wrong connection to a protective device based on a wrong entered IP address.

Transferring parameters into the wrong protective device might lead to death, personal injury, or damage of electrical equipment.

In order to prevent faulty connections, the User MUST document and maintain a list with the IP addresses of any switchboard/protective devices.

The User MUST double check the IP addresses of the connection that is to be established. That means, the User MUST first read out the IP address at the HMI of the device (within menu [Device para/TCP IP]) then compare the IP address with the list. If the addresses are identical, establish the connection. If they are not, DO NOT establish the connection.

Establishing a connection via TCP/IP to the device is only possible if your device is equipped with an Ethernet Interface (RJ45).

Contact your IT administrator in order to establish the network connection.

Part 1: Set the TCP/IP Parameters at the panel (Device).

Call up the »Device parameter/TCP/IP« menu at the HMI (panel) and set the following parameters:

• TCP/IP address;

• Subnet mask; and

• Gateway.

Part 2: Setting the IP address within PowerPort-E

• Call up the menu Settings/Device Connection within PowerPort-E.

• Set the radio button Network Connection.

• Enter the IP-Address of the device that should be connected.

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Parameter Setting and Evaluation via TCP/IP

PowerPort-E

IP-A

ddre

ss

Device Example

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Or:

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Protective Relay...

TCP/IP

TCP/IP

TCP/IP

Parameter Setting and Evaluation via TCP/IP

PowerPort-E

IP-A

dd

ress

IP-A

ddre

ss

IP-A

dd

ress

TCP/IP

Ethernet

Device Example

Device Example

Device Example

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Set-up a Connection Via Modbus Tunnel

Establishing a connection via a Gateway (TCP/IP)/Modbus RTU to the device is only possible if your device is equipped with an Ethernet Interface (RJ45).


Part 1: If you don´t know the Slave ID of the device that should be connected via Modbus Tunnel, it can be read out at the device.

• Call up the menu »Device parameter/Modbus« at the HMI (panel) and read out the Slave ID:

Part 2: Setting the IP address of the gateway and the Slave ID of the device that is to be connected via Modbus tunnel using PowerPort-E

• Call up the menu Settings/Device Connection within PowerPort-E.

• Set the radio button Modbus TCP Gateway.

• Enter the IP-Address of the device that should be connected.

• Enter the Slave ID of the device.

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Protective Relay ...

TCP/IP

Modbus RTU

Modbus RTU

Parameter Setting and Evaluation via Modbus Tunnel

PowerPort-E

Power Xpert Gateway

SLA

VE

ID 2

SLA

VE

ID 3

SLA

VE

ID n

IP-Address

Modbus RTU

Device Example

Device Example

Device Example

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PowerPort-E Troubleshooting

• Make sure that the Windows service Telephony is started. In [Start>System Control >Administration >Services] the service »Telephony« must be visible and must have been started. If not, the service has to be started.

• For establishing the connection, the User needs to have sufficient rights (administration rights).

• If a firewall is installed on your computer, TCP/IP port 52152 must have been released.

• If your computer does not have a serial interface, the User needs a USB-to-serial-adapter, approved by Eaton Corporation. This adapter has to be properly installed.

• Ensure that a null modem cable is used (a standard serial cable without control wires does not enable communication).

If a serial interface connection can not be established, and the User is running a Windows XP Operating System, the following may be the cause.

If a serial interface was selected in the connection assistant, it may be that this is not entered correctly in the dial-up network due to a bug in the Windows operating system. Your attention is drawn to this problem by the operational software and the error message »Warning, invalid connection setting« will be shown.

To solve this problem, you need administration rights.

Please proceed as follows.

• Select the menu item »Device Connection« in the »Settings« menu.

• Select »Serial Connection«.


• Change the register card to »General«.

• Ensure that »Communication cable between two computers (Com X)« is selected in the Drop Down menu. »X« = the interface number where the null modem cable is connected.

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If the message »Warning, invalid connection settings« appears during establishment of the connection, it indicates that the connection adjustments chosen are not correct.

If this warning is displayed, the User may respond as follows.

»Yes«: (to set up a completely new connection).By selecting »Yes«, all adjustments are canceled and the connection assistant is opened again for renewed adjustment of the connection to the device.

This procedure is advisable in case basic adjustments cannot be modified via the characteristics dialog (e.g.: if a new additional serial interface has been installed on the system).

»No«: (to modify the existing dial-up network entry).Selecting »No« opens the dialog for characteristics of the connection settings. During the dialog, it is possible to correct invalid settings (e.g.: the recommended baud rate).

»Cancel«:The warning is ignored and the connection adjustments remain as they are set. This procedure is accepted for a limited time, but the User is required to establish a correct connection at a later time.

PowerPort-E Persistent Connection Problems

In the case of persistent connection problems, the User should remove all connection settings and establish them again. In order to remove all connection settings, please proceed as follows.

1. Remove the Settings for the Dial-up Network.

• Close PowerPort-E.

• Call up the »Control Panel«.

• Choose »Network & Internet«.

• On the left side, click on »Manage Network Connections«.

• Right click on »"Protective Device Name" Direct Connection«.

• Choose »Delete« from the shortcut menu.

• Click on the »OK« button.

2. Remove the (Virtual) Modem.

• Call up the »Control Panel«.

• Choose »Hardware & Sound«.

• Choose »Phone & Modem Options«.

• Go to the »Modem« tab.

• Click on the correct (in case there is more than one) entry »Connection cable between two computers«.

• Click on the »Remove« button.

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Loading of Device Data When Using PowerPort-E• Start the PowerPort-E application.

• Make sure the connection has been established properly.

• Connect your PC with the device via a null modem cable.

• Select »Receiving Data From The Device« in the »Device« menu.

Restoring Device Data When Using PowerPort-E

By selecting the »Transfer only modified parameters into the device« button, only modified parameters are transmitted into the device.

Parameter modifications are indicated by a red “star symbol” in front of the parameter.

The star symbol (in the device tree window) indicates that parameters in the opened file (within PowerPort-E) differ from parameters stored on your local hard disk.

By selecting the »Transfer only modified parameters into the device« button, the User can transmit all parameters that are marked by this symbol.

If a parameter file is saved on the local hard drive, these parameters are no longer classified to be modified and cannot be transmitted via the »Transfer only modified parameters into the device« button.

In case the User has loaded and modified a parameter file from the device and saved it to the local hard drive without transferring the parameters into the device beforehand, the User cannot use the »Transfer only modified parameters into the device« button. In this case, use the »Transfer all parameters into the device« button.

The »Transfer only modified parameters into the device« button only works if modified parameters are available in the PowerPort-E application.

In contrast, all parameters of the device are transferred when the »Transfer all parameters into the device« button is pressed (provided all device parameters are valid).

• In order to (re-)transfer changed parameters into the device, select »Transfer all parameters into the device« in the »Device« menu.

• Confirm the safety inquiry »Shall the parameters be overwritten into the device?«.

• Enter the password for setting parameters in the pop-up window.

• The changed data is transferred to the device and adopted.

• Confirm the inquiry »Parameters successfully updated?«. It is recommended to save the parameters into a local file on your hard drive. Confirm »Shall The Data Be Saved Locally?“« with »Yes« (recommended). Select a suitable folder on the hard disk.

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• Confirm the chosen folder by clicking »Save«.

• The changed parameter data are now saved in the chosen folder.

Backup and Documentation When Using PowerPort-EHow to Save Device Data on a PC

Click on »Save as ...« in the »File« menu. Specify a name, choose a folder on the hard disk, and save the device data accordingly.

Printing of Device Data When Using PowerPort-E (Setting List)

The »Printing« menu offers the following options:

• Printer settings;• Page preview;• Printing; and • Exporting the selected print range into a "txt" file.

The printing menu of the PowerPort-E software offers different types of printing ranges.

• Printing of the complete parameter tree:All values and parameters of the present parameter file are printed.

• Printing of the displayed working window: Only the data shown on the relevant working window are printed (i.e.: this applies, if at least one window is opened).

• Printing of all opened working windows:The data shown on all windows are printed (i.e.: this applies only if more than one window is opened).

• Printing of the device parameter tree as from a shown position on:All data and parameters of the device parameter tree are printed as from the position/marking in the navigation window. Below this selection, the complete name of the marking is additionally displayed.

Exporting Data as a “txt” File Via PowerPort-E

Within the print menu [File>Print], the User can choose »Export into File« in order to export the device data into a “txt” file.

When exporting data, only the actual selected printing range will be exported into a “txt” file. That means that if the User has chosen the “Complete device parameter tree” printing range, then the “Complete device parameter tree” will be exported. But, if the User has chosen the “Actual working window” printing range, only that range of data will be exported.

This is the only method available to export data via PowerPort-E.

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If the User exports a “txt” file, the content of this file is encoded as Unicode. That means that, if the User wants to edit this file, the application must support Unicode encoded files (e.g.: Microsoft Office 2003 or higher).

Off-line Device Planning Via PowerPort-E

In order to be able to transmit a parameter file (e.g.: created off-line) into the device, the following information must be located:

• Type code (written on the top of the device/type label); and

• Version of the device model (can be found in menu [Device Parameters\Version].

The PowerPort-E application also enables the User to create a configuration/parameter file off-line using a “Device Model”. The advantage of using a device model is that the User can pre-configure a device by setting parameters in advance.

The User can also read the parameter file out of the device, further process it off-line (e.g.: from the office) and finally re-transfer it to the device.

The User can either:

• Load an existing parameter file from a device (please refer to the Section “Loading Device Data When Using PowerPort-E");

• Create a new parameter file (see below); or• Open a locally saved parameter file (backup).

In order to create a new device/parameter file by way of a device template off-line.

• In order to create a new off-line parameter file, select »Create new parameter file« within the »File« menu.

• A working window pops- up. Please make sure that you select the right device type with the correct version and configuration.

• Finally click on »Apply«.

• In order to save the device configuration, select »Save« out of the »File« menu.

• Within the »Modify Device Configuration (Typecode)« menu, the User can modify the device configuration or simply find out the type code of the current selection.

If the User wants to transfer the parameter file into a device, please refer to Section “Restoring Device Data When using PowerPort-E”.

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Signal SourcesSignal Sources - General

Configuring the AC signal sources requires at first the correct settings for each current and voltage transformer within the [System Parameters]. The User has to set the rated primary and secondary currents for current transformers and the rated primary and secondary voltages as well as the connection type »Main VT con« for the voltage transformers.

Measured Values Signal Sources of Voltage based Elements

Since the protective device offers one voltage measuring card, the User has to specify the location, that means the winding side, on which the voltage transformers are located. These settings have to be done within the [System Parameters]. By means of parameter »VT Winding Side« the User has to set the location of the phase voltage transformers. By means of parameter VX Winding Side« the User has to set the location of the ground/auxiliary voltage transformers.

Measured Values Signal Sources of Current based Elements

Since the protective device offers two current measuring cards, the User has to specify the signal source, that means the winding side, for each protective element that uses current measuring quantities only. This has to be done within each protective element by means of the parameter »CT winding side«.

Signal Sources of Breaker Wear Elements

Please note, that the breaker wear element [1] is always fed by winding side 1. The breaker wear element [2] is always fed by the currents of winding 2.

Signal Sources for Protective Elements Based on Current and Voltage Measurement

The VT location determines the winding, from which all measuring quantities (voltage and current) will be taken for protective elements and measuring values, that are working based on phase voltage and phase current measurement (like power elements).

Signal Sources for the Directional Feature of Phase Currents

Once that the signal sources of the measuring quantities are set, the User has to take care of the directional features.

Please note, that the directional feature elements are using the measuring quantities from the side, where the voltage transformer(s) are located. Directional phase overcurrent elements can be used only on those winding side where voltage transformers are located. In order to prevent malfunction, the User has to ensure within the device planning, that the used phase overcurrent elements are set to »non-directional« on that winding side, where no voltage transformers are mounted.

Signal Sources for the Directional Feature of the Ground Current

Directional Feature for Calculated Ground Current

The installation of the VT/VX is sometimes critical for the correct direction decision. The selection of the two quantities that are taken into account for the direction decision are depending on the location of the voltage transformers. For the ground direction detection one of the two settings »VT Winding Side« or »VX Winding Side« will be taken into account. Which setting is used, depends on the »IR Dir Cntrl« setting and on the »3V0 Source« setting.

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50R/51R Direction Decision by Angle Between:

Directional Feature depends on:

[System Para/Direction]:

IR Dir Cntrl =


3V0 Source =Residual current and neutral voltage:IR, 3V0 (measured)

»VX Winding Side« IR 3V0 Measured

Residual current and neutral voltage:IR, 3V0 (calculated)

»VT Winding Side« IR 3V0 Calculated

Residual current and neutral/ground currentIR, IX

»VX Winding Side« IR IPol Not applicable

Residual current and neutral/ground current (preferred), residual current and neutral voltage (alternatively):IR, IX (if available)else:IR, 3V0 (measured)

»VX Winding Side« IR Dual Measured

Residual current and neutral/ground current (preferred), residual current and neutral voltage (alternatively):IR, IX (if available)else:IR, 3V0 (calculated)

»VX Winding Side«

and

»VT Winding Side«

IR Dual Calculated

Negative sequence voltage and currentI2, V2

»VT Winding Side« IR Neg Not applicable

Please refer to section “Directional Features for Calculated (IR) Ground Fault Elements 50R/51R”.

Directional Feature for Measured Ground Current

The installation of the VT/VX is sometimes critical for the correct direction decision. The selection of the two quantities that are taken into account for the direction decision are depending on the location of the voltage transformers. For the ground direction detection one of the two settings »VT Winding Side« or »VX Winding Side« will be taken into account. Which setting is used, depends on the »IX Dir Cntrl« setting and on the »3V0 Source« setting.

The following table gives the User a quick overview of the all possible directional settings.

50X/51X Direction Decision by Angle Between:



IX Dir Cntrl =


3V0 Source =Measured ground current and neutral voltage:IX, 3V0 (measured)

»VX Winding Side« IX 3V0 Measured

Measured ground current and neutral voltage:IX, 3V0 (calculated)

»VT Winding Side« IX 3V0 Calculated


»VT Winding Side« IX Neg Not applicable

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IX Dir Cntrl =


3V0 Source =Negative phase sequence current and voltage (preferred), measured ground current and neutral voltage (alternatively):I2, V2 (if available)else:IX, 3V0 (measured)

»VT Winding Side«

and

»VX Winding Side«

IX Dual Measured

Negative phase sequence current and voltage (preferred), measured ground current and neutral voltage (alternatively):I2, V2 (if available)else:IX, 3V0 (calculated)

»VT Winding Side« IX Dual Calculated

Please refer to section “Directional Features for Measured (IX) Ground Fault Elements 50X/51X”.

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Measuring ValuesRead Out Measured Values

In the »Operation/Measured Values« menu, both measured and calculated values can be viewed. The measured values are ordered by »Standard values« and »Special values« (depending on the type of device).

Read Out of Measured Values Via PowerPort-E

• If PowerPort-E is not running, please start the application.

• If the device data have not been loaded, select »Receive Data From The Device« from the »Device« menu.

• Double click on the »Operation« icon in the navigation tree.

• Double click on the »Measured Values« icon within the »Operation« navigation tree.

• Double click the »Standard Values« or »Special values« within the »Measured values« tree.

• The measured and calculated values are now shown in tabular form in the window.

To have the measuring data read in a cyclic manner, select »Auto refresh« in the »View« menu. The measured values are read out about every two seconds.

Measurement Display

Menu [Operation\General Settings] offers options to change the display of measured values within the HMI and Smart view.

Scaling of Measured values

By means of the parameter »Scaling« the User can determine how measured values are to be displayed within the HMI and PowerPort-E:

• Per Unit quantities• Primary quantities• Secondary quantities

Power Units (applies only for devices with power measurement)

By means of the parameter »Power Units« the User can determine how measured values are to be displayed within the HMI and PowerPort-E:

• Power Auto Scaling• kW, kVAr or kVA• MW, MVAr or MVA• GW, GVAr or GVA

Energy Units (applies only for devices with energy measurement)

By means of the parameter »Energy Units« the User can determine how measured values are to be displayed

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within the HMI and PowerPort-E:

• Energy Auto Scaling• kWh, kVArh or kVAh• MWh, MVArh or MVAh• GWh, GVArh or GVAh

Temperature Unit (applies only for devices with temperature measurement)

By means of the parameter »Temperature Unit« the User can determine how measured values are to be displayed within the HMI and PowerPort-E:

• ° Celsius• ° Fahrenheit

Current - Measured ValuesCT W1 ,CT W2

If the device is not equipped with an voltage measuring card the first measuring input on the first current measuring card (slot with the lowest number) will be used as the reference angle (»IA«).


IA Fund. Measured value: Phase current (Fundamental)

[Operation/Measured Values/CT W1/Current Fund.]

IB Fund. Measured value: Phase current (Fundamental)


IC Fund. Measured value: Phase current (Fundamental)


IX meas Fund. Measured value (measured): IX (Fundamental)


IR calc Fund. Measured value (calculated): IR (Fundamental)


I0 Fund. Measured value (calculated): Zero current (Fundamental)


I1 Fund. Measured value (calculated): Positive phase sequence current (Fundamental)


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I2 Fund. Measured value (calculated): Unbalanced load current (Fundamental)


IA H2 Measured Value: Ratio of 2nd harmonic over fundamental of IA


IB H2 Measured Value: Ratio of 2nd harmonic over fundamental of IB


IC H2 Measured Value: Ratio of 2nd harmonic over fundamental of IC


IG H2 meas Measured Value: Ratio of 2nd harmonic over fundamental of IG (measured)


IG H2 calc Measured value (calculated): Ratio of 2nd harmonic over fundamental of IG (calculated)


Angle IA Measured Value (Calculated): Angle of Phasor IA


Angle IB Measured Value (Calculated): Angle of Phasor IB


Angle IC Measured Value (Calculated): Angle of Phasor IC


Angle IX meas Measured Value (Calculated): Angle of Phasor IX meas


Angle IR calc Measured Value (Calculated): Angle of Phasor IR calc


Angle I0 Measured Value (calculated): Angle of Zero Sequence System


Angle I1 Measured Value (calculated): Angle of Positive Sequence System


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Angle I2 Measured value (calculated): Angle of Negative Sequence System


IA RMS Measured value: Phase current (RMS) [Operation/Measured Values/CT W1/Current RMS]

IB RMS Measured value: Phase current (RMS) [Operation/Measured Values/CT W1/Current RMS]

IC RMS Measured value: Phase current (RMS) [Operation/Measured Values/CT W1/Current RMS]

IX meas RMS Measured value (measured): IX (RMS) [Operation/Measured Values/CT W1/Current RMS]

IR calc RMS Measured value (calculated): IR (RMS) [Operation/Measured Values/CT W1/Current RMS]

%IA THD Measured Value (Calculated): IA Total Harmonic Distortion

[Operation/Measured Values/CT W1/Current RMS]

%IB THD Measured Value (Calculated): IB Total Harmonic Distortion


%IC THD Measured Value (Calculated): IC Total Harmonic Distortion


IA THD Measured Value (Calculated): IA Total Harmonic Current


IB THD Measured Value (Calculated): IB Total Harmonic Current


IC THD Measured Value (Calculated): IC Total Harmonic Current


%(I2/I1) Measured value (calculated): I2/I1, phase sequence will be taken into account automatically.


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Differential Current - Measured ValuesDifferential Protection

If the device is not equipped with an voltage measuring card the first measuring input on the first current measuring card (slot with the lowest number) will be used as the reference angle (»IA«).

Voltage - Measured ValuesVT

The first measuring input on the first measuring card (slot with the lowest number) is used as the reference angle. E.g. »VA« respectively »VAB«.


f Measured Value: Frequency [Operation/Measured Values/Voltage RMS]

VAB Fund. Measured value: Phase-to-phase voltage (Fundamental)

[Operation/Measured Values/Voltage Fund.]

VBC Fund. Measured value: Phase-to-phase voltage (Fundamental)


VCA Fund. Measured value: Phase-to-phase voltage (Fundamental)


VA Fund. Measured value: Phase-to-neutral voltage (Fundamental)


VB Fund. Measured value: Phase-to-neutral voltage (Fundamental)


VC Fund. Measured value: Phase-to-neutral voltage (Fundamental)


VX meas Fund. Measured value (measured): VX measured (Fundamental)


VR calc Fund. Measured value (calculated): VR (Fundamental)


V0 Fund. Measured value (calculated): Symmetrical components Zero voltage(Fundamental)


V1 Fund. Measured value (calculated): Symmetrical components positive phase sequence voltage(Fundamental)


V2 Fund. Measured value (calculated): Symmetrical components negative phase sequence voltage(Fundamental)


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VAB RMS Measured value: Phase-to-phase voltage (RMS)

[Operation/Measured Values/Voltage RMS]

VBC RMS Measured value: Phase-to-phase voltage (RMS)


VCA RMS Measured value: Phase-to-phase voltage (RMS)


VA RMS Measured value: Phase-to-neutral voltage (RMS)


VB RMS Measured value: Phase-to-neutral voltage (RMS)


VC RMS Measured value: Phase-to-neutral voltage (RMS)


VX meas RMS Measured value (measured): VX measured (RMS)


VR calc RMS Measured value (calculated): VR (RMS) [Operation/Measured Values/Voltage RMS]

Angle VAB Measured Value (Calculated): Angle of Phasor VAB


Angle VBC Measured Value (Calculated): Angle of Phasor VBC


Angle VCA Measured Value (Calculated): Angle of Phasor VCA


Angle VA Measured Value (Calculated): Angle of Phasor VA


Angle VB Measured Value (Calculated): Angle of Phasor VB


Angle VC Measured Value (Calculated): Angle of Phasor VC


Angle VX meas Measured Value: Angle of Phasor VX meas [Operation/Measured Values/Voltage Fund.]

Angle VR calc Measured Value (Calculated): Angle of Phasor VR calc


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Angle V0 Measured Value (calculated): Angle of Zero Sequence System


Angle V1 Measured Value (calculated): Angle of Positive Sequence System


Angle V2 Measured value (calculated): Angle of Negative Sequence System


%(V2/V1) Measured value (calculated): V2/V1, phase sequence will be taken into account automatically.


%VAB THD Measured value (calculated): VAB Total Harmonic Distortion / fundamental


%VBC THD Measured value (calculated): VBC Total Harmonic Distortion / fundamental


%VCA THD Measured value (calculated): VCA Total Harmonic Distortion / fundamental


%VA THD Measured value (calculated): VA Total Harmonic Distortion / fundamental


%VB THD Measured value (calculated): VB Total Harmonic Distortion / fundamental


%VC THD Measured value (calculated): VC Total Harmonic Distortion / fundamental


VAB THD Measured value (calculated): VAB Total Harmonic Distortion


VBC THD Measured value (calculated): VBC Total Harmonic Distortion


VCA THD Measured value (calculated): VCA Total Harmonic Distortion


VA THD Measured value (calculated): VA Total Harmonic Distortion


VB THD Measured value (calculated): VB Total Harmonic Distortion


VC THD Measured value (calculated): VC Total Harmonic Distortion


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Volts/Hertz Ratio Volts/Hertz in relation to nominal values.


Power - Measured Values


Disp PF Measured Value (Calculated): 55D - Displacement Power Factor

[Operation/Measured Values/Power]

Wh Fwd Positive Active Power is consumed active energy

[Operation/Measured Values/Energy]

Wh Rev Negative Active Power (Fed Energy) [Operation/Measured Values/Energy]

VArh Lag Positive Reactive Power is consumed Reactive Energy


VArh Lead Negative Reactive Power (Fed Energy) [Operation/Measured Values/Energy]

VAh Net Net VA Hours [Operation/Measured Values/Energy]

Wh Net Net Watt Hours [Operation/Measured Values/Energy]

VArh Net Net VAr Hours [Operation/Measured Values/Energy]

Start Date/Time Energy counters run since... (Date and time of last reset)


Syst VA RMS Measured VAs (RMS) [Operation/Measured Values/Power]

Syst W RMS Measured Watts. Active power (P- = Fed Active Power, P+ = Consumpted Active Power) (RMS)


Syst VAr RMS Measured VARs. Reactive power (Q- = Fed Reactive Power, Q+ = Consumpted Reactive Power) (RMS)


Apt PF Measured Value (Calculated): 55A - Apparent Power Factor


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Energy CounterECr

Global Parameters of the Energy Counter Module


Power Units Power Units Power Auto Scaling, kW/kVAr/kVA, MW/MVAr/MVA, GW/GVAr/GVA

Power Auto Scaling

[Operation/General Settings]

Energy Units Energy Units Energy Auto Scaling, kWh/kVArh/kVAh, MWh/MVArh/MVAh, GWh/GVArh/GVAh

Energy Auto Scaling

[Operation/General Settings]

Direct Commands of the Energy Counter Module


Res all Energy Cr

Reset of all Energy Counters Inactive, Active

Inactive [Operation/Reset]

Signals of the Energy Counter Module (States of the Outputs)

Name Description

Cr Oflw VAh Net Signal: Counter Overflow VAh NetCr Oflw Wh Net Signal: Counter Overflow Wh NetCr Oflw Wh Fwd Signal: Counter Overflow Wh FwdCr Oflw Wh Rev Signal: Counter Overflow Wh RevCr Oflw VArh Net Signal: Counter Overflow VArh NetCr Oflw VArh Lag Signal: Counter Overflow VArh LagCr Oflw VArh Lead Signal: Counter Overflow VArh LeadVAh Net Res Cr Signal: VAh Net Reset CounterWh Net Res Cr Signal: Wh Net Reset CounterWh Fwd Res Cr Signal: Wh Fwd Reset CounterWh Rev Res Cr Signal: Wh Rev Reset CounterVArh Net Res Cr Signal: VArh Net Reset CounterVArh Lag Res Cr Signal: VArh Lag Reset CounterVArh Lead Res Cr Signal: VArh Lead Reset CounterRes all Energy Cr Signal: Reset of all Energy CountersCr OflwW VAh Net Signal: Counter VAh Net will overflow soonCr OflwW Wh Net Signal: Counter Wh Net will overflow soonCr OflwW Wh Fwd Signal: Counter Wh Fwd will overflow soon

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Name Description

Cr OflwW Wh Rev Signal: Counter Wh Rev will overflow soonCr OflwW VArh Net Signal: Counter VArh Net will overflow soonCr OflwW VArh Lag Signal: Counter VArh Lag will overflow soonCr OflwW VArh Lead Signal: Counter VArh Lead will overflow soon

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StatisticsStatistics

In the »Operation/Statistics« menu, the minimum, maximum, and mean values of the measured and calculated quantities can be found. The statistics are ordered by »Standard values« and »Special values« (depending on the type of device and the device planning).

In the »Device Parameter/Statistics« menu, the User can either set a fixed synchronization time and a calculation interval or start and stop the statistics via a function (e.g.: digital input).

Read Out Statistics• Call up the main menu.

• Call up the »Operation/Statistics« sub-menu.

• Call up either the »Standard values« or »Special values«.

Statistics to Be Read Out Via PowerPort-E


• If device data have not been downloaded recently, click »Receive Data From The Device« in the »Device« menu.


• Double click on the »Statistics« icon within the »Operation« navigation tree.

• Double click on the »Standard values« or »Special values« icon.

• In the window, the statistical data are shown in tabular form.

The values can be read out cyclically. For this purpose, please select »Auto Refresh« out of the »View« menu.

Statistics (Configuration)The Statistics module can be configured within the »Device Parameter/Statistics« menu.

The time interval, that is taken into account for the calculation of the statistics, can either be limited by a fixed duration or it can be limited by a start function (freely assignable signal from the »assignment list« menu).

Fixed Duration:

If the statistics module is set to a fixed duration/time interval, the minimum, maximum, and average values will be calculated and displayed continuously on the basis of this duration/time interval.

Start Function (Flexible Duration):

If the statistics module is to be initiated by a start function, the statistics will not be updated until the start function becomes true (rising edge). At the same time, a new time interval will be started.

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Statistics (Configuration) Via PowerPort-E


• If device data have not been downloaded recently, click »Receive Data From The Device« in the»Device« menu.

• Double click on the »Device Parameter« icon in the navigation tree.

• Double click on the »Statistics« icon within the »Device Parameter« navigation tree.

• Configure the Statistics module.

Direct Commands


ResFc all Resetting of all Statistic values (Current Demand, Power Demand, Min, Max)

Inactive, Active


ResFc I Demand

Resetting of Statistics - Current Demand (avg, peak avg)

Inactive, Active


ResFc P Demand

Resetting of Statistics - Power Demand (avg, peak avg)

Inactive, Active


ResFc Min Resetting of all Minimum values Inactive, Active


ResFc Max Resetting of all Maximum values Inactive, Active


Global Protection Parameters of the Statistics Module


ResFc Max Resetting of all Maximum values 1..n, Assignment List -.- [Device Para/Statistics/Min / Max]

ResFc Min Resetting of all Minimum values 1..n, Assignment List -.- [Device Para/Statistics/Min / Max]

Start I Demand via:

Start Current demand by: Duration, StartFct

Duration [Device Para/Statistics/Demand/Current Demand]

Start I Demand Fc

Start of the calculation, if the assigned signal becomes true.

Only available if: Start I Demand via: = StartFct

1..n, Assignment List -.- [Device Para/Statistics/Demand/Current Demand]

ResFc I Demand

Resetting of Statistics - Current Demand (avg, peak avg)

1..n, Assignment List -.- [Device Para/Statistics/Demand/Current Demand]

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Duration I Demand

Recording time

Only available if: Start I Demand via: = Duration

2 s, 5 s, 10 s, 15 s, 30 s, 1 min, 5 min, 10 min, 15 min, 30 min, 1 h, 2 h, 6 h, 12 h, 1 d, 2 d, 5 d, 7 d, 10 d, 30 d

15 s [Device Para/Statistics/Demand/Current Demand]

Window I Demand

Window configuration Sliding, Fixed

Fixed [Device Para/Statistics/Demand/Current Demand]

Start P Demand via:

Start Active Power demand by: Duration, StartFct

Duration [Device Para/Statistics/Demand/Power Demand]

Start P Demand Fc

Start of the calculation, if the assigned signal becomes true.

Only available if: Start P Demand via: = StartFct

1..n, Assignment List -.- [Device Para/Statistics/Demand/Power Demand]

ResFc P Demand

Resetting of Statistics - Power Demand (avg, peak avg)

1..n, Assignment List -.- [Device Para/Statistics/Demand/Power Demand]

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Duration P Demand

Recording time

Only available if: Start P Demand via: = Duration

2 s, 5 s, 10 s, 15 s, 30 s, 1 min, 5 min, 10 min, 15 min, 30 min, 1 h, 2 h, 6 h, 12 h, 1 d, 2 d, 5 d, 7 d, 10 d, 30 d

15 s [Device Para/Statistics/Demand/Power Demand]

Window P Demand

Window configuration Sliding, Fixed

Sliding [Device Para/Statistics/Demand/Power Demand]

States of the Inputs of the Statistics Module


StartFc 1-I State of the module input: Start of Statistics 1 (Update the displayed Demand )

[Device Para/Statistics/Demand/Current Demand]

StartFc 2-I State of the module input: Start of Statistics 2 (Update the displayed Demand )

[Device Para/Statistics/Demand/Power Demand]

ResFc I Demand-I State of the module input: Resetting of Statistics - Current Demand (avg, peak avg)

[Device Para/Statistics/Demand/Current Demand]

ResFc P Demand-I State of the module input: Resetting of Statistics - Power Demand (avg, peak avg)

[Device Para/Statistics/Demand/Power Demand]

ResFc Max-I State of the module input: Resetting of all Maximum values

[Device Para/Statistics/Min / Max]

ResFc Min-I State of the module input: Resetting of all Minimum values

[Device Para/Statistics/Min / Max]

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Signals of the Statistics Module

Name Description

ResFc all Signal: Resetting of all Statistic values (Current Demand, Power Demand, Min, Max)

ResFc I Demand Signal: Resetting of Statistics - Current Demand (avg, peak avg)ResFc P Demand Signal: Resetting of Statistics - Power Demand (avg, peak avg)ResFc Max Signal: Resetting of all Maximum values ResFc Min Signal: Resetting of all Minimum values

Counters of the Module Statistics


MeasPointNo Each measuring point that is taken over by the statistics increments this counter. By means of this counter, the User can check whether the statistics are alive and if data are being acquired.

[Operation/Count and RevData/Statistics]

MeasPointNo2 Each measuring point that is taken over by the statistics increments this counter. By means of this counter, the User can check whether the statistics are alive and if data are being acquired.

[Operation/Count and RevData/Statistics]

Res Cr I Demand Number of resets since last booting. The time-stamp shows date and time of the last reset.

[Operation/Statistics/Demand/CT W2]

Res Cr P Demand Number of resets since last booting. The time-stamp shows date and time of the last reset.

[Operation/Statistics/Demand/Power Demand]

Res Cr Min values Number of resets since last booting. The time-stamp shows date and time of the last reset.

[Operation/Statistics/Min/49]

Res Cr Max values Number of resets since last booting. The time-stamp shows date and time of the last reset.

[Operation/Statistics/Max/49]

Standard Statistic Values

Current - Statistic Values


I1 max Fund. Maximum value positive phase sequence current (Fundamental)

[Operation/Statistics/Max/CT W1]

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I1 min Fund. Minimum value positive phase sequence current (Fundamental)

[Operation/Statistics/Min/CT W1]

I2 max Fund. Maximum value unbalanced load current (Fundamental)


I2 min Fund. Minimum value unbalanced load current (Fundamental)


IA max RMS IA maximum value (RMS) [Operation/Statistics/Max/CT W1]

IA avg RMS IA average value (RMS) [Operation/Statistics/Demand/CT W1]

IA min RMS IA minimum value (RMS) [Operation/Statistics/Min/CT W1]

IB max RMS IB maximum value (RMS) [Operation/Statistics/Max/CT W1]

IB avg RMS IB average value (RMS) [Operation/Statistics/Demand/CT W1]

IB min RMS IB minimum value (RMS) [Operation/Statistics/Min/CT W1]

IC max RMS IC maximum value (RMS) [Operation/Statistics/Max/CT W1]

IC avg RMS IC average value (RMS) [Operation/Statistics/Demand/CT W1]

IC min RMS IC minimum value (RMS) [Operation/Statistics/Min/CT W1]

IX meas max RMS Measured value: IX maximum value (RMS) [Operation/Statistics/Max/CT W1]

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IX meas min RMS Measured value: IX minimum value (RMS) [Operation/Statistics/Min/CT W1]

IR calc max RMS Measured value (calculated): IR maximum value (RMS)


IR calc min RMS Measured value (calculated): IR minimum value (RMS)


%(I2/I1) max Measured value (calculated): I2/I1 maximum value, phase sequence will be taken into account automatically


%(I2/I1) min Measured value (calculated): I2/I1 minimum value, phase sequence will be taken into account automatically


IA Peak demand IA Peak value, RMS value [Operation/Statistics/Demand/CT W1]

IB Peak demand IB Peak value, RMS value [Operation/Statistics/Demand/CT W1]

IC Peak demand IC Peak value, RMS value [Operation/Statistics/Demand/CT W1]

Voltage - Statistic Values


f max Max. frequency value [Operation/Statistics/Max/Voltage]

f min Min. frequency value [Operation/Statistics/Min/Voltage]

V1 max Fund. Maximum value: Symmetrical components positive phase sequence voltage(Fundamental)

[Operation/Statistics/Max/Voltage]

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V1 min Fund. Minimum value: Symmetrical components positive phase sequence voltage(Fundamental)

[Operation/Statistics/Min/Voltage]

V2 max Fund. Maximum value: Symmetrical components negative phase sequence voltage(Fundamental)


V2 min Fund. Minimum value: Symmetrical components negative phase sequence voltage(Fundamental)


VAB max RMS VAB maximum value (RMS) [Operation/Statistics/Max/Voltage]

VAB min RMS VAB minimum value (RMS) [Operation/Statistics/Min/Voltage]

VBC max RMS VBC maximum value (RMS) [Operation/Statistics/Max/Voltage]

VBC min RMS VBC minimum value (RMS) [Operation/Statistics/Min/Voltage]

VCA max RMS VCA maximum value (RMS) [Operation/Statistics/Max/Voltage]

VCA min RMS VCA minimum value (RMS) [Operation/Statistics/Min/Voltage]

VA max RMS VA maximum value (RMS) [Operation/Statistics/Max/Voltage]

VA min RMS VA minimum value (RMS) [Operation/Statistics/Min/Voltage]

VB max RMS VB maximum value (RMS) [Operation/Statistics/Max/Voltage]

VB min RMS VB minimum value (RMS) [Operation/Statistics/Min/Voltage]

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VC max RMS VC maximum value (RMS) [Operation/Statistics/Max/Voltage]

VC min RMS VC minimum value (RMS) [Operation/Statistics/Min/Voltage]

VX meas max RMS Measured value: VX maximum value (RMS) [Operation/Statistics/Max/Voltage]

VX meas min RMS Measured value: VX minimum value (RMS) [Operation/Statistics/Min/Voltage]

VR calc max RMS Measured value (calculated): VR maximum value (RMS)


VR calc min RMS Measured value (calculated): VR minimum value (RMS)


%(V2/V1) max Measured value (calculated): V2/V1 maximum value, phase sequence will be taken into account automatically


%(V2/V1) min Measured value (calculated): V2/V1 minimum value , phase sequence will be taken into account automatically


Volts/Hertz max Maximum value: Ratio Volts/Hertz in relation to nominal values.


Volts/Hertz min Minimum value: Ratio Volts/Hertz in relation to nominal values.


Power - Statistic Values


Disp PF max Maximum value of the 55D - Displacement Power Factor

[Operation/Statistics/Max/Power]

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Disp PF min Minimum value of the 55D - Displacement Power Factor

[Operation/Statistics/Min/Power]

Syst VA max Maximum value of the apparent power [Operation/Statistics/Max/Power]

Syst VA avg Average of the apparent power [Operation/Statistics/Demand/Power Demand]

Syst VA min Minimum value of the apparent power [Operation/Statistics/Min/Power]

Syst W max Maximum value of the active power [Operation/Statistics/Max/Power]

Syst W avg Average of the active power [Operation/Statistics/Demand/Power Demand]

Syst W min Minimum value of the active power [Operation/Statistics/Min/Power]

Syst VAr max Maximum value of the reactive power [Operation/Statistics/Max/Power]

Syst VAr avg Average of the reactive power [Operation/Statistics/Demand/Power Demand]

Syst VAr min Minimum value of the reactive power [Operation/Statistics/Min/Power]

Apt PF max Maximum value of the 55A - Apparent Power Factor

[Operation/Statistics/Max/Power]

Apt PF min Minimum value of the 55A - Apparent Power Factor

[Operation/Statistics/Min/Power]

VA Peak demand VA Peak value, RMS value [Operation/Statistics/Demand/Power Demand]

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Watt Peak demand WATTS Peak value, RMS value [Operation/Statistics/Demand/Power Demand]

VAr Peak demand VARs Peak value, RMS value [Operation/Statistics/Demand/Power Demand]

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System AlarmsAvailable Elements:SysA

Within the System Alarms menu [SysA] the User can configure:

• General Settings (activate/inactivate the Demand Management, optional assign a signal, that will block the Demand Management);

• Power Protection (please refer to section 32, 32V, 32VA);

• Demand Management (Power and Current); and

• THD Protection.

Please note, that all thresholds are to be set as primary values.

Demand ManagementDemand is the average of system current or power over a time interval (window). Demand management supports the User to keep energy demand below target values bound by contract (with the energy supplier). If the contractual target values are exceeded, extra charges are to be paid to the energy supplier.

Therefore, demand management helps the User detect and avoid averaged peak loads that are taken into account for the billing. In order to reduce the demand charge respective to demand rate, peak loads, if possible, should be diversified. That means, if possible, avoiding large loads at the same time. In order to assist the User in analyzing the demand, demand management might inform the User by an alarm. The User might also use demand alarms and assign them on relays in order to perform load shedding (where applicable).

Demand management comprises:

• Watt Demand (Active Power);• VAr Demand (Reactive Power);• VA Demand (Apparent Power); and• Current Demand.

Configuring the Demand

Configuring the demand is a two step procedure. Proceed as follows.

Step1. Configure the general settings within the [Device Para/Statistics/Demand] menu:

• Set the trigger source to »Duration«.• Select a time base for the »window«.• Determine if the window is »fixed« or »sliding«.

The interval time (window) can be set to fixed or sliding.

Example for a fixed window: If the range is set for 15 minutes, the protective device calculates the average current or power over the past 15 minutes and updates the value every 15 minutes.

Example for a sliding window: If the sliding window is selected and the interval is set to 15 minutes, the protective device calculates and updates the average current or power continuously, for the past 15 minutes (the newest measuring value replaces the oldest measuring value continuously).

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5 6 7 8 9 10 11 12 13 14 15 16 17 181 2 3 4

5 6 7 8 9 10 11 12 13 14 15 16 17 181 2 3 4

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Window configuration = Sliding

Window configuration = Fixed

Sliding

Sliding

t-Delay0

Duration

Average Calculation Pickup

t-Delay0


t-Delay0


t-Delay0


Average Calculation Average Calculation Average Calculation Average Calculation

Average Calculation Average Calculation Average Calculation Average Calculation

Duration Duration Duration

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Step 2. In addition, the Demand specific settings have to be configured in the [System Para/System Alarms/Demand] menu:

• Determine if the demand should generate an alarm or if it should run in the silent mode (Alarm active/inactive);

• Set the threshold; and• Where applicable, set a delay time for the alarm.

Peak DemandThe protective device also saves the peak demand values for current and power. The quantities represent the largest demand value since the demand values were last reset. Peak demands for current and system power are date and time stamped.

Within the [Operation/Demand] menu, the current Demand and Peak demand values can be seen.

Min. and Max. ValuesWithin the Operation menu the minimum (min.) and maximum (max.) values can be seen.

Minimum values since last reset: The minimum values are continuously compared to the last minimum value for that measuring value. If the new value is less than the last minimum, the value is updated. Within the [Device Para/Statistics] menu, a reset signal can be assigned.

Maximum values since last reset: The maximum values are continuously compared to the last maximum value for that measuring value. If the new value is greater than the last maximum, the value is updated. Within the [Device Para/Statistics] menu, a reset signal can be assigned.

THD ProtectionIn order to supervise power quality, the protective device can monitor the voltage (phase-to-phase) and current THDs.

Within the [System Para/System Alarms/THD] menu:

• Determine if an alarm is to be issued or not (Alarm active/inactive);• Set the threshold; and• Where applicable, set a delay time for the alarm.

Device Planning Parameters of the Demand Management



Use [Device Planning]

Signals of the Demand Management (States of the Outputs)

Name Description

Active Signal: ActiveExBlo Signal: External Blocking

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Name Description

Alarm Watt Power Signal: Alarm WATTS peakAlarm VAr Power Signal: Alarm VArs peakAlarm VA Power Signal: Alarm VAs peakAlarm Watt Demand Signal: Alarm WATTS demand valueAlarm VAr Demand Signal: Alarm VARs demand valueAlarm VA Demand Signal: Alarm VAs demand valueAlm Current Demd Signal: Alarm Current demand valueAlarm I THD Signal: Alarm Total Harmonic Distortion CurrentAlarm V THD Signal: Alarm Total Harmonic Distortion VoltageTrip Watt Power Signal: Trip WATTS peakTrip VAr Power Signal: Trip VArs peakTrip VA Power Signal: Trip VAs peakTrip Watt Demand Signal: Trip WATTS demand valueTrip VAr Demand Signal: Trip VARs demand valueTrip VA Demand Signal: Trip VAs demand valueTrip Current Demand Signal: Trip Current demand valueTrip I THD Signal: Trip Total Harmonic Distortion CurrentTrip V THD Signal: Trip Total Harmonic Distortion Voltage

Global Protection Parameter of the Demand Management



Inactive, Active

Inactive [SysA/General Settings]


1..n, Assignment List -.- [SysA/General Settings]

CT Winding Side

Measuring values will be used from this winding side

W1, W2

W2 [SysA/General Settings]

Alarm Alarm Inactive, Active

Inactive [SysA/Power/Watt]

Threshold Threshold (to be entered as primary value) 1 – 40000000 kW 10000 kW [SysA/Power/Watt]

t-Delay Tripping Delay 0 – 60 min 0 min [SysA/Power/Watt]

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Inactive [SysA/Power/VAr]

Threshold Threshold (to be entered as primary value) 1 – 40000000 kVAr 10000 kVAr [SysA/Power/VAr]

t-Delay Tripping Delay 0 – 60 min 0 min [SysA/Power/VAr]


Inactive [SysA/Power/VA]

Threshold Threshold (to be entered as primary value) 1 – 40000000 kVA 10000 kVA [SysA/Power/VA]

t-Delay Tripping Delay 0 – 60 min 0 min [SysA/Power/VA]


Inactive [SysA/Demand/Power Demand/Watt Demand]

Threshold Threshold (to be entered as primary value) 1 – 40000000 kW 10000 kW [SysA/Demand/Power Demand/Watt Demand]

t-Delay Tripping Delay 0 – 60 min 0 min [SysA/Demand/Power Demand/Watt Demand]


Inactive [SysA/Demand/Power Demand/VAr Demand]

Threshold Threshold (to be entered as primary value) 1 – 40000000 kVAr 20000 kVAr [SysA/Demand/Power Demand/VAr Demand]

t-Delay Tripping Delay 0 – 60 min 0 min [SysA/Demand/Power Demand/VAr Demand]


Inactive [SysA/Demand/Power Demand/VA Demand]

Threshold Threshold (to be entered as primary value) 1 – 40000000 kVA 20000 kVA [SysA/Demand/Power Demand/VA Demand]

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t-Delay Tripping Delay 0 – 60 min 0 min [SysA/Demand/Power Demand/VA Demand]


Inactive [SysA/Demand/Current Demand]

Threshold Threshold (to be entered as primary value) 10 – 500000 A 500 A [SysA/Demand/Current Demand]

t-Delay Tripping Delay 0 – 60 min 0 min [SysA/Demand/Current Demand]


Inactive [SysA/THD/I THD]

Threshold Threshold (to be entered as primary value) 1 – 500000 A 500 A [SysA/THD/I THD]

t-Delay Tripping Delay 0 – 3600 s 0 s [SysA/THD/I THD]


Inactive [SysA/THD/V THD]

Threshold Threshold (to be entered as primary value) 1 – 500000 V 10000 V [SysA/THD/V THD]

t-Delay Tripping Delay 0 – 3600 s 0 s [SysA/THD/V THD]

States of the Inputs of the Demand Management


ExBlo-I Module Input State: External Blocking [SysA/General Settings]

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ResetsCollective Acknowledgments for Latched Signals:

Collective Acknowledgments

LEDs Relay Output Contacts

SCADA Pending Trip Command

LEDs+Relay Output

Contacts+SCADA+Pending

Trip Command

Via PowerPort-E or at the panel all...can be acknowledged.

At the panel, the [Operation\

Acknowledge] menu can directly be

accessed via the »C« key.

All LEDs at once:

Where? [Operation\

Acknowledge]

All Relay Output Contacts at

once:

Where? [Operation\

Acknowledge]

All SCADA signals at once:

Where? [Operation\

Acknowledge]

All pending trip commands at

once:

Where? [Operation\

Acknowledge]

All at once:

Where? [Operation\

Acknowledge]

External Acknowledg-ment*: Via a signal from the assignment list (e.g.: a digital Input) all... can be acknowledged.

All LEDs at once:

Where?Within the

Ex Acknowledge menu.

All Relay Output Contacts at once:

Where?Within the


All SCADA signals at once:

Where?Within the


All Pending Trip commands at once:

Where?Within the


All at once:

Where?Within the


*The External acknowledgment might be disabled if parameter »Ex acknowledgment«is set to »inactive« within menu [Device Para/Ex Acknowledge]. This blocks also the acknowledgment via Communication (e.g. Modbus).

Options for Individual Acknowledgments for Latched Signals:

Individual Acknowledgment

LEDs Relay Output Pending Trip Command

Via a signal from the assignment list (e.g.: a digital Input), a single... can be acknowledged.

Single LED:

Where? Within the Configuration menu

of this single LED.

Relay Output:

Where? Within the Configuration menu

of this single Relay Output.

Pending Trip Command.

Where?Within the module

TripControl

If the User is within the parameter setting mode, the User cannot acknowledge.

In case of a fault during parameter setting via the operating panel, the User must first leave the parameter mode by pressing either the push-buttons »Ack/Rst« or »OK« before accessing the »Acknowledgements« menu via the push-button.

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Manual Acknowledgment

• Press the »Ack/Rst« button on the panel.• Select the item to be acknowledged via the softkeys:

• Relay Output Contacts;• LEDs;• SCADA;• A trip command; or• All the above mentioned items at once.

• Press the Softkey with the »Wrench-Symbol«.• Enter the password.

Manual Acknowledgment Via PowerPort-E


• If device data have not been downloaded recently, select »Receive Data From The Device« from the »Device« menu.


• Double click on the »Acknowledgment« icon within the operation menu.

• Double click the entry within the pop-up that is to be acknowledged.

• Press the »Execute immediately« button.

• Enter the password.

External AcknowledgmentsWithin the [Ex Acknowledge] menu, the User can assign a signal (e.g.: the state of a digital input) from the assignment list that:

• Acknowledges all (acknowledgeable) LEDs at once;• Acknowledges all (acknowledgeable) Relay Output Contacts at once; or• Acknowledges all (acknowledgeable) SCADA signals at once.

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1..n, Assignment List

Ack LED


Ack RO


Ack Comm

Ex Acknowledge.Ack LED

Ex Acknowledge.Ack RO

Ex Acknowledge.Ack Comm

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Within the [Protection Para\Global Prot Para\TripControl] menu, the User can assign a signal that acknowledges a pending trip command.

For details, please refer to the Trip Control section.

External Acknowledge Via PowerPort-E• If PowerPort-E is not running, please start the application.

• If device data have not been downloaded recently, select »Receive Data From The Device« from the »Device« menu.

• Double click on the »Device Parameter« icon in the navigation tree.

• Double click on the »Ex Acknowledge« icon within the operation menu.

• In the working window, the User can now assign each signal that resets all acknowledgeable LEDs, a signal that resets all Relay Output Contacts, a signal that resets the SCADA signals respectively, and a signal that acknowledges a pending trip command.

External LED - Acknowledgment SignalsThe following signals can be used for external acknowledgment of latched LEDs.

Name Description

-.- No assignmentDI-8P X1.DI 1 Signal: Digital InputDI-8P X1.DI 2 Signal: Digital InputDI-8P X1.DI 3 Signal: Digital InputDI-8P X1.DI 4 Signal: Digital InputDI-8P X1.DI 5 Signal: Digital InputDI-8P X1.DI 6 Signal: Digital InputDI-8P X1.DI 7 Signal: Digital InputDI-8P X1.DI 8 Signal: Digital InputModbus.Comm Cmd 1 Communication CommandModbus.Comm Cmd 2 Communication CommandModbus.Comm Cmd 3 Communication CommandModbus.Comm Cmd 4 Communication CommandModbus.Comm Cmd 5 Communication CommandModbus.Comm Cmd 6 Communication CommandModbus.Comm Cmd 7 Communication CommandModbus.Comm Cmd 8 Communication CommandModbus.Comm Cmd 9 Communication CommandModbus.Comm Cmd 10 Communication CommandModbus.Comm Cmd 11 Communication Command

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Name Description

Modbus.Comm Cmd 12 Communication CommandModbus.Comm Cmd 13 Communication CommandModbus.Comm Cmd 14 Communication CommandModbus.Comm Cmd 15 Communication CommandModbus.Comm Cmd 16 Communication CommandLogic.LE1.Gate Out Signal: Output of the logic gateLogic.LE1.Timer Out Signal: Timer OutputLogic.LE1.Out Signal: Latched Output (Q)Logic.LE1.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE2.Gate Out Signal: Output of the logic gateLogic.LE2.Timer Out Signal: Timer OutputLogic.LE2.Out Signal: Latched Output (Q)Logic.LE2.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE3.Gate Out Signal: Output of the logic gateLogic.LE3.Timer Out Signal: Timer OutputLogic.LE3.Out Signal: Latched Output (Q)Logic.LE3.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE4.Gate Out Signal: Output of the logic gateLogic.LE4.Timer Out Signal: Timer OutputLogic.LE4.Out Signal: Latched Output (Q)Logic.LE4.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE5.Gate Out Signal: Output of the logic gateLogic.LE5.Timer Out Signal: Timer OutputLogic.LE5.Out Signal: Latched Output (Q)Logic.LE5.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE6.Gate Out Signal: Output of the logic gateLogic.LE6.Timer Out Signal: Timer OutputLogic.LE6.Out Signal: Latched Output (Q)Logic.LE6.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE7.Gate Out Signal: Output of the logic gateLogic.LE7.Timer Out Signal: Timer OutputLogic.LE7.Out Signal: Latched Output (Q)Logic.LE7.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE8.Gate Out Signal: Output of the logic gateLogic.LE8.Timer Out Signal: Timer OutputLogic.LE8.Out Signal: Latched Output (Q)Logic.LE8.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE9.Gate Out Signal: Output of the logic gateLogic.LE9.Timer Out Signal: Timer Output

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Name Description

Logic.LE9.Out Signal: Latched Output (Q)Logic.LE9.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE10.Gate Out Signal: Output of the logic gateLogic.LE10.Timer Out Signal: Timer OutputLogic.LE10.Out Signal: Latched Output (Q)Logic.LE10.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE11.Gate Out Signal: Output of the logic gateLogic.LE11.Timer Out Signal: Timer OutputLogic.LE11.Out Signal: Latched Output (Q)Logic.LE11.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE12.Gate Out Signal: Output of the logic gateLogic.LE12.Timer Out Signal: Timer OutputLogic.LE12.Out Signal: Latched Output (Q)Logic.LE12.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE13.Gate Out Signal: Output of the logic gateLogic.LE13.Timer Out Signal: Timer OutputLogic.LE13.Out Signal: Latched Output (Q)Logic.LE13.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE14.Gate Out Signal: Output of the logic gateLogic.LE14.Timer Out Signal: Timer OutputLogic.LE14.Out Signal: Latched Output (Q)Logic.LE14.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE15.Gate Out Signal: Output of the logic gateLogic.LE15.Timer Out Signal: Timer OutputLogic.LE15.Out Signal: Latched Output (Q)Logic.LE15.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE16.Gate Out Signal: Output of the logic gateLogic.LE16.Timer Out Signal: Timer OutputLogic.LE16.Out Signal: Latched Output (Q)Logic.LE16.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE17.Gate Out Signal: Output of the logic gateLogic.LE17.Timer Out Signal: Timer OutputLogic.LE17.Out Signal: Latched Output (Q)Logic.LE17.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE18.Gate Out Signal: Output of the logic gateLogic.LE18.Timer Out Signal: Timer OutputLogic.LE18.Out Signal: Latched Output (Q)Logic.LE18.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE19.Gate Out Signal: Output of the logic gate

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Name Description

Logic.LE19.Timer Out Signal: Timer OutputLogic.LE19.Out Signal: Latched Output (Q)Logic.LE19.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE20.Gate Out Signal: Output of the logic gateLogic.LE20.Timer Out Signal: Timer OutputLogic.LE20.Out Signal: Latched Output (Q)Logic.LE20.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE21.Gate Out Signal: Output of the logic gateLogic.LE21.Timer Out Signal: Timer OutputLogic.LE21.Out Signal: Latched Output (Q)Logic.LE21.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE22.Gate Out Signal: Output of the logic gateLogic.LE22.Timer Out Signal: Timer OutputLogic.LE22.Out Signal: Latched Output (Q)Logic.LE22.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE23.Gate Out Signal: Output of the logic gateLogic.LE23.Timer Out Signal: Timer OutputLogic.LE23.Out Signal: Latched Output (Q)Logic.LE23.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE24.Gate Out Signal: Output of the logic gateLogic.LE24.Timer Out Signal: Timer OutputLogic.LE24.Out Signal: Latched Output (Q)Logic.LE24.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE25.Gate Out Signal: Output of the logic gateLogic.LE25.Timer Out Signal: Timer OutputLogic.LE25.Out Signal: Latched Output (Q)Logic.LE25.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE26.Gate Out Signal: Output of the logic gateLogic.LE26.Timer Out Signal: Timer OutputLogic.LE26.Out Signal: Latched Output (Q)Logic.LE26.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE27.Gate Out Signal: Output of the logic gateLogic.LE27.Timer Out Signal: Timer OutputLogic.LE27.Out Signal: Latched Output (Q)Logic.LE27.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE28.Gate Out Signal: Output of the logic gateLogic.LE28.Timer Out Signal: Timer OutputLogic.LE28.Out Signal: Latched Output (Q)Logic.LE28.Out inverted Signal: Negated Latched Output (Q NOT)

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Name Description

Logic.LE29.Gate Out Signal: Output of the logic gateLogic.LE29.Timer Out Signal: Timer OutputLogic.LE29.Out Signal: Latched Output (Q)Logic.LE29.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE30.Gate Out Signal: Output of the logic gateLogic.LE30.Timer Out Signal: Timer OutputLogic.LE30.Out Signal: Latched Output (Q)Logic.LE30.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE31.Gate Out Signal: Output of the logic gateLogic.LE31.Timer Out Signal: Timer OutputLogic.LE31.Out Signal: Latched Output (Q)Logic.LE31.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE32.Gate Out Signal: Output of the logic gateLogic.LE32.Timer Out Signal: Timer OutputLogic.LE32.Out Signal: Latched Output (Q)Logic.LE32.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE33.Gate Out Signal: Output of the logic gateLogic.LE33.Timer Out Signal: Timer OutputLogic.LE33.Out Signal: Latched Output (Q)Logic.LE33.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE34.Gate Out Signal: Output of the logic gateLogic.LE34.Timer Out Signal: Timer OutputLogic.LE34.Out Signal: Latched Output (Q)Logic.LE34.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE35.Gate Out Signal: Output of the logic gateLogic.LE35.Timer Out Signal: Timer OutputLogic.LE35.Out Signal: Latched Output (Q)Logic.LE35.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE36.Gate Out Signal: Output of the logic gateLogic.LE36.Timer Out Signal: Timer OutputLogic.LE36.Out Signal: Latched Output (Q)Logic.LE36.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE37.Gate Out Signal: Output of the logic gateLogic.LE37.Timer Out Signal: Timer OutputLogic.LE37.Out Signal: Latched Output (Q)Logic.LE37.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE38.Gate Out Signal: Output of the logic gateLogic.LE38.Timer Out Signal: Timer OutputLogic.LE38.Out Signal: Latched Output (Q)

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Name Description

Logic.LE38.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE39.Gate Out Signal: Output of the logic gateLogic.LE39.Timer Out Signal: Timer OutputLogic.LE39.Out Signal: Latched Output (Q)Logic.LE39.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE40.Gate Out Signal: Output of the logic gateLogic.LE40.Timer Out Signal: Timer OutputLogic.LE40.Out Signal: Latched Output (Q)Logic.LE40.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE41.Gate Out Signal: Output of the logic gateLogic.LE41.Timer Out Signal: Timer OutputLogic.LE41.Out Signal: Latched Output (Q)Logic.LE41.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE42.Gate Out Signal: Output of the logic gateLogic.LE42.Timer Out Signal: Timer OutputLogic.LE42.Out Signal: Latched Output (Q)Logic.LE42.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE43.Gate Out Signal: Output of the logic gateLogic.LE43.Timer Out Signal: Timer OutputLogic.LE43.Out Signal: Latched Output (Q)Logic.LE43.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE44.Gate Out Signal: Output of the logic gateLogic.LE44.Timer Out Signal: Timer OutputLogic.LE44.Out Signal: Latched Output (Q)Logic.LE44.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE45.Gate Out Signal: Output of the logic gateLogic.LE45.Timer Out Signal: Timer OutputLogic.LE45.Out Signal: Latched Output (Q)Logic.LE45.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE46.Gate Out Signal: Output of the logic gateLogic.LE46.Timer Out Signal: Timer OutputLogic.LE46.Out Signal: Latched Output (Q)Logic.LE46.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE47.Gate Out Signal: Output of the logic gateLogic.LE47.Timer Out Signal: Timer OutputLogic.LE47.Out Signal: Latched Output (Q)Logic.LE47.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE48.Gate Out Signal: Output of the logic gateLogic.LE48.Timer Out Signal: Timer Output

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Name Description

Logic.LE77.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE78.Gate Out Signal: Output of the logic gateLogic.LE78.Timer Out Signal: Timer OutputLogic.LE78.Out Signal: Latched Output (Q)Logic.LE78.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE79.Gate Out Signal: Output of the logic gateLogic.LE79.Timer Out Signal: Timer OutputLogic.LE79.Out Signal: Latched Output (Q)Logic.LE79.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE80.Gate Out Signal: Output of the logic gateLogic.LE80.Timer Out Signal: Timer OutputLogic.LE80.Out Signal: Latched Output (Q)Logic.LE80.Out inverted Signal: Negated Latched Output (Q NOT)

Manual ResetsIn the »Operation/Reset« menu, the User can:

• Reset counters;• Delete records (e.g.: waveform records); and• Reset special things (like statistics, thermal replica, etc.).

The description of the reset commands can be found within the corresponding modules.

Manual Resets Via PowerPort-E• If PowerPort-E is not running, please start the application.


• Double click the »Operation« icon in the navigation tree.

• Double click the »Reset icon« within the operation menu.

• Double click the entry within the pop-up that is to be reset or deleted.

The description of the reset commands can be found within the corresponding modules.

Reset to Factory DefaultsThis Function will reset the device to the factory defaults. All records will be deleted and and the measured values and counters will be reset. The operation hours counter will be kept.

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This Function is available at the HMI only.

• Press the »Ack/Rst-key« during a cold start, in order to access the »Reset« menu.

• Select »Reset to factory default«.

• Confirm »Reset device to factory defaults and reboot« with »Yes« in order to execute the reset to factory defaults.«

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Status DisplayIn the status display within the »Operation« menu, the present state of all signals can be viewed. This means the User is able to see if the individual signals are active or inactive at that moment. The User can see all signals sorted by protective elements/modules.

State of the Module Input / Signal Is... Is Shown at the Panel as...

false / »0«

true / »1«

Status Display Via PowerPort E• If PowerPort E is not running, please start the application.

• If the device data have not been downloaded recently, select »Receive Data From The Device« from »Device« menu.


• Double click on the »Status Display« icon within the operational data.

• Double click on a subfolder (e.g. Prot) in order to see e.g. the states of the general alarms.

To have the status display updated in a cyclic manner, select »Automatic Up-Date« in the »VIEW« menu.

State of the Module Input / Signal Is... Is Shown in PowerPort-E as...

false / »0« 0true / »1« 1

No connection to the device ?

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Operating Panel (HMI)HMI

Special Parameters of the PanelThe »Device Parameter/HMI« menu is used to define the contrast of the display, the maximum admissible edit time, and the menu language (after expiration, all unsaved parameter changes will be rejected).

Direct Commands of the Panel


Contrast Contrast 30 - 60 50 [Device Para/HMI]

Global Protection Parameters of the Panel


t-max Edit If no other key(s) is pressed at the panel, after expiration of this time, all cached (changed) parameters are canceled.

20 – 3600 s 180 s [Device Para/HMI]

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RecordersWaveform Recorder

Waveform rec

The waveform recorder works with 32 samples per cycle. It can be started by one of eight start events (selection from the »Assignment list«/OR-Logic).

The waveform record contains the measuring values including the pre-trigger time. By means of PowerPort-E/Quality Manager (option), the oscillographic curves of the analog (current, voltage) and digital channels/traces can be shown and evaluated in a graphical form.

The waveform recorder has a storage capacity of 120 s (duration). The amount of records depends on the file size of each record.

The waveform recorder can be configured in the»Device Parameter/Recorder/Waveform rec« menu.

Determine the maximum recording time to register a waveform event. The maximum total length of a recording is 10 s (including pre-trigger and post-trigger time).

To trigger the waveform recorder, up to eight signals can be selected from the »Assignment list«. The trigger events are OR-linked. If a waveform record is written, a new waveform record cannot be triggered until all trigger signals, which have triggered the previous waveform record, are gone.

Recording is only done for the time the assigned event exists (event controlled), plus the time for the pre- and post-trigger, but not longer than 10 s. The time for the pre- and post-trigger is to be entered as percent of the maximum file size.

The post-trigger time will be up to the "Post-trigger time" depending on the duration of the trigger signal. The post-trigger will be the remaining time of the "Max file size" but, at maximum, the "Post-trigger time".

Example

The waveform recorder is started by the general activation facility. After the fault has been cleared (plus follow-up time), the recording process is stopped (but after 10 s at the latest).

The parameter »Auto Delete« defines how the device will react if a location to which to save the waveform record is not available. In case »Auto Delete« is »Active«, the first recorded waveform will be overwritten according to the FIFO principle. If the parameter is set to »Inactive«, recording of the waveform events will be stopped until the storage location is manually released.

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Start: 1Trigger

Start: 2Trigger

Start: 3Trigger

Start: 4Trigger

Start: 5Trigger

Start: 6Trigger

Start: 7Trigger

Start: 8Trigger

Man. Trigger

RecordingOR

OR

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Start 1

t

t

0

1

0

1300 ms

1200 ms

Pre-trigger time

t

0

1500 ms

Post-trigger time

t

0

12000 ms

t-rec

t

0

12000 ms

Max file size

Start 1 = Prot.Pickup

Start 2 = -.-Start 3 = -.-Start 4 = -.-


Start 8 = -.-

Post-trigger time = 25%

Pre-trigger time = 15%

Max file size = 2s

Auto overwriting = Active

t-rec = Max file size

0

0

0

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Start 1

t

t

0

1

0

1300 ms

200 ms

Pre-trigger time

t

0

1500 ms

Post-trigger time

t

0

11000 ms

t-rec

t-rec < Max file size

t

0

12000 ms

Max file size

Start 1 = Prot.TripStart 2 = -.-Start 3 = -.-


Start 7 = -.-Start 8 = -.-

Post-trigger time = 25%

Pre-trigger time = 15%

Max file size = 2s

Auto overwriting = Active

0

0

0

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Read Out of Waveform Records

Within the »Operation/Waveform rec« menu, the User can:

• Detect the accumulated waveform records.

Within the »Operation/Recorders/Man Trigger« menu, the User can trigger the waveform recorder manually.

To Read Out the Waveform Recorder with PowerPort-E


• If the device data have not been loaded, click »Receive Data From The Device« in the »Device« menu.


• Double click the »Recorders« icon in the navigation tree.

• Double click the »Waveform rec« icon.

• In the window, the waveform records are shown in tabular form.

• A pop-up will appear by double clicking on a waveform record. Choose a folder where the waveform record is to be saved.

• The User can analyze the waveform records by means of the optionally available Quality Manager by clicking on »Yes« when asked “Shall the received waveform record be opened by the Quality Manager?"

Deleting Waveform Records

Within the »Operation/Waveform rec« menu, the User can:

• Delete waveform records;

• Choose the waveform record that is to be deleted via »SOFTKEY« »up« and »SOFTKEY« »down«;

• Call up the detailed view of the waveform record via »SOFTKEY« »right«;

• Confirm by pressing »SOFTKEY« »delete«;

• Enter the User password followed by pressing the »OK« key;

• Choose whether only the current or all waveform records should be deleted; and

• Confirm by pressing »SOFTKEY« »OK«.

Deleting Waveform Records Via PowerPort-E


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• Double click the »Recorders« icon in the navigation tree.

• Double click the »Waveform rec« icon.

• In the window, the waveform records are shown in tabular form.

• In order to delete a waveform record, double click on

(the red x) in front of the waveform record and confirm.

Direct Commands of the Waveform Recorder Module


Man. Trigger Manual Trigger False, True

False [Operation/Recorders/Man. Trigger]

Res all rec Reset all records Inactive, Active


Global Protection Parameters of the Waveform Recorder Module


Start: 1 Start recording if the assigned signal is true. 1..n, Assignment List Prot.Pickup [Device Para/Recorders/Waveform rec]

Start: 2 Start recording if the assigned signal is true. 1..n, Assignment List 87.H2,H4,H5 Blo

[Device Para/Recorders/Waveform rec]

Start: 3 Start recording if the assigned signal is true. 1..n, Assignment List -.- [Device Para/Recorders/Waveform rec]





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Auto overwriting

If there is no more free memory capacity left, the oldest file will be overwritten.

Inactive, Active

Active [Device Para/Recorders/Waveform rec]

Post-trigger time

The post trigger time is settable up to a maximum of 50% of the Maximum file size setting. The post-trigger will be the remaining time of the "Max file size" but at maximum "Post-trigger time"

0 - 50% 20% [Device Para/Recorders/Waveform rec]

Pre-trigger time The pre trigger time is settable up to a maximum of 50% of the Maximum file size setting.

0 - 50% 20% [Device Para/Recorders/Waveform rec]

Max file size The maximum storage capacity per record is 10 seconds, including pre-trigger and post-trigger time. The waveform recorder has a total storage capacity of 120 seconds.

0.1 – 10.0 s 2 s [Device Para/Recorders/Waveform rec]

Waveform Recorder Module Input States


Start1-I State of the module input:: Trigger event / start recording if:
















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Waveform Recorder Module Signals

Name Description

Recording Signal: RecordingMemory full Signal: Memory FullClear fail Signal: Clear Failure in MemoryRes all rec Signal: All records deletedRes record Signal: Delete Record Man. Trigger Signal: Manual Trigger

Special Parameters of the Waveform Recorder

Value Description Default Size Menu Path

Rec state Recording state Ready Ready, Recording, Writing file, Trigger Blo

[Operation/Status display/Recorders/Waveform rec]

Error code Error code OK OK, Write err, Clear fail, Calculation err, File not found, Auto overwriting off

[Operation/Status display/Recorders/Waveform rec]

Fault RecorderFault rec

The fault recorder can be started by one of eight start events (selection from the »Assignment list«/OR-Logic). It can register up to 20 faults. The last of the recorded faults is stored in a fail-safe manner.

If one of the assigned trigger events becomes true, the fault recorder will be started. When a trigger event happens, each fault is saved including the module and name, fault number, number of grid faults and record number at that time. For each of the faults, the measuring values (at the time when the trigger event became true) can be viewed.

Up to eight signals to trigger the fault recorder can be selected from the following list. The trigger events are OR-linked.

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The parameter »Auto Delete« defines how the device will react if there is no saving place available. In case »Auto Delete« is »Active«, the first recorded fault will be overwritten according to the FIFO principle. If the parameter is set to »Inactive«, recording of the fault events will be stopped until the storage location is released manually.

Read Out the Fault Recorder

The measured values at the time of tripping are saved (fail-safe) within the fault recorder. If there is no more memory free, the oldest record will be overwritten (FIFO).

In order to read out a failure record:

• Call up the main menu;

• Call up the sub-menu »Operation/Recorders/Fault rec.«;

• Select a fault record; and

• Analyze the corresponding measured values.

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Start: 1Trigger

Start: 2Trigger

Start: 3Trigger

Start: 4Trigger

Start: 5Trigger

Start: 6Trigger

Start: 7Trigger

Start: 8Trigger

Man. Trigger

RecordingOR

OR

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To Read Out the Fault Recorder Via PowerPort-E




• Double click the »Fault Rec« icon within the »Operation/Recorders« tree.

• In the window, the fault recordings are shown in tabular form.

• In order to receive more detailed information on a fault double click the selected item in the list.

Via the print menu, the User can export the data into a file. Please proceed as follows.

• Call up the data as described above.

• Call up the »File/Print« menu.

• Choose »Print Actual Working Window« within the pop-up.

• Press the »Print« button.

• Press the »Export to File« button.

• Enter a file name.

• Choose a location where to save the file.

• Confirm the »Save« button.

Direct Commands of the Fault Recorder Module




Man. Trigger Manual Trigger False, True

False [Operation/Recorders/Man. Trigger]

Global Protection Parameters of the Fault Recorder Module


Start: 1 Start recording if the assigned signal is true. 1..n, Assignment List Prot.Trip [Device Para/Recorders/Fault rec]

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Start: 2 Start recording if the assigned signal is true. 1..n, Assignment List -.- [Device Para/Recorders/Fault rec]







Auto overwriting

If there is no more free memory capacity left, the oldest file will be overwritten.

Inactive, Active

Active [Device Para/Recorders/Fault rec]

Fault Recorder Module Input States



[Device Para/Recorders/Fault rec]













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Fault Recorder Module Signals

Name Description

Res. Record Signal: Delete Record Man. Trigger Signal: Manual Trigger

Event RecorderEvent rec

The event recorder can register up to 300 events and the last 50 (minimum) saved events are stored in non-volatile memory, and therefore retained when power is lost to the unit. The following information is provided for any of the events.

Events are logged as follows:

Record No. Fault No. No of grid faults Date of Record Module Name State

Sequential Number Number of the ongoing fault.

This counter will be incremented by each General Pickup (Prot.Pickup).

A grid fault No. can have several Fault Nos.

This counter will be incremented by each General Pickup.(Exception AR: this applies only to devices that offer auto reclosing).

Time stamp What has changed? Changed Value

There are three different classes of events.

• Alternation of binary states are shown as:• 0->1 if the signal changes physically from »0« to »1«.• 1->0 if the signal changes physically from »1« to »0«.

• Counters increment is shown as:• Old Counter state -> New Counter state (e.g.: 3->4)

• Alternation of multiple states are shown as:• Old state -> New state (e.g.: 0->2)

Read Out the Event Recorder

• Call up the »main menu«.

• Call up the sub-menu »Operation/Recorders/Event rec«.

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• Select an event.

To Read Out the Event Recorder Via PowerPort-E


• If the device data have not been loaded, click »Receive Data From The Device« in the »Device menu.


• Double click the »Event Rec« icon within the »Operation/Recorders« menu.

• In the window, the events are shown in tabular form.

To have the event recorder updated in a cyclic manner, select »Automatic Up-Date« in the »View« menu.

PowerPort-E is able to record more events than the device itself, if the window of the event recorder is opened and »Automatic Up-Date« is set to active.

Via the print menu, the User can export the data into a file. Please proceed as follows.

• Call up the data as described above.

• Call up the »File/Print« menu.

• Choose »Print Actual Working Window« within the pop-up.

• Press the »Print« button.

• Press the »Export to File« button.

• Enter a file name.

• Choose a location where to save the file.

• Confirm the »Save« button.

Direct Commands of the Event Recorder Module




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Event Recorder Module Signals

Name Description

Res all rec Signal: All records deleted

Trend RecorderAvailable Elements:Trend rec

Functional Description

The Trend Data are data points stored by the Trend Recorder on the relay device over fixed intervals of time, and can be downloaded from the device using PowerPort-E. A Trend Record is viewable using the Quality Monitor software by selecting files saved by PowerPort-E with a file extension of “.ErTr”. The list of available trend recorder data is viewable by selecting [Operation/ Recorders/Trend Recorder] on the front panel of the relay.

When viewed within the Quality Manager, the trend record will show the observed values (up to 10) that the User has specified. The available values are dependent on the ordered protective device.

Managing Trend Records

To download information from the Trend Recorder, select [Operation/Recorder/Trend Rec] from the menu tree. The User will find three options within the Trend Recorder window that will allow the User to:

• Receive Trend Records,• Refresh the Trend Recorder, and • Delete Trend Records.

Selecting the »Receive Trend Record« button will download data from the relay to the User's PC. By selecting the »Refresh Trend Recorder«”, PowerPort-E updates the list of the Trend Recorder. The »Delete Trend Recorder« function will clear all trend data from the relay, leaving the data files on the User's PC.

To view data using the Quality Manager, first the User must open the desired “.ErTr” file to be viewed from a folder location previously designated by the User. Once the “.ErTr” file is open, the User will see the “Analog Channels” that are monitored by the Trend Recorder. By clicking on the “Analog Channels”, all monitored parameters are listed. To view a channel, the User must click on the left mouse key, then drag and drop the channel onto the right side of the Quality Manager screen. The channel is then listed under the »Displayed Channels«.

To remove a channel from view, the User must select the Trend Data to be removed in the »Displayed Channels« menu tree, then click on the right mouse button to bring up the menu options. Here, the User will find the »Remove« menu option that, when selected, will remove the trend data.

Configuring the Trend Recorder

The Trend Recorder is to be configured within [Device Para/Recorders/Trend Recorder] menu.

The User has to set the time interval. This defines the distance between two measuring points.

The User can select up to ten values that will be recorded.

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Selection List for Trending

Name Description

-.- No assignmentVT.VA RMS Measured value: Phase-to-neutral voltage (RMS)VT.VB RMS Measured value: Phase-to-neutral voltage (RMS)VT.VC RMS Measured value: Phase-to-neutral voltage (RMS)VT.VX meas RMS Measured value (measured): VX measured (RMS)VT.VAB RMS Measured value: Phase-to-phase voltage (RMS)VT.VBC RMS Measured value: Phase-to-phase voltage (RMS)VT.VCA RMS Measured value: Phase-to-phase voltage (RMS)VT.V0 Fund. Measured value (calculated): Symmetrical components Zero

voltage(Fundamental)VT.V1 Fund. Measured value (calculated): Symmetrical components positive

phase sequence voltage(Fundamental)VT.V2 Fund. Measured value (calculated): Symmetrical components negative

phase sequence voltage(Fundamental)VT.VA avg RMS VA average value (RMS)VT.VB avg RMS VB average value (RMS)VT.VC avg RMS VC average value (RMS)VT.VAB avg RMS VAB average value (RMS)VT.VBC avg RMS VBC average value (RMS)VT.VCA avg RMS VCA average value (RMS)VT.f Measured Value: FrequencyVT.VA THD Measured value (calculated): VA Total Harmonic Distortion VT.VB THD Measured value (calculated): VB Total Harmonic Distortion VT.VC THD Measured value (calculated): VC Total Harmonic Distortion VT.VAB THD Measured value (calculated): VAB Total Harmonic Distortion VT.VBC THD Measured value (calculated): VBC Total Harmonic Distortion VT.VCA THD Measured value (calculated): VCA Total Harmonic Distortion CT W1.IA RMS Measured value: Phase current (RMS)CT W1.IB RMS Measured value: Phase current (RMS)CT W1.IC RMS Measured value: Phase current (RMS)CT W1.IX meas RMS Measured value (measured): IX (RMS)CT W1.IR calc RMS Measured value (calculated): IR (RMS)CT W1.I0 Fund. Measured value (calculated): Zero current (Fundamental)CT W1.I1 Fund. Measured value (calculated): Positive phase sequence current

(Fundamental)CT W1.I2 Fund. Measured value (calculated): Unbalanced load current

(Fundamental)CT W1.IA avg RMS IA average value (RMS)CT W1.IB avg RMS IB average value (RMS)

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Name Description

CT W1.IC avg RMS IC average value (RMS)CT W1.IA THD Measured Value (Calculated): IA Total Harmonic Current CT W1.IB THD Measured Value (Calculated): IB Total Harmonic Current CT W1.IC THD Measured Value (Calculated): IC Total Harmonic Current CT W2.IA RMS Measured value: Phase current (RMS)CT W2.IB RMS Measured value: Phase current (RMS)CT W2.IC RMS Measured value: Phase current (RMS)CT W2.IX meas RMS Measured value (measured): IX (RMS)CT W2.IR calc RMS Measured value (calculated): IR (RMS)CT W2.I0 Fund. Measured value (calculated): Zero current (Fundamental)CT W2.I1 Fund. Measured value (calculated): Positive phase sequence current

(Fundamental)CT W2.I2 Fund. Measured value (calculated): Unbalanced load current

(Fundamental)CT W2.IA avg RMS IA average value (RMS)CT W2.IB avg RMS IB average value (RMS)CT W2.IC avg RMS IC average value (RMS)CT W2.IA THD Measured Value (Calculated): IA Total Harmonic Current CT W2.IB THD Measured Value (Calculated): IB Total Harmonic Current CT W2.IC THD Measured Value (Calculated): IC Total Harmonic Current URTD.W1-A Measured Value: Winding TemperatureURTD.W1-A max Measured Value: Winding Temperature Maximum ValueURTD.W1-B Measured Value: Winding TemperatureURTD.W1-B max Measured Value: Winding Temperature Maximum ValueURTD.W1-C Measured Value: Winding TemperatureURTD.W1-C max Measured Value: Winding Temperature Maximum ValueURTD.W2-A Measured Value: Winding TemperatureURTD.W2-A max Measured Value: Winding Temperature Maximum ValueURTD.W2-B Measured Value: Winding TemperatureURTD.W2-B max Measured Value: Winding Temperature Maximum ValueURTD.W2-C Measured Value: Winding TemperatureURTD.W2-C max Measured Value: Winding Temperature Maximum ValueURTD.Amb1 Measured Value: Ambient TemperatureURTD.Amb1 max Measured Value: Ambient Temperature Maximum ValueURTD.Amb2 Measured Value: Ambient TemperatureURTD.Amb2 max Measured Value: Ambient Temperature Maximum ValueURTD.Aux1 Measured Value: Auxiliary TemperatureURTD.Aux1 max Measured Value: Auxiliary Temperature Maximum ValueURTD.Aux2 Measured Value: Auxiliary TemperatureURTD.Aux2 max Measured Value: Auxiliary Temperature Maximum Value

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Name Description

URTD.Aux3 Measured Value: Auxiliary TemperatureURTD.Aux3 max Measured Value: Auxiliary Temperature Maximum ValueURTD.Aux4 Measured Value: Auxiliary TemperatureURTD.Aux4 max Measured Value: Auxiliary Temperature Maximum ValueURTD.RTD Max Maximum temperature of all channels.RTD.Hottest WD W1 Hottest winding on side W1RTD.Hottest WD W2 Hottest winding on side W2RTD.Hottest Amb Hottest Ambient TemperatureRTD.Hottest Aux Hottest Auxiliary temperature in degrees C. Resettable with "Sys

Res OperationsCr" or "All".ECr.Disp PF Measured Value (Calculated): 55D - Displacement Power FactorECr.Apt PF Measured Value (Calculated): 55A - Apparent Power FactorECr.Syst VA RMS Measured VAs (RMS)ECr.VAh Net Net VA HoursAnIn[1].Value Measured value of the Input in percentAnIn[2].Value Measured value of the Input in percent

Global Protection Parameters of the Trend Recorder


Resolution Resolution (recording frequency) 60 min, 30 min, 15 min, 10 min, 5 min

15 min [Device Para/Recorders/Trend rec]

Observed Value1

Observed Value1 1..n, TrendRecList CT W1.IA RMS [Device Para/Recorders/Trend rec]

Observed Value2

Observed Value2 1..n, TrendRecList CT W1.IB RMS [Device Para/Recorders/Trend rec]

Observed Value3

Observed Value3 1..n, TrendRecList CT W1.IC RMS [Device Para/Recorders/Trend rec]

Observed Value4

Observed Value4 1..n, TrendRecList CT W1.IX meas RMS

[Device Para/Recorders/Trend rec]

Observed Value5

Observed Value5 1..n, TrendRecList VT.VA RMS [Device Para/Recorders/Trend rec]

Observed Value6

Observed Value6 1..n, TrendRecList VT.VB RMS [Device Para/Recorders/Trend rec]

Observed Value7

Observed Value7 1..n, TrendRecList VT.VC RMS [Device Para/Recorders/Trend rec]

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Observed Value8

Observed Value8 1..n, TrendRecList VT.VX meas RMS

[Device Para/Recorders/Trend rec]

Observed Value9

Observed Value9 1..n, TrendRecList -.- [Device Para/Recorders/Trend rec]

Observed Value10

Observed Value10 1..n, TrendRecList -.- [Device Para/Recorders/Trend rec]

Trend Recorder Module Signals (Output States)

Name Description

Hand Reset Hand Reset

Direct Commands of the Trend Recorder


Reset Delete all entries Inactive, Active


Counter Values of the Trend Recorder


Max avail Entries Maximum available entries in the current configuration

0 0 - 9999999999 [Operation/Count and RevData/Trend rec]

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Communication ProtocolsModbus®

Modbus

Modbus® Protocol Configuration

The time-controlled Modbus® protocol is based on the master-slave working principle. This means that the substation control and protection system sends an inquiry or instruction to a certain device (slave address) that will then be answered or carried out accordingly. If the inquiry/instruction cannot be answered/carried out (e.g.: because of an invalid slave address), a failure message is returned to the master.

The master (substation control and protection system) can query information from the device, such as:

• Type of unit version;• Measuring values/statistical measured values;• Switch operating position (in preparation);• State of device;• Time and date;• State of the device’s digital inputs; and• Protection-/state pickups.

The master (control system) can give commands/instructions to the device, such as:

• Control of switchgear (where applicable, i.e.: each according to the applied device version);• Change-over of parameter set;• Reset and acknowledgment of pickups/signals;• Adjustment of the date and time; and• Control of pickup relays.

For detailed information on data point lists and error handling, please refer to the Modbus® documentation.

To allow configuration of the devices for Modbus® connection, some default values of the control system must be available.

Device Planning Parameters of the Modbus


Mode Mode RTU, TCP

RTU [Device Plan-ning]

Modbus RTU

Part 1: Configuration of the Devices

Call up »Device parameter/Modbus« and set the following communication parameters:

• Slave address, to allow clear identification of the device; and

• Baud rate.

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Also, select the RS485 interface-related parameters such as:

• Number of data bits;

• One of the following supported communication variants:• Number of data bits,• Even,• Odd,• Parity or no parity, or• Number of stop bits;

• »t-timeout«: communication errors are only identified after expiration of a supervision time »t-timeout«; and

• Response time (defining the period within which an inquiry from the master has to be answered).

Part 2: Hardware Connection

• For hardware connection to the control system, there is an RS485 interface at the rear side of the device (RS485, fiber optic or terminals).

• Connect the bus and the device (wiring).

• Up to 32 devices can be connected to the bus (point to point connection/spurs).

• Connect a terminating resistor to the bus.

Error Handling - Hardware Errors

Information on physical communication errors, such as:

• Baud rate error and• Parity error;

can be obtained from the event recorder.

Error Handling – Errors on Protocol Level

If, for example, an invalid memory address is inquired, error codes will be returned by the device that need to be interpreted.

Modbus TCP

Establishing a connection via TCP/IP to the device is only possible if the device is equipped with an Ethernet Interface (RJ45).


Part 1: Setting the TCP/IP Parameters

Call up »Device parameter/TCP/IP« at the HMI (panel) and set the following parameters:

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• TCP/IP address;

• Subnetmask; and

• Gateway.

Part 2: Configuration of the Devices

Call up »Device parameter/Modbus« and set the following communication parameters.

• Setting a unit identifier is only necessary if a TCP network should be coupled to a RTU network.

• If a different port than the default port 502 should be used, please proceed as follows:

• Choose “Private” within the TCP-Port-Configuration.

• Set the port number.

• Set the maximum acceptable time out for “no communication”. If this time has expired without any communication, the device concludes a failure has occurred within the master system.

• Allow or disallow the blocking of SCADA commands.

Part 3: Hardware Connection

• There is a RJ45 interface at the rear side of the device for the hardware connection to the control system.

• Establish the connection to the device by means of a proper Ethernet cable.

Direct Commands of the Modbus®


Res Diagn Cr All Modbus Diagnosis Counters will be reset.

Inactive, Active


Global Protection Parameters of the Modbus®


Slave ID Device address (Slave ID) within the bus system. Each device address has to be unique within a bus system.

Only available if:Device Planning = RTU

1 - 247 1 [Device Para/Modbus]

Unit ID The Unit Identifier is used for routing. This parameter is to be set, if a Modbus RTU and a Modbus TCP network should be coupled.

Only available if:Device Planning = TCP


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TCP Port Config

TCP Port Configuration. This parameter is to be set only if the default modbus TCP Port should not be used.

Only available if:Device Planning = TCP

Default, Private

Default [Device Para/Modbus]

Port Port number

Only available if:Device Planning = TCP And Only available if: TCP Port Config = Private


t-timeout Within this time the answer has to be received by the Communication system, otherwise the request will be disregarded. In that case, the Communication system detects a communication failure and the Communication System has to send a new request.


0.01 – 10.00 s 1 s [Device Para/Modbus]

Baud rate Baud rate


1200, 2400, 4800, 9600, 19200, 38400

19200 [Device Para/Modbus]

Physical Settings

Digit 1: Number of bits. Digit 2: E=even parity, O=odd parity, N=no parity. Digit 3: Number of stop bits. More information on the parity: It is possible that the last data bit is followed by a parity bit which is used for recognition of communication errors. The parity bit ensures that with even parity ("EVEN") always an even number of bits with valence "1" or with odd parity ("ODD") an odd number of "1" valence bits are transmitted. But it is also possible to transmit no parity bits (here the setting is "Parity = None"). More information on the stop-bits: The end of a data byte is terminated by the stop-bits.


8E1, 8O1, 8N1, 8N2

8E1 [Device Para/Modbus]

t-call If there is no request message sent from Communication to the device after expiry of this time, the device concludes a communication failure within the Communication system.

1 – 3600 s 10 s [Device Para/Modbus]

Comm CmdBlo Activating (allowing)/ Deactivating (disallowing) the blocking of the Communication Commands

Inactive, Active

Inactive [Device Para/Modbus]

Disable Latching

Disable Latching: If this parameter is active (true), none of the Modbus states will be latched. That means that trip signals wont be latched by Modbus.

Inactive, Active

Inactive [Device Para/Modbus]

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AllowGap If this parameter is active (True), the User can request a set of modbus register without getting an exception, because of invalid address in the requested array. The invalid addresses have a special value 0xFAFA, but the User is responsible for ignoring invalid addresses. Attention: This special value can be valid, if address is valid.

Inactive, Active

Active [Device Para/Modbus]

Modbus® Module Signals (Output States)

Some signals (that are active for a short time only) have to be acknowledged separately (e.g.: trip signals) by the communication system.

Name Description

Transmission Signal: Communication ActiveComm Cmd 1 Communication CommandComm Cmd 2 Communication CommandComm Cmd 3 Communication CommandComm Cmd 4 Communication CommandComm Cmd 5 Communication CommandComm Cmd 6 Communication CommandComm Cmd 7 Communication CommandComm Cmd 8 Communication CommandComm Cmd 9 Communication CommandComm Cmd 10 Communication CommandComm Cmd 11 Communication CommandComm Cmd 12 Communication CommandComm Cmd 13 Communication CommandComm Cmd 14 Communication CommandComm Cmd 15 Communication CommandComm Cmd 16 Communication Command

Modbus® Module Values


NoOfRequestsTotal Total number of requests. Includes requests for other slaves.

0 0 - 9999999999 [Operation/Count and RevData/Modbus]

NoOfRequestsForMe Total Number of requests for this slave.


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NoOfResponse Total number of requests having been responded.


NoOfResponsTimeOverruns

Total number of requests with exceeded response time. Physically corrupted Frame.


NoOfOverrunErros Total Number of Overrun Failures. Physically corrupted Frame.


NoOfParityErrors Total number of parity errors. Physically corrupted Frame.


NoOfFrameErrors Total Number of Frame Errors. Physically corrupted Frame.


NoOfBreaks Number of detected communication aborts


NoOfQueryInvalid Total Number of Request errors. Request could not be interpreted


NoOfInternalError Total Number of Internal errors while interpreting the request.


IEC 61850IEC61850

Introduction

To understand the functioning and mode of operation of a substation in an IEC 61850 automation environment, it is useful to compare the commissioning steps with those of a conventional substation in a Modbus TCP environment. In a conventional substation, the individual Intelligent Electronic Devices (IEDs) communicate in a vertical direction with the higher level control center via Communication. The horizontal communication is exclusively realized by wiring relay output contacts (RO) and digital inputs (DI) together.

In an IEC 61850 environment, communication between the IEDs takes place digitally (via Ethernet) by a service called Generic Object Oriented Substation Event (GOOSE). By means of this service, information about events is submitted between each IED. Therefore each IED has to know about the functional capability of all other connected IEDs.

Each IEC 61850 capable device includes a description of its own functionality and communications skills (IED Capability Description, *.ICD). By means of a Substation Configuration Tool to describe the structure of the substation, assignment of the devices to the primary technique, etc., virtual wiring of the IEDs between each other and with other switch gear of the substation can be achieved. A description of the substation configuration will be generated in the form of a *.SCD file. Finally, this file has to be submitted to each device. Now the IEDs are able to communicate with each other, react to interlockings, and operate switch gear.

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Commissioning steps for a conventional substation with modbus TCP environment:

• Parameter setting of the IEDs;• Ethernet installation;• TCP/IP settings for the IEDs; and• Wiring according to wiring scheme.

Commissioning steps for a substation with IEC 61850 environment:

1. Parameter setting of the IEDsEthernet installationTCP/IP settings for the IEDs

2. IEC 61850 configuration (software wiring)a) Exporting an ICD file from each deviceb) Configuration of the substation

(generating a SCD file)c) Transmit SCD file to each device.

Generation/Export of a Device Specific ICD File

Each Eaton IEC 61850 capable device includes a description of its own functionality and communications skills in the form of an IED Capability Description (*.ICD) file. This file can be exported as follows and be used for the configuration of the substation.

A change of the devices parameters has an influence on the content of the ICD file.

1. Connect the device with your PC/Notebook.2. Start PowerPort E.3. Click on »Receive data from Device« in the »Device« menu.4. Click on »IEC 61850« in the »Device Para« menu.5. Click on the ICD icon in the IEC 61850 window.6. Select a drive and file name for the ICD file and click "save".7. Repeat the steps 1 to 6 for all connected devices in this IEC 61850 environment.

Generation/Export of a SCD file

Each device of the HighPROTEC can create an export it's own functionality and communications skills in form of a *.SCD file.

1. Connect the device with your PC/Notebook.2. Start Smart view.3. Click on »Receive data from Device« in the menu »Device«.4. Click on »IEC61850« in the menu »Device Para«.5. Click on the SCD icon in the IEC61850 window.6. Select a drive and file name for the SCD file and click "save".

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Ethernet

Com

mIE

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GOOSE IEC61850 soft wiring

IED1 IED2 IED3

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Ethernet

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7. Repeat the steps 1 to 6 for all connected devices in this IEC61850 environment.

Generation of a Substation Configuration Description (SCD) File

The substation configuration (i. e. connection of all logical nodes of protection and control devices) as well as switch gear usually is done with a ”Substation Configuration Tool“. Therefore the ICD files of all connected IEDs in the IEC 61850 environment have to be available. The result of the station wide “software wiring” can be exported in the form of a Station Configuration Description (SCD) file.

Suitable Substation Configuration Tools (SCT) are available by the following Companies:

• H&S, Hard- & Software Technologie GmbH & Co. KG, Dortmund (Germany) (www.hstech.de)• Applied Systems Engineering Inc. (www.ase-systems.com)• Kalki Communication Technologies Limited (www.kalkitech.com)

Import of the *.SCD File into the Device

When the substation configuration is completed, the *.SCD file has to be transmitted to all connected devices. This is has to be done as follows:

1. Connect the device with your PC/notebook.2. Start PowerPort E.3. Click on »Receive data from Device« in the »Device« menu.4. Click on »IEC 61850« in the »Device Para« menu.5. Switch the parameter »IEC 61850 Communication« to »OFF« and submit the changed parameter set

into the device.6. Click on the IEC icon in the IEC 61850 window.7. Select the folder where the *.SCD file is stored. Select the *.SCD file and click "Open".8. A password is requested. Enter the same password, which you use for parameter setting of the device.9. Following Step 5, again switch on the IEC Communication and submit the changed parameter set into

the device.10. Repeat Steps 1 through 9 for all devices connected to this IEC 61850 environment.11. If no error message occurs, the configuration has been completed successfully.

• When changing the substation configuration, usually a new *.SCD file has to be generated. This *.SCD file must be transmitted to all devices by means of PowerPort E. If the file is not transmitted to all devices, IEC 61850 malfunctions will be the result.

• If the parameters of the devices are changed after the completion of the substation configuration, changes in the corresponding *.ICD file may result. This, in turn, may make an update of the *.SCD file necessary.

IEC 61850 Virtual Outputs

In addition to the standardized logical node status information, up to 16 free configurable status information items can be assigned to the 16 Virtual Outputs. This can be done in the [Device Para/IEC61850] menu.

Device Planning Parameters of the IEC 61850



Use [Device Plan-ning]

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Direct Commands of the IEC 61850


ResetStatistic Reset of all IEC61850 diagnostic counters Inactive, Active


Global Protection Parameters of the IEC 61850



Inactive, Active

Inactive [Device Para/IEC61850]

VirtualOutput1 Virtual Output. This signal can be assigned or visualized via the SCD file to other devices within the IEC61850 substation.

1..n, Assignment List -.- [Device Para/IEC61850]

























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States of the Inputs of the IEC 61850


VirtOut1-I Module input state: Binary state of the Virtual Output (GGIO)

[Device Para/IEC61850]































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IEC 61850 Module Signals (Output States)

Name Description

VirtInp1 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp2 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp3 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp4 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp5 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp6 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp7 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp8 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp9 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp10 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp11 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp12 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp13 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp14 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp15 Signal: Virtual Input (IEC61850 GGIO Ind)VirtInp16 Signal: Virtual Input (IEC61850 GGIO Ind)

IEC 61850 Module Values


NoOfGooseRxAll Total number of received GOOSE messages including messages for other devices (subscribed and not subscribed messages).

0 0 - 9999999999 [Operation/Count and RevData/IEC61850]

NoOfGooseRxSubscribed

Total Number of subscribed GOOSE messages including messages with incorrect content.


NoOfGooseRxCorrect

Total Number of subscribed and correctly received GOOSE messages.


NoOfGooseRxNew Number of subscribed and correctly received GOOSE messages with new content.


NoOfGooseTxAll Total Number of GOOSE messages that have been published by this device.


NoOfGooseTxNew Total Number of new GOOSE messages (modified content) that have been published by this device.


NoOfServerRequestsAll

Total number of MMS Server requests including incorrect requests.


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NoOfDataReadAll Total Number of values read from this device including incorrect requests.


NoOfDataReadCorrect

Total Number of correctly read values from this device.


NoOfDataWrittenAll Total Number of values written by this device including incorrect ones.


NoOfDataWrittenCorrect

Total Number of correctly written values by this device.


NoOfDataChangeNotification

Number of detected changes within the datasets that are published with GOOSE messages.


Values of the IEC 61850


GoosePublisherState

State of the GOOSE Publisher (on or off)

Off Off, On, Error

[Operation/Status display/IEC61850]

GooseSubscriberState

State of the GOOSE Subscriber (on or off)

Off Off, On, Error


MmsServerState State of MMS Server (on or off) Off Off, On, Error


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Time SynchronizationTimeZones

The device gives the User the ability to synchronize the device with a central time generator. This provides the following advantages:

• The time does not drift from the reference time. A continuously accumulating deviation of the reference time thereby will be balanced. Also refer to the Specifications (Tolerances Real Time Clock) section.

• All time synchronized devices operate with the same time. Therefore, logged events of the individual devices can be compared exactly and be evaluated (single events of the event recorder, waveform records).

The device's time can be synchronized via the following protocols:

• IRIG-B;• SNTP; and/or• Communications-Protocol Modbus (RTU or TCP).

These protocols use different hardware interfaces and are different in accuracy. Further information can be found in the Specifications section.

Used Protocol Hardware-Interface Recommended Application

Without time synchronization

--- Not recommended.

IRIG-B IRIG-B Terminal Recommend, if interface available.SNTP RJ45 (Ethernet) Recommend alternative to IRIG-B, especially when using

IEC 61850 or Modbus TCP.Modbus RTU RS485, D-SUB or Fiber

OpticRecommend when using Modbus RTU communication protocol and when no

IRIG-B real time clock is available.Modbus TCP RJ45 (Ethernet) Limited recommendation when Modbus TCP communication protocol is used

and when no IRIG-B real time clock or SNTP-Server is available.

Accuracy of Time Synchronization

The accuracy of the device's synchronized system time depends on different factors:

• Accuracy of the connected time generator;• Synchronization protocol that is used; and• At Modbus TCP and SNTP: Network load and data package transmission times

Please consider the accuracy of the time generator used. Deviations of the time generator's time causes the same deviations on the device's system time.

Selection of Timezone and Synchronisation Protocol

The protection relay masters both UTC and local time. This means that the device can be synchronised with UTC time while using local time for User display.

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Time Synchronisation with UTC time (recommended):

Time synchronisation is usually done using UTC time. This means for example that an IRIG-B time generator is sending UTC time information to the protection relay. This is the recommended use case, since here a continuous time synchronisation can be ensured. There are no “leaps in time” through change of Daylight Savings Time.

To achieve that the device shows the current local time, the timezone and the change to Daylight Savings Time can be configured.

Please carry out the following parameterization steps under [Device Para/ Time]:

1. Select your local timezone in the timezone menu.2. There also configure the switching of daylight savings time.3. Select the used time synchronisation protocol in the TimeSync menu (e.g. “IRIG-B”).4. Set the parameters of the synchronisation protocol (refer to the according chapter).

Time Synchronisation with local time:

Should the time synchronisation however be done using local time, then please leave the timezone to »UTC+0 London« and do not use switching of daylight saving time.

The synchronisation of the relay´s system time is exclusively done by the synchronisation protocol selected in the menu [Device Para/ Time/ TimeSync/ Used Protocol].

Without Time Synchronisation:

To achieve that the device shows the current local time, the timezone and the change to Daylight Savings Time can be configured.

Please carry out the following parameterization steps under [Device Para/ Time]:

1. Select your local timezone in the timezone menu.2. There also configure the switching of daylight savings time.3. Select »manual« as your used protocol in the TimeSync menu.4. Set date and time.

Global Protection Parameters of the Time Synchronization


DST offset Difference to wintertime -180 – 180 min 60 min [Device Para/Time/Timezone]

DST manual Manual setting of the Daylight Saving Time Inactive, Active

Active [Device Para/Time/Timezone]

Summertime Daylight Saving Time

Only available if: DST manual = Active

Inactive, Active

Inactive [Device Para/Time/Timezone]

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Summertime m Month of clock change summertime


January, February, March, April, May, June, July, August, September, October, November, December

March [Device Para/Time/Timezone]

Summertime d Day of clock change summertime


Sunday, Monday, Tuesday, Wednesday, Thursday, Friday, Saturday, General day

Saturday [Device Para/Time/Timezone]

Summertime w Place of selected day in month (for clock change summertime)


First, Second, Third, Fourth, Last

Last [Device Para/Time/Timezone]

Summertime h Hour of clock change summertime


0 – 23 h 2 h [Device Para/Time/Timezone]

Summertime min

Minute of clock change summertime


0 – 59 min 0 min [Device Para/Time/Timezone]

Wintertime m Month of clock change wintertime


January, February, March, April, May, June, July, August, September, October, November, December

October [Device Para/Time/Timezone]

Wintertime d Day of clock change wintertime


Sunday, Monday, Tuesday, Wednesday, Thursday, Friday, Saturday, General day

Saturday [Device Para/Time/Timezone]

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Wintertime w Place of selected day in month (for clock change wintertime)


First, Second, Third, Fourth, Last

Last [Device Para/Time/Timezone]

Wintertime h Hour of clock change wintertime


0 – 23 h 3 h [Device Para/Time/Timezone]

Wintertime min Minute of clock change wintertime


0 – 59 min 0 min [Device Para/Time/Timezone]

Time Zones Time Zones UTC+14 Kiritimati, UTC+13 Rawaki, UTC+12.75 Chatham Island, UTC+12 Wellington, UTC+11.5 Kingston, UTC+11 Port Vila, UTC+10.5 Lord Howe Island, UTC+10 Sydney, UTC+9.5 Adelaide, UTC+9 Tokyo, UTC+8 Hong Kong, UTC+7 Bangkok, UTC+6.5 Rangoon, UTC+6 Colombo, UTC+5.75 Kathmandu, UTC+5.5 New Delhi, UTC+5 Islamabad, UTC+4.5 Kabul, UTC+4 Abu Dhabi, UTC+3.5 Tehran, UTC+3 Moscow, UTC+2 Athens, UTC+1 Berlin, UTC+0 London, UTC-1 Azores, UTC-2 Fern. d. Noronha, UTC-3 Buenos Aires, UTC-3.5 St. John’s, UTC-4 Santiago, UTC-5 New York, UTC-6 Chicago, UTC-7 Salt Lake City, UTC-8 Los Angeles, UTC-9 Anchorage, UTC-9.5 Taiohae, UTC-10 Honolulu, UTC-11 Midway Islands

UTC+0 London [Device Para/Time/Timezone]

TimeSync Time synchronization -, SNTP, IRIG-B, Modbus

- [Device Para/Time/TimeSync/TimeSync]

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SNTPSNTP

Important pre-condition: The device needs to have access to an SNTP server via the connected network. This server preferably should be installed locally.

Principle – General Use

SNTP is a standard protocol for time synchronization via a network. At minimum, one SNTP server has to be integrated into the network. The device can be configured for one or two connected SNTP servers.

The device's system time will be synchronized by the connected SNTP server 1 to 4 times per minute. In turn, the SNTP server synchronizes its time via NTP with other NTP servers. This is the normal case. Alternatively it can receive its time via GPS, radio controlled clock, or the like.

If the server's “Stratum” has been set manually, it is not an indication of its quality or reliability.

Accuracy

The accuracy of the SNTP server used and the accuracy of its reference clock influences the accuracy of the protection relay's clock.

With each transmitted time information, the SNTP server sends information about its accuracy:

• Stratum: The stratum gives information on how close the SNTP server within the cluster is to other NTP servers that are connected to an atomic clock.

• Precision: This is the accuracy, the SNTP server provides the system time.

Also the performance (traffic and data package transmission time) of the connected network has an influence on the accuracy of the time synchronization A locally installed SNTP server with an accuracy of ≤200 µsec is recommended. If this cannot be provided, the connected server's accuracy can be checked in the

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Protective Relay

GPS Satellite Signal (optional )

GPS Connection (optional )

TCP/IPNTP-Server

SNTP-Protocol

NTP-Protocol

TCP/IP

(option)

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[Operation/Status Display/Time Sync.] menu:

• The server quality gives information about the accuracy of the used server. The quality should be GOOD or SUFFICENT. A server with BAD quality should not be used because this could cause fluctuations of the time synchronization

• The network quality gives information about the network's load and data package transmission time. The quality should be GOOD or SUFFICENT. A network with BAD quality should not be used because this could cause fluctuations during time synchronization

Using Two SNTP Servers

When configuring two SNTP servers, the device selects the server with the lower stratum value because this provides a more precise time synchronization If the servers have the same stratum value, the device selects the server with the better accuracy (precision). It does not matter which of the servers is configured as Server 1 or Server 2. When the last used server fails, the device automatically switches to the other server. When the server recovers, the device switches back to the previous one with the better quality.

SNTP Commissioning

Activate the SNTP time synchronization by means of the [Device Para/ Time/ TimeSync] menu:

• Select »SNTP« in the time synchronisation menu.• Set the IP address of the first server in the SNTP menu.• Set the IP address of the second server, if available.• Set all configured servers to “active”.

Fault Analysis

If there is no SNTP signal for more than 120 seconds., the SNTP status changes from “active” to “inactive” and an entry in the Event Recorder will be set.

The SNTP functionality can be checked in the [Operation/Status Display/Time Sync./Sntp] menu.If the SNTP status is not “active”, please proceed as follows:

• Check if the wiring is correct (Ethernet-cable connected).• Check if a valid IP address is set in the device (Device Para/TCP/IP).• Check if the Ethernet connection is active (Device Para/TCP/IP/Link = Up?).• Check if the SNTP server as well as the protection device answers to a Ping.• Check if the SNTP server is up and working.

Device Planning Parameters of the SNTP




Direct Commands of the SNTP


Res Counter Reset all Counters. Inactive, Active


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Global Protection Parameters of the SNTP


Server1 Server 1 Inactive, Active

Inactive [Device Para/Time/TimeSync/SNTP]

IP Byte1 IP1.IP2.IP3.IP4 0 - 255 0 [Device Para/Time/TimeSync/SNTP]




Server2 Server 2 Inactive, Active

Inactive [Device Para/Time/TimeSync/SNTP]





Signals of the SNTP

Name Description

SNTP active Signal: If there is no valid SNTP signal for 120 sec, SNTP is regarded as inactive.

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SNTP Counters


NoOfSyncs Total Number of Synchronizations. 0 0 - 9999999999 [Operation/Count and RevData/TimeSync/SNTP]

NoOfConnectLost Total Number of lost SNTP Connections (no sync for 120 sec).

0 0 - 9999999999 [Operation/Count and RevData/TimeSync/SNTP]

NoOfSmallSyncs Service counter: Total Number of very small Time Corrections.


NoOfNormSyncs Service counter: Total Number of normal Time Corrections.


NoOfBigSyncs Service counter: Total Number of big Time Corrections.


NoOfFiltSyncs Service counter: Total Number of filtered Time Corrections.


NoOfSlowTrans Service counter: Total Number of slow Transfers.


NoOfHighOffs Service counter: Total Number of high Offsets.


NoOfIntTimeouts Service counter: Total Number of internal timeouts.


StratumServer1 Stratum of Server 1 0 0 - 9999999999 [Operation/Status display/TimeSync/SNTP]

StratumServer2 Stratum of Server 2 0 0 - 9999999999 [Operation/Status display/TimeSync/SNTP]

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SNTP Values


Used Server Which Server is used for SNTP synchronization.

None Server1, Server2 , None

[Operation/Status display/TimeSync/SNTP]

PrecServer1 Precision of Server 1 0 ms 0 – 1000.00000 ms [Operation/Status display/TimeSync/SNTP]

PrecServer2 Precision of Server 2 0 ms 0 – 1000.00000 ms [Operation/Status display/TimeSync/SNTP]

ServerQlty Quality of Server used for Synchronization (GOOD, SUFFICIENT, BAD)

- GOOD, SUFFICENT, BAD, -


NetConn Quality of Network Connection (GOOD, SUFFICIENT, BAD).

- GOOD, SUFFICENT, BAD, -


IRIG-B00XIRIG-B

Requirement: An IRIG-B00X time code generator is needed. IRIG-B004 and higher will support/transmit the “year information”.

If you are using an IRIG time code that does not support the “year information” (IRIG-B000, IRIG-B001, IRIG-B002, IRIG-B003), you have to set the “year” manually within the device. In these cases the correct year information is a precondition for a properly working IRIG-B.

Principle - General Use

The IRIG-B standard is the most used standard to synchronize the time of protection devices in medium voltage applications.

The protection device supports IRIG-B according to the IRIG STANDARD 200-04. This means that all time synchronization formats IRIG-B00X (IRIG-B000 / B001 / B002 / B003 / B004 / B005 / B006 / B007) are supported. It is recommended to use IRIG-B004 and higher which also transmits the “year information”.

The system time of the protection device is being synchronized with the connected IRIG-B code generator once a second. The accuracy of the used IRIG-B code generator can be increased by connecting a GPS-receiver to it.

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The location of the IRIG-B interface depends to the device type. Please refer to the wiring diagram supplied with the protective device.

IRIG-B Commissioning

Activate the IRIG-B synchronization within menu [Device Para/ Time/ TimeSync]:

• Select »IRIG-B« in the time synchronisation menu.• Set the time synchronization in the IRIG-B menu to »Active«.• Select the IRIG-B type (choose B000 through B007).

Fault Analysis

If the device does not receive any IRIG-B time code for more than 60 s, the IRIG-B status switches from »active« to »inactive« and there is created an entry within the Event Recorder.

Check the IRIG-B functionality through the menu [Operation/ Status display/ TimeSync/ IRIG-B]. Should the IRIG-B status not be reported as being »active«, please proceed as follows:

• To begin with check the IRIG-B wiring.• Check, if the correct IRIG-B00X type is configured.

IRIG-B Control Commands

In addition to the date and time information, the IRIG-B code offers the option to transmit up to 18 control commands that can be processed by the protective device. They have to be set and issued by the IRIG-B code generator.

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Protective Relay

GPS Satellite Signal (optional)

GPS Connection (optional )

+

Twisted Pair Cable

To Other Devices

-

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The protective device offers up to 18 IRIG-B assignment options for those control commands in order to carry out the assigned action. If there is a control command assigned to an action, this action is being triggered as soon as the control command is transmitted as being true. As an example there can be triggered the start of statistics or the street lighting can be switched on through a relay.

Device Planning Parameters of the IRIG-B00X




Direct Commands of the IRIG-B00X


Res IRIG-B Cr Resetting of the Diagnosis Counters: IRIG-B Inactive, Active


Global Protection Parameters of the IRIG-B00X



Inactive, Active

Inactive [Device Para/Time/TimeSync/IRIG-B]

IRIG-B00X Determination of the Type: IRIG-B00X. IRIG-B types differ in types of included “Coded Expressions” (year, control-functions, straight-binary-seconds).

IRIGB-000, IRIGB-001, IRIGB-002, IRIGB-003, IRIGB-004, IRIGB-005, IRIGB-006, IRIGB-007

IRIGB-000 [Device Para/Time/TimeSync/IRIG-B]

Signals of the IRIG-B00X (Output States)

Name Description

Active Signal: ActiveInverted Signal: IRIG-B invertedControl Signal1 Signal: IRIG-B Control SignalControl Signal2 Signal: IRIG-B Control SignalControl Signal4 Signal: IRIG-B Control SignalControl Signal5 Signal: IRIG-B Control SignalControl Signal6 Signal: IRIG-B Control SignalControl Signal7 Signal: IRIG-B Control SignalControl Signal8 Signal: IRIG-B Control SignalControl Signal9 Signal: IRIG-B Control Signal

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Name Description

Control Signal10 Signal: IRIG-B Control SignalControl Signal11 Signal: IRIG-B Control SignalControl Signal12 Signal: IRIG-B Control SignalControl Signal13 Signal: IRIG-B Control SignalControl Signal14 Signal: IRIG-B Control SignalControl Signal15 Signal: IRIG-B Control SignalControl Signal16 Signal: IRIG-B Control SignalControl Signal17 Signal: IRIG-B Control SignalControl Signal18 Signal: IRIG-B Control Signal

IRIG-B00X Values


NoOfFramesOK Total number valid Frames. 0 0 - 65535 [Operation/Count and RevData/TimeSync/IRIG-B]

NoOfFrameErrors Total Number of Frame Errors. Physically corrupted Frame.

0 0 - 65535 [Operation/Count and RevData/TimeSync/IRIG-B]

Edges Edges 0 0 - 65535 [Operation/Count and RevData/TimeSync/IRIG-B]

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ParametersParameter setting and planning can be done:

• Directly at the device; or

• By way of the PowerPort-E software application.

Parameter Definitions

Device Parameters

Device Parameters are part of the Device Parameter tree. By modifying the Device Parameters, the User may (depending on the type of device):

• Set cutoff levels;• Configure digital inputs, Assign LEDs;• Configure Relay Output Contacts;• Assign acknowledgment signals;• Configure statistics;• Configure general Protocol Settings;• Adapt HMI settings;• Configure recorders (reports);• Set date and time;• Change passwords; and/or• Check the version (build) of the device.

System Parameters

System Parameters are part of the Device Parameter tree. System Parameters comprise the essential, basic settings of your switchboard such as rated frequency and transformer ratios.

Protection Parameters

Protection Parameters are part of the Device Parameter tree. This Protection Parameters include the following.

• Global Protection Parameters are part of the Protection Parameters: All settings and assignments that are done within the Global Parameter tree are valid independent of the Setting Groups. They have to be set only once. In addition, Global Protection Parameters include the parameters used for Breaker Management.

• The Parameter Setting Switch is part of the Protection Parameters: The User may either directly switch to a certain parameter setting group or determine the conditions for switching to another parameter setting group.

• Setting Group Parameters are part of the Protection Parameters: By means of the Setting Group Parameters, the User may individually adapt the protective device to the current conditions or grid conditions. The Setting Group Parameters may be individually set in each Settings group.

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Device Planning Parameters

Device Planning Parameters are part of the Device Parameter tree.

• Improving the Usability (Clarity): All protection modules that are currently unused can be hidden (switched to invisible) through Device Planning. In the Device Planning menu, the User can adapt the scope of functionality of the protective device exactly as needed. The User can improve the usability by hiding all modules that are not currently needed.

• Adapting the device to the application: For those modules that are needed, determine how they should be set up (e.g.: directional, non-directional, <, >...).

Direct Commands

Direct Commands are part of the Device Parameter tree but NOT part of the parameter file. They will be executed directly (e.g.: Resetting of a Counter).

State of the Module Inputs

Module Inputs are part of the Device Parameter tree. The State of the Module Input is context-dependent.

By means of the Module Inputs, information can be passed to and acted upon by the modules. The User can assign signals to Module Inputs. The state of the signals that are assigned to an input can be viewed from the Status Display. Module Inputs can be identified by an ”-I” at the end of the name.

Signals

Signals are part of the Device Parameter tree. The state of the signal is context-dependent.

• Signals represent the state of the installation/equipment (e.g.: position indicators of the breaker).

• Signals are assessments of the state of the grid and the equipment (System OK, Transformer failure detected, ...).

• Signals represent decisions that are taken by the device (e.g.: Trip Command) based on the User parameter settings.

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Adaptive Parameter Sets

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PSet-SwitchAdap

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Adaptive Parameter Sets are part of the Device Parameter tree.

By means of Adaptive Parameter Sets, the User can temporarily modify single parameters within the Parameter Setting groups.

Adaptive Parameters drop-out automatically if the acknowledged signal that has activated them has dropped-out. Please take into account that Adaptive Set 1 is dominant to Adaptive Set 2. Adaptive Set 2 is dominant to Adaptive Set 3. Adaptive Set 3 is dominant to Adaptive Set 4.

In order to increase the usability (clarity), Adaptive Parameter Sets become visible if a corresponding activation signal has been assigned (PowerPort-E V. 1.2 and higher).

Example: In order to use Adaptive Parameters within Protective Element I [1], please proceed as follows.

• Assign within the Global Parameter tree, within Protective Element I[1], an activation signal for Adaptive Parameter Set 1.

• Adaptive Parameter Set 1 becomes now visible within the Protection Parameter Sets for element I[1].

By means of additional activation signals, further Adaptive Parameter Sets can be used.

The functionality of the IED (relay) can be enhanced / adapted, by means of Adaptive Parameters in order to meet the requirements of modified states of the grid or the power supply system respectively, to manage unpredictable events.

Moreover, the adaptive parameter can also be used to realize various special protective functions or to expand the existing function modules in a simple way, without costly redesign the existing hardware or software platform.

The Adaptive Parameter feature allows, besides a standard parameter set, one of the four parameter sets labeled from 1 to 4, to be used, for example, in a time overcurrent element under the control of the configurable Set Control Logic. The dynamic switch-over of the adaptive parameter set is only active for a particular element when its adaptive set control logic is configured and only as long as the activation signal is true.

For some protection elements, such as time overcurrent and instantaneous overcurrent (50P, 51P, 50G, 51G, …), besides the “default” setting there exists another four “alternative” settings for pickup value, curve type, time dial, and reset mode set values that can dynamically be switched-over by means of the configurable adaptive setting control logic in the single set parameter.

If the Adaptive Parameter feature is not used, the adaptive set control logic will not be selected (assigned). The protective elements work, in this case, just like a normal protection using the “Default” settings. If one of the Adaptive Set Control logic is assigned to a logic function, the protective element will be “switched-over” to the corresponding adaptive settings if the assigned logic function is asserted and will drop-out to the “Default” setting if the assigned signal that has activated the Adaptive Set has dropped-out.

Adaptive Parameters Via HMI

The use of Adaptive Parameters via the HMI (panel) differs a bit to the use via PowerPort-E.

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Adaptive Parameters can be also used via the HMI (instead of using the recommended PowerPort-E). The principle method of using them via the HMI is as follows.

1. Assign an activation signal for an Adaptive Parameter Set within the Global Parameters »Global Para« for a protective element (available for current functions only).

2. Call up this protective element within a Setting Group.

3. Go to the parameter that should be modified adaptively and call it up for editing (arrow-right-key).

4. Choose the corresponding Adaptive Set.

5. Set the modified parameter for the selected Adaptive Set.

Application Example

The tripping time »t« for the 50[1] element of »Parameter Set 1« should be desensitized (reduced) in case Digital Input 2 becomes active.

1. Call up the menu [Protection Para/Global Protection Para/I-Prot/50[1]/AdaptSet1] and assign Digital Input 2 as activation signal.

2. Call up the 50[1] element within the menu [Protection Para/Set[1]/I-Port/50[1].

3. Go to the tripping time parameter »t« by means of the softkey (arrow-down) and call up the submenu by means of the softkey (arrow-right).

4. Call up the corresponding parameter set (Adaptive Set 1 in this example).

5. Set the reduced tripping time for »AdaptSet 1«.

Check and confirm that the functionality is in compliance with your protection plan via a commissioning test.

Application Example

During a “Switch-OnTo-Fault” condition, the User is usually requested to make the embedded protective function tripping of the faulted line faster, instantaneous, or sometimes non-directional.

Such a “Switch-OnTo-Fault” application can easily be realized using the Adaptive Parameter features mentioned previously. The standard time overcurrent protection element (e.g.: 51P) should trip instantaneously in case of SOTF condition,. If the SOTF logic function »SOTF ENABLED« is detecting a manual breaker close condition, the relay switches to Adaptive Set 1 if the signal »SOTF.ENABLED« is assigned to Adaptive Set 1. The corresponding Adaptive Set 1 will become active and than »t = 0« sec.

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The screen shot above shows the adaptive setting configurations following applications based on only one simple overcurrent protection element:

1. Standard Set: Default settings;2. Adaptive Set 1: SOTF application (Switch-OnTo-Fault);3. Adaptive Set 2: CLPU application (Cold Load Pickup);

Application Examples

• The output signal of the Switch OnTo Fault module can be used to activate an Adaptive Parameter Set that sensitizes the overcurrent protection.

• The output signal of the Cold Load Pickup module can be used to activate an Adaptive Parameter Set that desensitizes the overcurrent protection.

• By means of Adaptive Parameter Sets, an Adaptive Auto Reclosure can be realized. After a reclosure attempt, the tripping thresholds or tripping curves of the overcurrent protection can be adapted.

• Depending on undervoltage, the overcurrent protection can be modified (voltage controlled). This applies to devices that offer voltage protection only.

• The ground overcurrent protection can be modified by the residual voltage. This applies to devices that offer voltage protection only.

• Dynamic and automatic adaption of the ground current settings in order to adapt the settings to different loads (single-phase load diversity).

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Adaptive Parameter Sets are only available for devices with current protection modules.

Adaptive Parameter Set Activation Signals

Name Description

-.- No assignmentIH2[1].Blo Phase A Signal: Blocked Phase AIH2[1].Blo Phase B Signal: Blocked Phase BIH2[1].Blo Phase C Signal: Blocked Phase CIH2[1].Blo IG meas Signal: Blocking of the ground protection module (measured

ground current)IH2[1].Blo IG calc Signal: Blocking of the ground protection module (calculated

ground current)IH2[2].Blo Phase A Signal: Blocked Phase AIH2[2].Blo Phase B Signal: Blocked Phase BIH2[2].Blo Phase C Signal: Blocked Phase CIH2[2].Blo IG meas Signal: Blocking of the ground protection module (measured


ground current)27M[1].Pickup Signal: Pickup Voltage Element27M[2].Pickup Signal: Pickup Voltage Element59M[1].Pickup Signal: Pickup Voltage Element59M[2].Pickup Signal: Pickup Voltage Element47[1].Pickup Signal: Pickup Voltage Asymmetry47[2].Pickup Signal: Pickup Voltage AsymmetrySOTF.enabled Signal: Switch Onto Fault enabled. This Signal can be used to

modify Overcurrent Protection Settings.CLPU.enabled Signal: Cold Load enabledSudden Press.Alarm Signal: AlarmExt Oil Temp.Alarm Signal: AlarmExt Temp Superv[1].Alarm Signal: AlarmExt Temp Superv[2].Alarm Signal: AlarmExt Temp Superv[3].Alarm Signal: AlarmDI-8P X1.DI 1 Signal: Digital InputDI-8P X1.DI 2 Signal: Digital InputDI-8P X1.DI 3 Signal: Digital InputDI-8P X1.DI 4 Signal: Digital InputDI-8P X1.DI 5 Signal: Digital InputDI-8P X1.DI 6 Signal: Digital InputDI-8P X1.DI 7 Signal: Digital InputDI-8P X1.DI 8 Signal: Digital Input

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Name Description

Logic.LE79.Gate Out Signal: Output of the logic gateLogic.LE79.Timer Out Signal: Timer OutputLogic.LE79.Out Signal: Latched Output (Q)Logic.LE79.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE80.Gate Out Signal: Output of the logic gateLogic.LE80.Timer Out Signal: Timer OutputLogic.LE80.Out Signal: Latched Output (Q)Logic.LE80.Out inverted Signal: Negated Latched Output (Q NOT)Sys.Maint Mode Active Signal: Arc Flash Reduction Maintenance ActiveSys.Maint Mode Inactive Signal: Arc Flash Reduction Maintenance Inactive

Operational Modes (Access Authorization)

Operational Mode – »Display Only«

• The protection is activated.

• All data, measuring values, records, and counters/meters can be viewed.

Operation Mode – »Parameter Setting and Planning«

In this mode, the User is able to:

• Edit and set parameters;

• Change device planning details; and

• Configure and reset operational data (event recorder/fault recorder/power meter/switching cycles).

If the device was not active within the parameter setting mode for a longer time (can be set between 20 – 3600 seconds), the device will automatically reset to »Display Only« mode (Please refer to the Appendix Module Panel).

As long as the User is within the parameter setting mode, the device cannot acknowledge.

In order to change into the operation mode (»Parameter Setting«) please proceed as follows.

1. Mark the parameter to be changed in the device display.

2. Press the »Wrench« soft key to temporarily change into the Parameter Setting mode.

3. Enter the parameter password.

4. Change the parameter.

5. Change any additional parameters that are needed.

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As long as the User is within the parameter setting mode, a wrench icon will be shown in the upper right corner of the display.

6. For saving the altered parameter(s):

• Press the »OK« key; and• Confirm by pressing the »Yes« soft key.

7. Then the device changes into the »Display Only« mode.

Password

Password Entry at the Panel

Passwords can be entered by way of the soft keys

1 2 3 4

Example: For password (3244) press successively:

• Soft key 3;• Soft key 2;• Soft key 4; and• Soft key 4.

Password Changes

Passwords can be changed at the device in the »Device Para/Password« menu or by means of the PowerPort-E software.

A password must be a User-defined combination of the numbers 1, 2, 3, 4.

All other characters and keys WILL NOT be accepted.

The password for the operation mode »Parameter setting and planning« enables the User to transfer parameters from the PowerPort-E software into the device.

When the User wants to change a password, the existing one has to be entered first. The new password (up to 8 digits) is then to be confirmed twice. Please proceed as follows.

• In order to change the password, please enter the old password followed by pressing the »OK« key.• Next, enter the new password and press the »OK« key.• Finally, confirm your new password and press the »OK« key.

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Password Forgotten

By pressing the »C« key during cold booting a reset menu will be called up. By selecting »Reset All Passwords?« and confirming with »Yes« all passwords will be reset to the defaults »1234«.

Changing of Parameters - Example• Move to the parameter to be change by using the soft keys.

• Press the »Wrench« soft key.

• Enter the password for parameter setting.

• Edit/change the parameter.

Now the User can:

• Save the change made and have it adopted by the system; or

• Change additional parameters and save all the altered parameters and have them adopted by the system.

To Save Parameter Changes Immediately

• Press the »OK« key to save the changed parameters directly and to have them adopted by the device. Confirm the parameter changes by pressing the »Yes« soft key or dismiss by pressing »No« soft key.

To Change Additional Parameters and Save Afterwards

• Move to other parameters and change them.

A star symbol in front of the changed parameters indicates that the modifications have only temporarily been saved. They are not yet stored and adopted by the device.

In order to make things easier to follow, especially where complex parameter changes are involved, on every superior/higher-ranking menu level, the intended change of the parameter is indicated by the star symbol (star trace). This makes it possible to control or follow from the main menu level at any time where parameter changes have been made and have not been saved.

In addition to the star trace to the temporarily saved parameter changes, a general parameter changing symbol is faded in at the left corner of the display. It is possible from each point of the menu tree to see that there are parameter changes still not adopted by the device.

Press the »OK« key to initiate the final storage of all parameter changes. Confirm the parameter changes by pressing the »Yes« soft key or dismiss by pressing the »No« soft key.

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Plausibility Check

In order to prevent obvious incorrect settings, the device constantly monitors all temporarily saved parameter changes. If the device detects a conflict, it is indicated by a question mark in front of the respective parameter.

In order to make things easier to follow, especially where complex parameter changes are involved, a question mark appears above the temporarily saved parameters (on every superior/higher-ranking menu level). This makes it possible to control or follow, from the main menu level, where conflicts are intended to be saved. This can be done at any time.

In addition to the question mark trace to the temporarily saved conflict parameter changes, a general conflict symbol/question mark is faded-in at the left corner of the display, and so it is possible to see from each point of the menu tree that conflicts have been detected by the device.

A star/parameter change indication is always overwritten by the question mark/conflict symbol.

If a device detects a conflict, it rejects saving and adopting of the parameters.

Changing of Parameters When Using the PowerPort-E - ExampleExample: Changing of a protective parameter (to alter the characteristic for the overcurrent protection function I[1] in Parameter Set 1).

• If PowerPort-E is not in operation, please start the application.

• If the device data have not been loaded, select »Data To Be Received From The Device« in the »Device« menu.

• Double-click the »Protection Para Icon« in the navigation tree.

• Double-click the »Protection Para Set Icon« in the navigation tree.

• Double-click the »Set 1 Icon« in the navigation tree.

• Double-click the »protection stage I[1]« in the navigation tree.

• In the working window, a tabulated overview appears showing the parameters assigned to this protective function.

• In this table, double-click the value/parameter to be changed (in this example: »Char«).

• Another window (pop-up) is opened where the User can select the required characteristic.

• Close this window by clicking the »OK« key.

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A star symbol in front of the changed parameters indicates that the alterations have only temporarily been saved. They are not yet stored and adopted by the software/device.

In order to make things easier to follow, especially where complex parameter changes are involved, on every superior/higher menu level, the intended change of the parameter is indicated by the star symbol (star trace). This makes it possible to control or follow, from the main menu level, where parameter changes have been made and have not been saved. This can be done at any time.

Plausibility Check

In order to prevent obvious incorrect settings, the application constantly monitors all temporarily saved parameter changes. If the device detects a conflict, it is indicated by a question mark in front of the respective parameter.

In order to make things easier to follow, especially where complex parameter changes are involved, on every superior/higher menu level above of the temporarily saved parameters, a conflict is indicated by a question mark (plausibility trace). This makes it possible to control or follow, from the main menu level, where conflicts exist. This can be done at any time.

So it is possible to see from each point of the menu tree that conflicts have been detected by the application.

A star/parameter change indication is always overwritten by the question mark/conflict symbol.

If the software detects a conflict, it rejects the saving and adopting of the parameters.

• Additional parameters can be changed if required.

• In order to transfer changed parameters into the device, please select »Transfer all parameters into the device« in the »Device« menu.

• Confirm the safety inquiry »Shall The Parameters Be Overwritten?«.

• Enter the password for setting parameters in the pop-up window.

• Confirm the inquiry »Shall The Data Be Saved Locally?« with »Yes« (recommended). Select a suitable storing location on your hard disk.

• Confirm the selected storage location by clicking »Save«.

• The changed parameter data is now saved in the data file chosen. Thereafter, the changed data is transferred to the device and adopted.

Once the User has entered the parameter setting password, PowerPort-E will not ask the User again for the password for at least 10 minutes. This time interval will start again each time parameters are transmitted into the device. If, for more than 10 minutes, no parameters are transmitted into the device, PowerPort-E will again ask for the password when the User tries to transmit parameters into the device.

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Protection Parameters

Please note that by deactivating, for example protective functions, the User also changes the functionality of the device.

The manufacturer does not accept liability for any personal or material damage as a result of incorrect planning.

Contact your Eaton Customer Service representative for more information.

The protection parameters include the following protection parameter trees.

• Global Protection Parameters »Global Prot Para«: Here the User can find all protection parameters that are universally valid. That means they are valid independent of the protection parameter sets.

• Setting Group Parameters »Set1..4«: The protection parameters that the User set within a parameter set are only valid if the parameter set selected is switched to active.

Setting Groups

Setting Group Switch

Within the »Protection Para/P-Set Switch« menu, the User has the following possibilities:

• To manually set one of the four setting groups active;• To assign a signal to each setting group that sets this group to active; and• Scada switches the setting groups.

Option Setting Group Switch

Manual Selection Switch over, if another setting group is chosen manually within the menu »Protection Para/P-Set Switch«.

Via Input Function (e.g. Digital Input)

Switch over not until the request is clear. That means, if there is more or less than one request signal active, no switch over will be executed.

Example::DI3 is assigned onto Parameter set 1. DI3 is active „1“.DI4 is assigned onto Parameter set 2. DI4 is inactive „0“.

Now the device should switch from parameter set 1 to parameter set 2. Therefore at first DI3 has to become inactive “0”. Than DI4 has to be active “1”.

If DI4 becomes again inactive „0“, parameter set 2 will remain active “1” as long as there is no clear request (e.g. DI3 becomes active “1”, all the other assignments are inactive “0”).

Via Scada Switch over if there is a clear SCADA request.

Otherwise no switch over will be executed.

The description of the parameters can be found within the “System Parameters” section.

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Signals That Can Be Used for PSS

Name Description

-.- No assignmentDI-8P X1.DI 1 Signal: Digital InputDI-8P X1.DI 2 Signal: Digital InputDI-8P X1.DI 3 Signal: Digital InputDI-8P X1.DI 4 Signal: Digital InputDI-8P X1.DI 5 Signal: Digital InputDI-8P X1.DI 6 Signal: Digital InputDI-8P X1.DI 7 Signal: Digital InputDI-8P X1.DI 8 Signal: Digital InputLogic.LE1.Gate Out Signal: Output of the logic gateLogic.LE1.Timer Out Signal: Timer OutputLogic.LE1.Out Signal: Latched Output (Q)Logic.LE1.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE2.Gate Out Signal: Output of the logic gateLogic.LE2.Timer Out Signal: Timer OutputLogic.LE2.Out Signal: Latched Output (Q)Logic.LE2.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE3.Gate Out Signal: Output of the logic gateLogic.LE3.Timer Out Signal: Timer OutputLogic.LE3.Out Signal: Latched Output (Q)Logic.LE3.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE4.Gate Out Signal: Output of the logic gateLogic.LE4.Timer Out Signal: Timer OutputLogic.LE4.Out Signal: Latched Output (Q)Logic.LE4.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE5.Gate Out Signal: Output of the logic gateLogic.LE5.Timer Out Signal: Timer OutputLogic.LE5.Out Signal: Latched Output (Q)Logic.LE5.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE6.Gate Out Signal: Output of the logic gateLogic.LE6.Timer Out Signal: Timer OutputLogic.LE6.Out Signal: Latched Output (Q)Logic.LE6.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE7.Gate Out Signal: Output of the logic gateLogic.LE7.Timer Out Signal: Timer OutputLogic.LE7.Out Signal: Latched Output (Q)Logic.LE7.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE8.Gate Out Signal: Output of the logic gate

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Logic.LE76.Out Signal: Latched Output (Q)Logic.LE76.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE77.Gate Out Signal: Output of the logic gateLogic.LE77.Timer Out Signal: Timer OutputLogic.LE77.Out Signal: Latched Output (Q)Logic.LE77.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE78.Gate Out Signal: Output of the logic gateLogic.LE78.Timer Out Signal: Timer OutputLogic.LE78.Out Signal: Latched Output (Q)Logic.LE78.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE79.Gate Out Signal: Output of the logic gateLogic.LE79.Timer Out Signal: Timer OutputLogic.LE79.Out Signal: Latched Output (Q)Logic.LE79.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE80.Gate Out Signal: Output of the logic gateLogic.LE80.Timer Out Signal: Timer OutputLogic.LE80.Out Signal: Latched Output (Q)Logic.LE80.Out inverted Signal: Negated Latched Output (Q NOT)Sys.Maint Mode Active Signal: Arc Flash Reduction Maintenance ActiveSys.Maint Mode Inactive Signal: Arc Flash Reduction Maintenance Inactive

Setting Group Switch Via PowerPort-E



• Double click the »Protection Para« icon in the navigation tree.

• Double click the »P-Set Switch« within the protection parameters.

• To configure the Setting Group Switch respectively, manually choose an active set.

The description of the parameters can be found within the “System Parameters” section.

Copying Setting Groups (Parameter Sets) Via PowerPort-E

Setting groups can only be copied if there are no conflicts (no red question marks).

For applications using multiple settings groups, one can use the configuration file from the first group to create

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the second group. With the help of PowerPort-E, the User can simply copy an existing setting group to another (not yet configured) one. The User only needs to change those parameters where the two setting groups are different.

To efficiently establish a second parameter set where only few parameters are different, proceed as follows.


• Open a (off-line) parameter file of a device or load data of a connected device.

• Carefully save the relevant device parameters by selecting [File\Save as].

• Select »Copy Parameter Sets« out of the “Edit” menu.

• Then define both source and destination of the parameter sets to be copied (source = copy from; destination: copy to).

• Click on »OK« to start the copy procedure.

• The copied parameter set is now cached (not yet saved!).

• Then, modify the copied parameter set(s), if applicable.

• Assign a new file name to the revised device parameter file and save it on your hard disk (backup copy).

• To transfer the modified parameters back to the device, click on the »Device« menu item and select »Transfer All Parameters into the Device«.

Comparing Setting Groups Via PowerPort-E


• Click on menu item »Edit« and select »Compare Parameter Sets«.

• Select the two parameter sets from the two drop down menus that are to be compared with each other.

• Press the »Compare« button.

• The values that are different from the set parameters will be listed in tabular form.

Comparing Parameter Files Via PowerPort-EWith the help of PowerPort-E, the User can simply compare/differentiate the currently open parameter/device file against a file on the hard disk. The precondition is that the versions and type of devices match. To compare the parameter files, please proceed as follows.

• Click on »Compare with a Parameter File« within the »Device« menu.

• Click on the Folder icon in order to select a file on your hard disk.

• The differences will be shown in tabular form.

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Converting Parameter Files Via PowerPort-EParameter files of the same type can be up- or down-graded (converted). During this process, the new parameter file will keep all active settings from the source parameter file and, at the same time, remove all inactive settings. As many parameters as possible will be converted.

• Parameters that are newly added will be set to default.

• Parameters that are not included in the target file version will be deleted.

• In order to convert a parameter file please proceed as follows.

• If PowerPort-E is not in operation, please start the application.

• Open a parameter file or load the parameters from a device that should be converted.

• Make a backup of this file in a fail-safe place.

• Choose »Save as« from the »File« menu.

• Enter a new file name (in order to prevent overwriting the original file).

• Choose the new file type from drop down menu »File Type«.

• Confirm the security check by clicking on »Yes« only if the User is sure that the file conversion should be executed.

• In tabular form the modifications will be shown as follows.

Added parameter:

Deleted parameter:

Program ModeBy means of the Program Mode, parameter settings can be locked against any changes as long as one or all of the breaker(s) are in the »CLOSED« position. The Program Mode can be activated within the [System Para/General Settings/Program Mode Bypass] menu.

• »Both Bkr Open« - Parameter changes require all breakers to be in the »OPEN« state.

• »Either Bkr Open or Close« - Parameter changes do not require the breaker to be in the »OPEN« state.

Unlike, if the Program Mode is used for Motor Protection devices, the User has the following options:

• »Motor Stop« - Lock parameter changes, if the motor is not in the »STOP« state. This ensures, that parameter changes can only be done while the motor stands still (zero speed).

• »Either Motor Stopped or Running« - Parameter changes do not require the motor to be in the »Motor stop« state.

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Bypass of the Program Mode

The program mode can be bypassed by means of the Direct Control Parameter »Program Mode Bypass«. The protective device will fall back into the program mode either:

• Directly after a parameter change has been saved, else

• 10 minutes after the bypass has been activated.

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Device ParametersSys

Date and TimeIn the »Device parameters/Date/Time« menu, the User can set the date and time.

The User cannot set time and date manually (manual changes will be ignored), if the clock of the protective device is synchronized automatically (e.g. via IRIG-B or SNTP).

Synchronize Date and Time Via PowerPort-E



• Double click the »Device parameters« icon in the navigation tree.

• Double click the »Date/time« icon within the operational data.

• From the working window, the User can now synchronize the date and time of the device with the PC (i.e.: that means that the device accepts the date and time from the PC).

VersionWithin the»Device parameters/Version« menu, the User can obtain information on the software and hardware versions.

Version Via PowerPort-EWithin the »File/Properties« menu, the User can obtain detailed information on the currently opened file (e.g.: software and hardware version).

In order to be able to transmit a parameter file (e.g.: created off line) into the device, the following parameters must agree:

• Type Code (written on the top of the device/type label); and

• Version of the device model (can be found in the »Device Parameters\Version« menu).

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TCP/IP Settings

Warning: Mixing up IP Addresses

(In case there is more than one protective device within the TCP/IP network or establishing an unintentional wrong connection to a protective device based on a wrong entered IP address.

Transferring parameters into the wrong protective device might lead to death, personal injury, or damage of electrical equipment.

In order to prevent faulty connections, the User MUST document and maintain a list with the IP addresses of any switchboard/protective devices.

The User MUST double check the IP addresses of the connection that is to be established. That means, the User MUST first read out the IP address at the HMI of the device (within menu [Device para/TCP IP]) then compare the IP address with the list. If the addresses are identical, establish the connection. If they are not, DO NOT establish the connection.

Within »Device Para / TCP/IP« menu, the TCP/IP settings have to be set.

The first-time setting of the TCP/IP Parameters can be done at the panel (HMI) only.

Establishing a connection via TCP/IP to the device is only possible if the device is equipped with an Ethernet interface (RJ45).


Set the TCP/IP Parameters:

Call up »Device parameter/TCP/IP« at the HMI (panel) and set the following parameters:

• TCP/IP address;

• Subnetmask; and

• Gateway.

Direct Commands of the System Module


Ack LED All acknowledgeable LEDs will be acknowledged.

Inactive, Active


Ack RO All acknowledgeable Relay Output Contacts will be acknowledged.

Inactive, Active


Ack Comm Communication will be acknowledged. Inactive, Active


Ack RO LED Comm TCmd

Reset the Relay Output Contacts, LEDs, Communication, and the Trip Command.

Inactive, Active


Reboot Rebooting the device. No, Yes

No [Service/General]

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MaintMode Manually

Arc Flash Reduction Maintenance Switch Mode: Manual Activation of the Arc Flash Reduction Mode

Only available if: Maint Mode = Activation Manually

Maint Mode inactive, Activation via Comm, Activation via DI, Inactive, Active

Inactive [Service/MaintMode Manually]

Program Mode Bypass

Short-period bypass of the Program Mode. Inactive, Active

Inactive [System Para/General Settings]

CAUTION: Manually rebooting the device will release the Supervision Contact.

Global Protection Parameters of the System


PSet-Switch Switching Parameter Set PS1, PS2, PS3, PS4, PSS via Inp fct, PSS via Comm

PSS via Inp fct [Protection Para/PSet-Switch]

PS1: Activated by

This Setting Group will be the active one if: The Parameter Setting Group Switch is set to "Switch via Input" and the other three input functions are inactive at the same time. In case there is more than one input function active, no Parameter Setting Group Switch will be executed. In case all input functions are inactive, the device will keep working with the Setting Group that was activated lastly.

Only available if: PSet-Switch = PSS via Inp fct

1..n, PSS Sys.Maint Mode Inactive

[Protection Para/PSet-Switch]

PS2: Activated by



1..n, PSS Sys.Maint Mode Active


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PS3: Activated by



1..n, PSS -.- [Protection Para/PSet-Switch]

PS4: Activated by



1..n, PSS -.- [Protection Para/PSet-Switch]

Remote Reset Enables or disables the option to acknowledge from external/remote via signals (assignments) and Communication.

Inactive, Active

Active [Device Para/Ex Acknowledge]

Ack LED All acknowledgeable LEDs will be acknowledged if the state of the assigned signal becomes true.

1..n, Assignment List -.- [Device Para/Ex Acknowledge]

Ack RO All acknowledgeable Relay Output Contacts will be acknowledged if the state of the assigned signal becomes true.


Ack Comm Communication will be acknowledged if the state of the assigned signal becomes true.


Scaling Display of the measured values as primary, secondary, or per unit values

Per unit values, Primary values, Secondary values

Primary values [Operation/General Settings]

Maint Mode Activation Mode of the Arc Flash Reduction. Switching into another mode is only possible when no Activation Signal is active (pending).

Inactive, Activation Manually, Activation via Comm, Activation via DI

Inactive [Service/Maint Mode]

Maint Mode Activated by

Activation Signal for the Arc Flash Reduction Maintenance Switch

Only available if: Maint Mode Activated by = Activation via DI

-.-, DI-8P X1.DI 1, DI-8P X1.DI 2, DI-8P X1.DI 3, DI-8P X1.DI 4, DI-8P X1.DI 5, DI-8P X1.DI 6, DI-8P X1.DI 7, DI-8P X1.DI 8

DI-8P X1.DI 7 [Service/Maint Mode]

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Program Mode Program Mode Either Bkr Open or Close, Both Bkr Open

Either Bkr Open or Close

[System Para/General Settings]

System Module Input States


Ack LED-I Module Input State: LEDs Acknowledgment by Digital Input.

[Device Para/Ex Acknowledge]

Ack RO-I Module Input State: Acknowledgment of the Relay Output Contacts.


Ack Comm-I Module Input State: Acknowledge Communication via Digital Input. The replica that Communication has received from the device is to be reset.


PS1-I State of the module input, respectively of the signal, that should activate this Parameter Setting Group.








Maint Mode-I Module Input State: Arc Flash Reduction Maintenance Switch

[Service/Maint Mode]

System Module Signals

Name Description

Reboot Signal: Rebooting the device: 1=Restart initiated by power supply; 2=Restart initiated by the User; 3=Set on defaults (Super Reset); 4=Restart by the debugger; 5=Restart because of configuration change; 6=General failure; 7=Restart initiated by System Abort (host side); 8=Restart initiated by watchdog timeout (host side); 9=Restart initiated by System Abort (dsp side); 10=Restart initiated by watchdog timeout (dsp side); 11=Power supply failure (short term interruption) or power supply voltage to low; 12=illegal memory access.

Act Set Signal: Active Parameter SetPS 1 Signal: Parameter Set 1PS 2 Signal: Parameter Set 2PS 3 Signal: Parameter Set 3PS 4 Signal: Parameter Set 4PSS manual Signal: Manual switch over of a Parameter Set

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Name Description

PSS via Comm Signal: Parameter Set Switch via CommunicationPSS via Inp fct Signal: Parameter Set Switch via Input FunctionMin. 1 param changed Signal: At least one parameter has been changedProgram Mode Bypass Signal: Short-period bypass of the Program Mode.Maint Mode Active Signal: Arc Flash Reduction Maintenance ActiveMaint Mode Inactive Signal: Arc Flash Reduction Maintenance InactiveMaintMode Manually Signal: Arc Flash Reduction Maintenance Manual ModeMaint Mode Comm Signal: Arc Flash Reduction Maintenance Comm ModeMaint Mode DI Signal: Arc Flash Reduction Maintenance Digital Input ModeParam to be saved Number of parameters to be saved. 0 means that all parameter

changes are overtaken.Ack LED Signal: LEDs AcknowledgmentAck RO Signal: Acknowledgment of the Relay Output ContactsAck Counter Signal: Reset of all CountersAck Comm Signal: Acknowledge CommunicationAck TripCmd Signal: Reset Trip CommandAck LED-HMI Signal: LEDs Acknowledgment :HMIAck RO-HMI Signal: Acknowledgment of the Relay Output Contacts :HMIAck Counter-HMI Signal: Reset of all Counters :HMIAck Comm-HMI Signal: Acknowledge Communication :HMIAck TripCmd-HMI Signal: Reset Trip Command :HMIAck LED-Comm Signal: LEDs Acknowledgment :CommunicationAck RO-Comm Signal: Acknowledgment of the Relay Output Contacts

:CommunicationAck Counter-Comm Signal: Reset of all Counters :CommunicationAck Comm-Comm Signal: Acknowledge Communication :CommunicationAck TripCmd-Comm Signal: Reset Trip Command :Communication

Special Values of the System Module


Build Build [Device Para/Version]

Version Version [Device Para/Version]

Operating hours Cr Operating hours counter of the protective device

[Operation/Count and RevData/Sys]

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System ParametersSystem Para

Within the system parameters, the User can set all parameters that are relevant for the primary side and the mains operational method like frequency, primary and secondary values, and the star point treatment.

General System Parameters


Phase Sequence

Phase Sequence direction ABC, ACB

ABC [System Para/General Settings]

f Nominal frequency 50 Hz, 60 Hz

60 Hz [System Para/General Settings]

Generator Specific System Parameters


SN Maximum Apparent Power of the Transformer. This has to be entered in kVA.

1 – 800000 kVA 5250 kVA [System Para/Transformer]

TrV W1 Transformer rated voltage at side W1. Primary Side Nominal Voltage

60 – 500000 V 13200 V [System Para/Transformer]

TrV W2 Transformer rated voltage at side W2. Secondary Side Nominal Voltage

60 – 500000 V 4160 V [System Para/Transformer]

W1 Connection/Grounding

Note: The zero current will be removed in order to prevent faulty tripping of the differential protection. If a star point is connected to ground according to the winding connection, the zero current (symmetrical components) will be removed.

Y, D, Z, YN, ZN

D [System Para/Transformer]

W2 Connection/Grounding

Note: The zero current will be removed in order to prevent faulty tripping of the differential protection. If a star point is connected to ground according to the winding connection, the zero current (symmetrical components) will be removed.

y, d, z, yn, zn

yn [System Para/Transformer]

Phase Shift Angle that the secondary winding lags or leads the primary winding, depending on winding connection and system rotation. The phase shift angle is factor (1,2,3...11) multiplied with 30 degrees.

0 - 11 1 [System Para/Transformer]

Tap changer Tap changer, the tapchanger refers to the primary side (W1).

-15 - 15% 0% [System Para/Transformer]

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Voltage Depending System Parameters


VT Winding Side

Directional elements are dependant on the location of the VTs (primary or secondary winding) when voltage is used as the polarizing quantity. This parameter also determines the side, from which power elements take their measuring quantities.

W1, W2

W2 [System Para/VT]

Main VT pri Enter the primary phase to phase voltage of the VTs

60 – 500000 V 4200 V [System Para/VT]

Main VT sec Enter the secondary phase to phase voltage of the VTs

60.00 – 600.00 V 120 V [System Para/VT]

Main VT con Main VTs connection Wye, Phase-to-Phase, Open-Delta

Wye [System Para/VT]

VX Winding Side

Assignment of the voltage of the fourth measuring input to winding side

W1, W2

W2 [System Para/VT]

Aux VT pri Primary voltage of Aux VTs 60 – 500000 V 4200 V [System Para/VT]

Aux VT sec Secondary voltage of Aux VTs 35.00 – 600.00 V 120 V [System Para/VT]

Phase MTA Maximum Torque Angle: Angle between phase current and reference voltage in case of a short circuit. This angle is needed to determine the fault direction in case of short circuits.

0 - 360° 30° [System Para/Direction]

IR Dir Cntrl Options for direction detection. IR is used as operating quantity.

IR 3V0, IR IPol, IR Dual, IR Neg

IR 3V0 [System Para/Direction]

IX Dir Cntrl Options for direction detection. IX is used as operating quantity.

IX 3V0, IX Neg, IX Dual

IX 3V0 [System Para/Direction]

3V0 Source Earth overcurrent protection elements take into account this parameter for direction decisions. You have to ensure, that this parameter is set to "Measured" only if the ground current is fed to the fourth measuring input of the current measuring card.

Measured, Calculated

Measured [System Para/Direction]

Ground MTA Ground Maximum Torque Angle: Angle between chosen operating quantity and chosen reference quantity in case of a ground fault. This angle is needed to determine the ground fault direction in case of a short circuit. Depending on the selected ground direction option, different MTA values are used: IR 3V0, IX 3V0 : Ground MTA; IR Neg, IX Neg : 90° + Phase MTA; IR IPol : 0°; IR Dual : 0° (if I2 and V2 available) or Ground MTA; IX Dual : 90° + Phase MTA (if I2 and V2 available) or Ground MTA.

0 - 360° 110° [System Para/Direction]

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IM02602013E ETR-5000

Current Depending System Parameters


CT pri Nominal current of the primary side of the current transformers.

1 – 50000 A CT W1: 400 ACT W2: 1200 A

[System Para/CT W1]

CT sec Nominal current of the secondary side of the current transformers.

1 A, 5 A

5 A [System Para/CT W1]

CT dir Protection functions with directional feature can only work properly if the connection of the current transformers is free of wiring errors. If all current transformers are connected to the device with an incorrect polarity, the wiring error can be compensated by this parameter. This parameter turns the current vectors by 180 degrees.

0°, 180°

0° [System Para/CT W1]

XCT pri This parameter defines the primary nominal current of the connected ground current transformer. If the ground current is measured via the Residual connection, the primary value of the phase current transformer must be entered here.

1 – 50000 A 50 A [System Para/CT W1]

XCT sec This parameter defines the secondary nominal current of the connected ground current transformer. If the ground current is done via the Residual connection, the primary value of the phase current transformer must be entered here.

1 A, 5 A

5 A [System Para/CT W1]

XCT dir Ground fault protection with directional feature depends also on the correct wiring of the ground current transformer. An incorrect polarity/wiring can be corrected by means of the settings "0°" or "180°". The operator has the possibility of turning the current vector by "180°" (change of sign) without modification of the wiring. This means, that – in terms of figures - the determined current indicator was turned by "180°" by the device.

0°, 180°

0° [System Para/CT W1]

278 www.eaton.com

ETR-5000 IM02602013E

BlockingThe device provides a function for temporary blocking of the complete protection functionality or of single protections.

Make absolutely sure that no illogical or even life-threatening blockings are allocated.

Make sure not to carelessly deactivate protection functions that have to be available according to the protection concept.

Permanent BlockingSwitching “On” or “Off” the Complete Protection Functionality

In the »Protection« module, the complete protection of the device can be switched “On” or “Off”. Set the Function parameter to »Active« or »Inactive« in the »Prot« module .

Protection is activated only if in the »Prot« module the parameter Function is = »Active« (i.e.: with »Function« = »Inactive«, no protection function are operating). If »Function« = »Inactive«, then the device cannot protect any components.

Switching Modules “On” or “Off”

Each of the modules can be switched “On” or “Off” (permanently). This is achieved when the »Function« parameter is set to »Active« or »Inactive« in the respective module.

Activating or Deactivating the Tripping Command of a Protection Permanently

In each of the protections, the tripping command to the breaker can be permanently blocked. For this purpose, the »TripCmd Blo« parameter has to be set to »Active«.

Temporary BlockingTo Block the Complete Protection of the Device Temporarily by a Signal

In the »Prot« module, the complete protection of the device can be blocked temporarily by a signal. On the condition that a module-external blocking is permitted (»ExBlo Fc=active«). In addition to this, a related blocking signal from the »Assignment list« must have been assigned. For the time the allocated blocking signal is active, the module is blocked.

If the »Prot« module is blocked, the complete protection function does not work. As long as the blocking signal is active, the device cannot protect any components.

To Block a Complete Protection Module Temporarily by an Active Assignment

• In order to establish a temporary blockage of a protection module, the parameter »ExBlo Fc« of the module has to be set to »Active«. This gives the permission: »This module can be blocked«.

• Within the general protection parameters, a signal has to be additionally chosen from the »Assignment list«. The blocking only becomes active when the assigned signal is active.

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IM02602013E ETR-5000

To Block the Tripping Command of a Protection Element Temporarily by an Active Assignment

The tripping command of any of the protection modules can be blocked from an external signal. In this case, external does not only mean from outside the device, but also from outside the module. Not only real external signals are permitted to be used as blocking signals (for example: the state of a digital input), but the User can also choose any other signal from the »Assignment list«.

• In order to establish a temporary blockage of a protection element, the parameter »ExBlo TripCmd Fc« of the module has to be set to »Active«. This gives the permission: »The tripping command of this element can be blocked«.

• Within the general protection parameters, an additional signal has to be chosen and assigned to the »ExBlo« parameter from the »Assignment list«. If the selected signal is activated, the temporary blockage becomes effective.

280 www.eaton.com

ETR-5000 IM02602013E

To Activate or Deactivate the Tripping Command of a Protection Module

www.eaton.com 281

Inac

tive

Activ

e

Nam

e.Bl

o Tr

ipCm

d

Inac

tive

Activ

e

Nam

e.Ex

Blo

Trip

Cm

d Fc

1..n

, Ass

ignm

ent L

ist

Nam

e.Ex

Blo

Trip

Cm

d

Nam

e.Ex

Blo

Trip

Cm

d

Trip

Blo

ckin

gs

Nam

e =

All M

odul

es T

hat A

re B

lock

able

Nam

e.Ex

Blo

Trip

Cm

d-I

Nam

e.Bl

o Tr

ipC

md

3O

R

AND

IM02602013E ETR-5000

Activate, Deactivate Respectively to Block Temporary Protection Functions

Current protective functions cannot only be blocked permanently (»Function = Inactive«) or temporarily by any blocking signal from the »Assignment list«, but also by »Reverse Interlocking«.

All other protection functions can be activated, deactivated, or blocked in the same manner.

282 www.eaton.com

AND

Inac

tive

Activ

e

Nam

e.Fu

nctio

n

Inac

tive

Activ

e

Nam

e.Ex

Blo

Fc

Nam

e.Ac

tive

Prot

. Act

ive

1..n

, Ass

ignm

ent L

ist

Nam

e.Ex

Blo

1

Nam

e.Ex

Blo

Bloc

king

s (The

Gen

eral

Pro

tect

ion

mod

ule

is n

ot d

eact

ivat

ed o

r blo

cked

)

Nam

e.Ex

Blo1

-I

1..n

, Ass

ignm

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ist

Nam

e.Ex

Blo

2Na

me.

ExBl

o2-I

Nam

e =A

ll Mod

ules

Tha

t Are

Blo

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le

1

2

Plea

se R

efer

to D

iagr

am: P

rot

OR

AND

* Freq

uenc

y ra

nge

info

1.

** Fr

eque

ncy

rang

e in

fo2.

Freq

uenc

y is

with

in th

e no

min

al fr

eque

ncy

rang

e.(*

)(**

)

ETR-5000 IM02602013E

www.eaton.com 283

AND

Inac

tive

Activ

e

Nam

e.R

vs B

lo F

c

AND

Inac

tive

Activ

e

Nam

e.Fu

nctio

n

Inac

tive

Activ

e

Nam

e.Ex

Blo

Fc

Nam

e.A

ctiv

e

Prot

. Act

ive

1..n

, Ass

ignm

ent L

ist

Nam

e.Ex

Blo

1

1..n

, Ass

ignm

ent L

ist

Nam

e.R

vs B

lo

Nam

e.Ex

Blo

Nam

e.Rv

s Bl

o

Bloc

kings

**

(The

Gen

eral

Pro

tect

ion

mod

ule

is n

ot d

eact

ivate

d or

blo

cked

)

Nam

e =

I[1]..

.[n],

IG[1

]...[n

]

Nam

e.Ex

Blo1

-I

Nam

e.R

vs B

lo-I

1..n

, Ass

ignm

ent L

ist

Nam

e.Ex

Blo

2Na

me.

ExBl

o2-I

1

4

Plea

se R

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am: P

rot

OR

AND

*Fr

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ncy

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** Fr

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Freq

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e.(*

)(**

)

IM02602013E ETR-5000

Protection (Prot) ModuleProt

The »Protection« module serves as the outer frame for all other protection modules (i.e.: they are all enclosed by the »Protection« Module).

In the case where the »Protection« module is blocked, the complete protective function of the device is disabled.

Module Prot Blocked - Protection Inactive:

If the master »Protection« module is allowed to be temporarily blocked and the allocated blocking signals are active, then all protection functions will be disabled. In such a case, the protective function is »Inactive«.

Protection Active:

If the master »Protection« module was activated and a blockade for this module was not activated respectively, the assigned blocking signals are inactive at that moment, then the »Protection« is »Active«.

How to Block All Protective and Supervisory FunctionsIn order to block all protective and supervisory functions, call up the menu [Protection/Para/Global Prot Para/Prot]:

• Set the parameter »ExBlo Fc = active«;

• Choose an assignment for »ExBlo1«; and

• Optionally choose an assignment for »ExBlo2«.

If the signal becomes true, then all protective and supervisory functions will be blocked as long as one of these signals are true.

284 www.eaton.com

ETR-5000 IM02602013E

www.eaton.com 285

AND

Inac

tive

Activ

e

Prot

.ExB

lo F

c

Prot

.Act

ive

1..n

, Ass

ignm

ent L

ist

Prot

.ExB

lo 1

Prot

.ExB

lo

Pro

t -A

ctiv

e 1..n

, Ass

ignm

ent L

ist

Prot

.ExB

lo 2

Prot

.ExB

lo1-

I

Prot

.ExB

lo2-

I

AND

Prot

.Ava

ilabl

e M

easu

red

Valu

es: O

K

At th

e m

omen

t, no

par

amet

er is

bei

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hang

ed (e

xcep

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et p

aram

eter

s).

1

OR

AND

Sele

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st

Pro

t.ExB

lo 3

**Pr

ot.E

xBlo

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**=A

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third

blo

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g in

put d

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and

mod

ule

IM02602013E ETR-5000

Each protection element generates its own pickup and trip signals, which are automatically passed onto the »Prot« module where the phase based and general (collective) pickup and trip signals are generated. The »Prot« module serves as a top level and a common place to group all pickups and trips from each individual protection element.

For instance, »PROT.PICKUP PHASE A« is the phase A pickup signal OR-ed from all protection elements; »PROT.TRIP PHASE A« is the phase A trip signal OR-ed from all protection elements; »PROT.PICKUP« is the collective pickup signal OR-ed from all protection elements; Prot.Trip is the collective Trip signal OR-ed from all protection elements, and etc. The Tripping commands of the protection elements have to be fed to the »Bkr Manager« module for further trip request processing.

The tripping commands are executed by the »Bkr Manager« module. Tripping commands have to be assigned to a breaker. The Breaker Manager will issue the trip command to the breaker.

If a protection element is activated and respectively decides to trip, two pickup signals will be created.

1. The module or the protection element issues an pickup/alarm (e.g.: »50P[1].PICKUP or »50P[1].TRIP«).

2. The master »Prot« module collects/summarizes the signals and issues a pickup/alarm or a trip signal »PROT.PICKUP« »PROT.TRIP«.

286 www.eaton.com

ETR-5000 IM02602013E

www.eaton.com 287

Prot

.Trip

Nam

e.Tr

ip

Nam

e =

Each

trip

of a

n ac

tive,

trip

aut

horiz

ed p

rote

ctio

n m

odul

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ll le

ad to

a g

ener

al tr

ip.

Nam

e.Tr

ip

Pro

t.Trip Nam

e[n]

.Trip

...15 15 15

OR

IM02602013E ETR-5000

288 www.eaton.com

Prot

.Pick

up

Pro

t.Pic

kup

Nam

e.Pi

ckup

Nam

e.Pi

ckup

Nam

e.Pi

ckup

Nam

e =

Each

pic

kup

of a

mod

ule

(exc

ept f

rom

sup

ervis

ion

mod

ules

but

incl

udin

g BF

) will

lead

to a

gen

eral

pic

kup

(col

lect

ive

pick

up).

...14 1414

OR

ETR-5000 IM02602013E

www.eaton.com 289

50R[

1]...

[n].T

rip*

59[n

].Trip

Cmd*

Prot

.Trip

IX o

r IR

51R

[1]..

.[n].T

rip*

Prot

.Trip

Eac

h ph

ase

sele

ctiv

e tri

p of

a tr

ip a

utho

rized

mod

ule

(I, IG

, V, V

X d

epen

ding

on

the

devi

ce ty

pe) w

ill le

ad to

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hase

se

lect

ive

gene

ral t

rip.

19c

19d

23

OR

Prot

.Trip

Pha

se A

50P[

1]...

[n].T

rip P

hase

A*

51P[

1]...

[n].T

rip P

hase

A*

V[n

].Trip

Pha

se A

*

16a

16b

20

OR

Prot

.Trip

Pha

se B

50P[

1]...

[n].T

rip P

hase

B*

51P[

1]...

[n].T

rip P

hase

B*

V[n

].Trip

Pha

se B

*

17a

17b 21

OR

Prot

.Trip

Pha

se C

50P[

1]...

[n].T

rip P

hase

C*

51P[

1]...

[n].T

rip P

hase

C*

V[n

].Trip

Pha

se C

*

18a

18b

22

OR

50X[

1]...

[n].T

rip*

51X[

1]...

[n].T

rip*

19a

19b

*=Depending on the type of device

IM02602013E ETR-5000

290 www.eaton.com

50R[

1]...

[n].P

icku

p*

59[n

].Pic

kup*

Prot

.Pick

up IX

or I

R

51R[

1]...

[n].P

icku

p*

Pro

t.Pic

kup

Eac

h ph

ase

sele

ctiv

e pi

ckup

of a

mod

ule

(I, IG

, V, V

X d

epen

ding

on

the

devi

ce ty

pe) w

ill le

ad to

a p

hase

sel

ectiv

e ge

nera

l pic

kup

(col

lect

ive

pick

up).

27c

27d 31

OR

Prot

.Pic

kup

Phas

e B

50P[

1]...

[n].P

ickup

IB*

V[n]

.Pic

kup

Phas

e B*

25a

29

OR

51P[

1]...

[n].P

icku

p IB

*25

b

Prot

.Pick

up P

hase

C

50P[

1]...

[n].P

ickup

IC*

V[n]

.Pic

kup

Phas

e C

*

26a

30

OR

26b

51P[

1]...

[n].P

ickup

IC*

Prot

.Pic

kup

Phas

e A

51P[

1]...

[n].P

ickup

IA*

V[n]

.Pic

kup

Phas

e A*

24b

28

OR

50P[

1]...

[n].P

ickup

IA*

24a

50X[

1]...

[n].P

icku

p*

51X

[1]..

.[n].P

icku

p*

27a

27b

*=Depending on the type of device

ETR-5000 IM02602013E

Direct Commands of the Protection Module


Res Fault a Mains No

Resetting of fault number and number of grid faults.

Inactive, Active


Global Protection Parameters of the Protection Module


ExBlo Fc Activate (allow) the external blocking of the global protection functionality of the device.

Inactive, Active

Inactive [Protection Para/Global Prot Para/Prot]

ExBlo1 If external blocking of this module is activated (allowed), the global protection functionality of the device will be blocked if the state of the assigned signal becomes true.

1..n, Assignment List -.- [Protection Para/Global Prot Para/Prot]

ExBlo2 If external blocking of this module is activated (allowed), the global protection functionality of the device will be blocked if the state of the assigned signal becomes true.

1..n, Assignment List -.- [Protection Para/Global Prot Para/Prot]

Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Prot]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Prot]

Protection Module Signals (Output States)

Name Description

Available Signal: Protection is available.Active Signal: ActiveExBlo Signal: External BlockingPickup Phase A Signal: General Pickup Phase APickup Phase B Signal: General Pickup Phase BPickup Phase C Signal: General Pickup Phase CPickup IX or IR Signal: General Pickup - Ground FaultPickup Signal: General PickupTrip Phase A Signal: General Trip Phase ATrip Phase B Signal: General Trip Phase B

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IM02602013E ETR-5000

Name Description

Trip Phase C Signal: General Trip Phase CTrip IX or IR Signal: General Trip Ground FaultTrip Signal: General TripRes Fault a Mains No Signal: Resetting of fault number and number of grid faults.I dir fwd Signal: Phase current failure forward directionI dir rev Signal: Phase current failure reverse directionI dir n poss Signal: Phase fault - missing reference voltageIR dir fwd Signal: IR Ground fault (calculated) forwardIR dir rev Signal: IR Ground fault (calculated) reverse directionIR dir n poss Signal: IR Ground fault (calculated) direction detection not possibleIX dir fwd Signal: IX Ground fault (measured) forwardIX dir rev Signal: IX Ground fault (measured) reverse directionIX dir n poss Signal: IX Ground fault (measured) direction detection not possible

Protection Module Values


FaultNo Waveform No. [Operation/Count and RevData/Prot]

No of grid faults Number of grid faults: A grid fault, e.g. a short circuit, might cause several faults with trip and autoreclosing, each fault being identified by an increased fault number. In this case, the grid fault number remains the same.

[Operation/Count and RevData/Prot]

292 www.eaton.com

ETR-5000 IM02602013E

Switchgear/Breaker – ManagerBkr[1] ,Bkr[2]

WARNING Misconfiguration of switchgear could result in death or serious injury. This e. g. is the case when opening a disconnector under load or when switching a ground connector to live parts of a system.

Beside protection functions, protective relays more and more will take care about controlling switchgear, like breakers, load break switches, disconnectors and ground connectors.

A correct configuration of all switchgear is an indispensable precondition for the proper functioning of the protective device. This also is the case, when the switchgear are not controlled, but supervised only.

Single Line DiagramFor construction of a single line diagram, please address to our technical support.

The single line diagram includes the graphically description of the switchgear and their designations (names) as well as their features (short circuit proof or not ...). For displaying in the devices software, the switchgear designations (e. g. QA1, QA2, instead of SG[x]) will be taken from the single line diagram.

Beside switching properties a configuration file also includes a single line diagram. Switching properties and single line diagram are coupled via the the configuration file. Since the single line diagram is independent of the device type, a new/other single line diagram can be imported into the configuration file.

Whenever a configuration file is loaded into a protection device, a single line diagram will be always loaded at the same time.

This means, whenever a configuration file is transfered from one to another device, a suitable single line digram has to be loaded by means of the Device Planning menu.

Import of a Single Line DiagramTo import a single line diagram into a device, proceed as follows:

• Load the configuration file of the device via Smart view.• Change into the Device Planning menu• Assign the right single line diagram to the configuration file.• Save the configuration file to a volume. The single line diagram now is saved together

with the *.ErPara file.

Transfer of the Single Line Diagram into the DeviceIf in the Smart view menu »Device« »Transfer All Parameters into the Device« has been selected, beside all parameters also the single line diagram and the switchgear properties will be transferred into the device.

Export of a Single Line DiagramTo export a single line diagram, go into the Device Planning menu [Device Planning/Control]. Click onto »Control.Name«. Afterwards click onto the field ”Export current File to Disk“.

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IM02602013E ETR-5000

After the single line diagram has been loaded, each individual switchgear has to be configured. The following table shows the required configurations dependent on the type of switchgear.

To be Configured at: Type of Switchgear

[Control\SG\Designation of Switchgear]

Brea

ker

(con

trolle

d)

Brea

ker

(sup

ervi

sed)

Sw

itch

Dis

conn

ecto

r(c

ontro

lled)

Switc

h D

isco

nnec

tor

(sup

ervi

sed)

Gro

und

Con

nect

or(c

ontro

lled)

Gro

und

Con

nect

or(s

uper

vise

d)

Dis

conn

ecto

r(c

ontro

lled)

Dis

conn

ecto

r(s

uper

vise

d)

Assignment of position indications(Digital inputs)

x x x x x x x x

Assignment of commands(Relay output contacts) x - x - x - x -

Setting of supervision timers x x x x x x x xInterlockings x - x - x - x -Trip Manager(Assignment of trip commands) x x - - - - - -

Optional: Synchronous switching x - - - - - - -

Optional: Ex OPEN/CLOSE Cmd x - x - x - x -

Optional: SGW x x x x x x x x

Switchgear Configuration

Wiring

At first the switchgear positioning indicators have to be connected to the digital inputs of the protection device.One of the position indicators (either the »Aux CLOSE« or the »Aux OPEN«) contact has to be connected necessarily. It is recommended also to connect the »Aux OPEN« contact.

Thereafter the command outputs (relay output contacts) have to be connected with the switchgear.

Please observe the following option: In the general settings of a breaker, the CLOSE/OPEN commands of a protection element can be issued to the same relay output contacts, where the other control commands are issued.

If the commands are issued to different relays relay output contacts the amount of wiring increases.

Assignment of Position Indications

The position indication is needed by the device to get (evaluate) the information about the current status /position of the breaker. The switchgear position indications are shown in the devices display. Each position change of a switchgear results in a change of the corresponding switchgear symbol.

294 www.eaton.com

ETR-5000 IM02602013E

For the detection of a switchgear's position always two separate Aux contacts are recommended! If only one Aux contact is used, no intermediate or disturbed positions can be detected.

A (reduced) transition supervision (time between issue of the command and position feedback indication of the switchgear) is also possible by one Aux contact.

In the menu [Control/SG/SG [x] ] the assignments for the position indications have to be set.

Detection of switchgear position with two Aux contacts – Aux CLOSE and Aux OPEN (recommended!)

For detection of their positions switchgear are provided with Aux contacts (Aux CLOSE and Aux OPEN). It is recommended to use both contacts to detect intermediate and disturbed positions too.

The protection device continuously supervises the status of the inputs »Aux CLOSE-I« and »Aux OPEN-I«. These signals are validated based on the supervision timers »t-Move CLOSE« and »t-Move OPEN« validation functions. As a result, the switchgear position will be detected by the following signals:

• Pos CLOSE • Pos OPEN• Pos Indeterm• Pos Disturb.• Pos (State=0,1,.2 or 3)

Supervision of the CLOSE command

When an CLOSE command is initiated, the »t-Move CLOSE« timer will be started. While the timer is running, the »POS INDETERM« State will become true. If the command is executed and properly fed back from the switchgear before the timer has run down, »POS CLOSE« will become true. Otherwise, if the timer has expired »POS DISTURB« will become true.

Supervision of the OPEN command

When an OPEN command is initiated, the »t-Move OPEN« timer will be started. While the timer is running, the »POS INDETERM« State will become true. If the command is executed and properly fed back before the timer has run down, »POS OPEN« will become true. Otherwise, if the timer has expired »POS DISTURB« will become true.

The following table shows how switchgear positions are validated:

States of the Digital Inputs Validated Breaker PositionsAux CLOSE-I Aux OPEN-I POS CLOSE POS OPEN POS Indeterm POS Disturb POS

State

0 0 0 0 1(while a Moving timer

is running)

0(while a Moving timer is running)

0Intermediate

1 1 0 0 1(while a Moving timer

is running)

0(while a Moving timer is running)

0Intermediate

0 1 0 1 0 0 1OPEN

1 0 1 0 0 0 2CLOSE

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IM02602013E ETR-5000

States of the Digital Inputs Validated Breaker Positions

0 0 0 0 0(Moving timer

elapsed)

1(Moving timer

elapsed)

3Disturbed

1 1 0 0 0(Moving timer

elapsed)

1(Moving timer

elapsed)

3Disturbed

Single Position Indication Aux CLOSE or Aux OPEN

If the single pole indication is used, the »SI SINGLECONTACTIND« will become true.

The moving time supervision works only in one direction. If the Aux OPEN signal is connected to the device, only the “OPEN command” can be supervised and if the Aux CLOSE signal is connected to the device, only the “CLOSE command” can be supervised.

Single Position Indication – Aux CLOSE

If only the Aux CLOSE signal is used for the Status Indication of an “CLOSE command”, the switch command will also start the moving time, the position indication indicates an INTERMEDIATE position during this time interval. When the switchgear reaches the end position indicated by the signals Pos CLOSE and CES succesf before the moving time has elapsed the signal Pos Indeterm disappears.

If the moving time elapsed before the switchgear has reached the end position, the switching operation was not successful and the Position Indication will change to POS Disturb and the signal Pos Indeterm disappears. After the moving time has elapsed, the Dwell time will be started (if set). During this time interval the Position Indication will also indicate an INTERMEDIATE state. When the Dwell time elapses the Position Indication will change to Pos CLOSE.

The following table shows how breaker positions are validated based on Aux CLOSE:

States of the Digital Input Validated Breaker PositionsAux CLOSE-I Aux OPEN-I POS CLOSE POS OPEN POS Indeterm POS Disturb POS

State

0 Not wired 0 0 1(while t-Move CLOSE

is running)

0(while t-Move CLOSE

is running)

0Intermediate

0 Not wired 0 1 0 0 1OPEN

1 Not wired 1 0 0 0 2CLOSE

If there is no digital input assigned to the »Aux CLOSE« contact, the position indication will have the value 3 (disturbed).

Single Position Indication – Aux OPEN

If only the Aux OPEN signal is used for the monitoring of the “OPEN command”, the switch command will start the moving timer. The Position Indication will indicate an INTERMEDIATE position. When the switchgear reaches its end position before the moving timer elapses, »CES succesf« will be indicated. At the same time the signal »Pos Indeterm« disappears.

If the moving time elapsed before the switchgear has reached the OPEN position, the switching operation was not successful and the Position Indication will change to »Pos Disturb« and the signal »Pos Indeterm« disappears.

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When the moving timer has elapsed, the dwell timer will be started (if configured). During this timer elapses »Pos Disturb« will be indicated. When the dwell time has elapsed, the OPEN position of the switchgear will be indicated by the »Pos OPEN« signal.

The following table shows how breaker positions are validated based on Aux OPEN:

States of the Digital Input Validated Breaker PositionsAux CLOSE-I Aux OPEN-I POS CLOSE POS OPEN POS Indeterm POS Disturb POS

StateNot wired 0 0 0 1

(while t-Move OPEN is running)

0(while t-Move OPEN

is running)

0Intermediate

Not wired 0 0 1 0 0 1OPEN

Not wired 1 1 0 0 0 2CLOSE

If there is no digital input assigned to the »Aux OPEN« contact, the position indication will have the value 3 (disturbed).

Setting of Supervision Times

In the menu [Control/SG/SG[x]/General Settings] the supervision times of the individual switchgear have to be set. Dependent on the type of switchgear it can be necessary to set further parameters, like dwell time.

Interlockings

To avoid faulty operations, interlockings have to be provided. This can be realized mechanically or electrically.

For a controllable switchgear up to three interlockings can be assigned in both switching directions (CLOSE/OPEN). These interlockings prevent switching in the corresponding direction.

The protection OPEN command and the reclosing command of the AR module are always executed without interlockings. For the case, that a protection OPEN command must not be issued, this must be blocked separately.

Further interlockings can be realized by means of the Logic module.

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ETR-5000 IM02602013E

Trip Manager – Assignment of Commands

The trip commands of the protection elements have to be assigned to those switchgear, that are make/break capable (Breaker). For every make/break capable switchgear a Trip Manager is provided.

In the Trip Manger all tripping commands are combined by an “OR” logic. The actual tripping command to the switchgear is exclusively given by the Trip Manager. This means, that only tripping commands which are assigned in the Trip Manager lead to an operation of the switchgear. In addition to that, the User can set the minimum hold time of the tripping command within this module and define whether the tripping command is latched or not.

Tripable Elements:

Name Description

-.- No assignment87.TripCmd Signal: Trip Command87H.TripCmd Signal: Trip Command87GD[1].TripCmd Signal: Trip Command87GDH[1].TripCmd Signal: Trip Command87GD[2].TripCmd Signal: Trip Command87GDH[2].TripCmd Signal: Trip Command50P[1].TripCmd Signal: Trip Command50P[2].TripCmd Signal: Trip Command50P[3].TripCmd Signal: Trip Command50P[4].TripCmd Signal: Trip Command51P[1].TripCmd Signal: Trip Command51P[2].TripCmd Signal: Trip Command51P[3].TripCmd Signal: Trip Command51P[4].TripCmd Signal: Trip Command50X[1].TripCmd Signal: Trip Command50X[2].TripCmd Signal: Trip Command51X[1].TripCmd Signal: Trip Command51X[2].TripCmd Signal: Trip Command50R[1].TripCmd Signal: Trip Command50R[2].TripCmd Signal: Trip Command51R[1].TripCmd Signal: Trip Command51R[2].TripCmd Signal: Trip Command49.TripCmd Signal: Trip Command51Q[1].TripCmd Signal: Trip Command51Q[2].TripCmd Signal: Trip Command27M[1].TripCmd Signal: Trip Command27M[2].TripCmd Signal: Trip Command59M[1].TripCmd Signal: Trip Command59M[2].TripCmd Signal: Trip Command

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Name Description

27A[1].TripCmd Signal: Trip Command27A[2].TripCmd Signal: Trip Command59A[1].TripCmd Signal: Trip Command59A[2].TripCmd Signal: Trip Command46[1].TripCmd Signal: Trip Command46[2].TripCmd Signal: Trip Command47[1].TripCmd Signal: Trip Command47[2].TripCmd Signal: Trip Command81[1].TripCmd Signal: Trip Command81[2].TripCmd Signal: Trip Command81[3].TripCmd Signal: Trip Command81[4].TripCmd Signal: Trip Command81[5].TripCmd Signal: Trip Command81[6].TripCmd Signal: Trip Command32[1].TripCmd Signal: Trip Command32[2].TripCmd Signal: Trip Command32[3].TripCmd Signal: Trip Command32V[1].TripCmd Signal: Trip Command32V[2].TripCmd Signal: Trip Command32V[3].TripCmd Signal: Trip CommandZI[1].TripCmd Signal: Zone Interlocking Trip CommandZI[2].TripCmd Signal: Zone Interlocking Trip Command24[1].TripCmd Signal: Trip Command24[2].TripCmd Signal: Trip CommandExP[1].TripCmd Signal: Trip CommandExP[2].TripCmd Signal: Trip CommandExP[3].TripCmd Signal: Trip CommandExP[4].TripCmd Signal: Trip CommandSudden Press.TripCmd Signal: Trip CommandExt Oil Temp.TripCmd Signal: Trip CommandExt Temp Superv[1].TripCmd Signal: Trip CommandExt Temp Superv[2].TripCmd Signal: Trip CommandExt Temp Superv[3].TripCmd Signal: Trip CommandRTD.TripCmd Signal: Trip CommandPres[1].TripCmd Signal: Trip CommandTmp1[1].TripCmd Signal: Trip CommandTmp2[1].TripCmd Signal: Trip CommandVibr[1].TripCmd Signal: Trip CommandVBat[1].TripCmd Signal: Trip Command

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Name Description

TapV[1].TripCmd Signal: Trip CommandAnaP[1].TripCmd Signal: Trip Command

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Signal Breaker CLOSE

Signal Breaker OPEN

Signal Breaker Ready

Trigger [x]

Trigger [x]

Trigger [x]

Brea

ker

Breaker OPEN Command

Breaker CLOSE Command

Protection Trip Command

Position Indication:OPEN, CLOSE,

Indeterminated, Disturbed

Trip Command 50P[x]

Trip Command 51P[x]

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Autoreclosure CLOSE

SCADA

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ETR-5000 IM02602013E

Ex CLOSE/OPEN

If the switchgear should be opened or closed by an external signal, the User can assign one signal that will trigger the CLOSE and one signal that will trigger the OPEN command (e.g. digital inputs or output signals of the logic). An OPEN command has priority. CLOSE commands are slope oriented, OPEN commands are level oriented.

Synchronised Switching*

*=availability depends on ordered device type

Before a switchgear may connect two mains sections, synchronism of these sections must be assured. In the menu [Synchronous Switching] the parameter »Synchronism« defines which signal indicates synchronism.

If the synchronism condition shall be evaluated by the internal Synch-Check module the signal »Sync. Ready to Close« (release by synch-check module) has to be assigned. Alternatively a digital input or a logic output can be assigned.

In the synchronisation mode “Generator-to-System” additionally the synchronism request has to be assigned in the menu [Protection Para\Global Prot Para\Sync].

If a synchronism signal is assigned, the switching command will only be executed, when the synchronism signal will become true within the maximum supervision time »t-MaxSyncSuperv«. This supervision time will be started with the issued CLOSE command. If no synchronism signal has been assigned, the synchronism release is permanently.

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Signal Breaker CLOSE

Signal Breaker OPEN

Signal Breaker Ready

Trigger [x]

Trigger [x]

Synchronism

Brea

ker

Breaker OPEN Command

Breaker CLOSE Command

Trip Command

CLOSE Request

Position Indication:OPEN, CLOSE,

Indeterminated, Disturbed

HMI

Autoreclosure CLOSE

SCADA

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Sync

Chec

k

Breaker CLOSE Initiative

ETR-5000 IM02602013E

Switching Authority

For the Switching Authority [Control\General Settings], the following general settings are possible:

NONE: No control function;LOCAL: Control only via push buttons at the panel;REMOTE: Control only via SCADA, digital inputs, or internal signals; andLOCAL&REMOTE: Control via push buttons, SCADA, digital inputs, or internal signals.

The following Signals can trigger the Sync-check.

Name Description

-.- No assignmentDI-8P X1.DI 1 Signal: Digital InputDI-8P X1.DI 2 Signal: Digital InputDI-8P X1.DI 3 Signal: Digital InputDI-8P X1.DI 4 Signal: Digital InputDI-8P X1.DI 5 Signal: Digital InputDI-8P X1.DI 6 Signal: Digital InputDI-8P X1.DI 7 Signal: Digital InputDI-8P X1.DI 8 Signal: Digital InputLogic.LE1.Gate Out Signal: Output of the logic gateLogic.LE1.Timer Out Signal: Timer OutputLogic.LE1.Out Signal: Latched Output (Q)Logic.LE1.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE2.Gate Out Signal: Output of the logic gateLogic.LE2.Timer Out Signal: Timer OutputLogic.LE2.Out Signal: Latched Output (Q)Logic.LE2.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE3.Gate Out Signal: Output of the logic gateLogic.LE3.Timer Out Signal: Timer OutputLogic.LE3.Out Signal: Latched Output (Q)Logic.LE3.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE4.Gate Out Signal: Output of the logic gateLogic.LE4.Timer Out Signal: Timer OutputLogic.LE4.Out Signal: Latched Output (Q)Logic.LE4.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE5.Gate Out Signal: Output of the logic gateLogic.LE5.Timer Out Signal: Timer OutputLogic.LE5.Out Signal: Latched Output (Q)Logic.LE5.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE6.Gate Out Signal: Output of the logic gateLogic.LE6.Timer Out Signal: Timer Output

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Name Description

Logic.LE74.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE75.Gate Out Signal: Output of the logic gateLogic.LE75.Timer Out Signal: Timer OutputLogic.LE75.Out Signal: Latched Output (Q)Logic.LE75.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE76.Gate Out Signal: Output of the logic gateLogic.LE76.Timer Out Signal: Timer OutputLogic.LE76.Out Signal: Latched Output (Q)Logic.LE76.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE77.Gate Out Signal: Output of the logic gateLogic.LE77.Timer Out Signal: Timer OutputLogic.LE77.Out Signal: Latched Output (Q)Logic.LE77.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE78.Gate Out Signal: Output of the logic gateLogic.LE78.Timer Out Signal: Timer OutputLogic.LE78.Out Signal: Latched Output (Q)Logic.LE78.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE79.Gate Out Signal: Output of the logic gateLogic.LE79.Timer Out Signal: Timer OutputLogic.LE79.Out Signal: Latched Output (Q)Logic.LE79.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE80.Gate Out Signal: Output of the logic gateLogic.LE80.Timer Out Signal: Timer OutputLogic.LE80.Out Signal: Latched Output (Q)Logic.LE80.Out inverted Signal: Negated Latched Output (Q NOT)

Non-interlocked Switching

For test purposes, during commissioning and temporarily operations, interlockings can be disabled.

WARNING: Non-interlocked Switching can lead to serious injuries or death!

For non-interlocked switching the menü [Control\General Settings] provides the following options:

• Non-interlocked switching for one single command;• Permanent;• Non-interlocked switching for a certain time; and• Non-interlocked switching, activated by an assigned signal.

The set time for non-interlocked switching applies also for the “Single Operation“ mode.

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Manual Manipulation of the Switchgear Position

In case of faulty position indication contacts (Aux contacts) or broken wires, the position indication resulted from the assigned signals can be manipulated (overwritten) manually, to keep the ability to switch the affected switchgear. A manipulated switchgear position will be indicated on the display by an exclamation mark “!” beside the switchgear symbol.

WARNING: Manipulation of the Switchgear Position can lead to serious injuries or death!

Double Operation Locking

All control commands to any switchgear in a bay have to be processed sequentially. During a running control command no other command will be handled.

Switch Direction Control

Switching commands are validated before execution. When the switchgear is already in the desired position, the switch command will not be issued again. An opened breaker cannot be opened again. This also applies for switching command at the HMI or via SCADA.

Anti-PumpingBy pressing the CLOSE command softkey only a single switching CLOSE impulse will be issued independent, how low the softkey is actuated. The switchgear will close only once per close command.

Direct Commands of the Control


Res Bwear Sl Breaker

Resetting the slow breaker alarm Inactive, Active


Ack TripCmd Acknowledge Trip Command Inactive, Active


Global Protection Parameters of the Control


CinBkr-52a The breaker is in CLOSE-position if the state of the assigned signal is true (52a).


Bkr[1]: DI-8P X1.DI 5Bkr[2]: DI-8P X1.DI 6

[Control/Bkr/Bkr[1]/Pos Indicatrs Wirng]

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CinBkr-52b The breaker is in OPEN-position if the state of the assigned signal is true (52b).


-.- [Control/Bkr/Bkr[1]/Pos Indicatrs Wirng]

Ready Breaker is ready for operation if the state of the assigned signal is true. This digital input can be used by some protective elements (if they are available within the device) like Auto Reclosure (AR), e.g. as a trigger signal.


-.- [Control/Bkr/Bkr[1]/Pos Indicatrs Wirng]

Interl CLOSE1 Interlocking of the CLOSE command 1..n, Assignment List Wired Inputs.Bkr Trouble-I

[Control/Bkr/Bkr[1]/Interlockings]

Interl CLOSE2 Interlocking of the CLOSE command 1..n, Assignment List -.- [Control/Bkr/Bkr[1]/Interlockings]

Interl CLOSE3 Interlocking of the CLOSE command 1..n, Assignment List -.- [Control/Bkr/Bkr[1]/Interlockings]

Interl OPEN1 Interlocking of the OPEN command 1..n, Assignment List -.- [Control/Bkr/Bkr[1]/Interlockings]



SC CLOSE Switching CLOSE Command, e.g. the state of the logic or the state of the digital input

1..n, DI-LogicList -.- [Control/Bkr/Bkr[1]/Ex OPEN/CLOSE Cmd]

SC OPEN Switching OPEN Command, e.g. the state of the logic or the state of the digital input

1..n, DI-LogicList -.- [Control/Bkr/Bkr[1]/Ex OPEN/CLOSE Cmd]

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t-TripCmd Minimum hold time of the OPEN-command (Breaker, load break switch)

0 – 300.00 s 0.2 s [Control/Bkr/Bkr[1]/Trip Manager]

Latched Defines whether the Relay Output will be Latched when it picks up.

Inactive, Active

Inactive [Control/Bkr/Bkr[1]/Trip Manager]

Ack TripCmd Ack TripCmd 1..n, Assignment List -.- [Control/Bkr/Bkr[1]/Trip Manager]

Trigger1 Open Command to the Breaker if the state of the assigned signal becomes true.

1..n, Trip Cmds Bkr[1]: 50P[1].TripCmdBkr[2]: 50P[3].TripCmd

[Control/Bkr/Bkr[1]/Trip Manager]











1..n, Trip Cmds Bkr[1]: 50X[1].TripCmdBkr[2]: 50X[2].TripCmd



1..n, Trip Cmds Bkr[1]: 51X[1].TripCmdBkr[2]: 51X[2].TripCmd



1..n, Trip Cmds Bkr[1]: 50R[1].TripCmdBkr[2]: 50R[2].TripCmd



1..n, Trip Cmds Bkr[1]: 51R[1].TripCmdBkr[2]: 51R[2].TripCmd



1..n, Trip Cmds Bkr[1]: 51Q[1].TripCmdBkr[2]: 27M[1].TripCmd



1..n, Trip Cmds Bkr[1]: ZI[1].TripCmdBkr[2]: 27M[2].TripCmd


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1..n, Trip Cmds Bkr[1]: 46[1].TripCmdBkr[2]: 59M[1].TripCmd



1..n, Trip Cmds Bkr[1]: 49.TripCmdBkr[2]: 59M[2].TripCmd



1..n, Trip Cmds Bkr[1]: 24[1].TripCmdBkr[2]: 27A[1].TripCmd



1..n, Trip Cmds Bkr[1]: 24[2].TripCmdBkr[2]: 27A[2].TripCmd



1..n, Trip Cmds Bkr[1]: RTD.TripCmdBkr[2]: 59A[1].TripCmd



1..n, Trip Cmds Bkr[1]: -.-Bkr[2]: 59A[2].TripCmd



1..n, Trip Cmds Bkr[1]: -.-Bkr[2]: 46[2].TripCmd




















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1..n, Trip Cmds Bkr[1]: -.-Bkr[2]: 32V[1].TripCmd









1..n, Trip Cmds Bkr[1]: -.-Bkr[2]: 49.TripCmd









1..n, Trip Cmds Bkr[1]: -.-Bkr[2]: RTD.TripCmd



1..n, Trip Cmds -.- [Control/Bkr/Bkr[1]/Trip Manager]

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Synchronism Synchronism 1..n, In-SyncList -.- [Control/Bkr/Bkr[1]/Synchron Switchg]

t-MaxSyncSuperv

Synchron-Run timer: Max. time allowed for synchronizing process after a close initiate. Only used for GENERATOR2SYSTEM working mode.

0 – 3000.00 s 0.2 s [Control/Bkr/Bkr[1]/Synchron Switchg]

t-Move CLOSE Time to move to the CLOSE Position 0.01 – 100.00 s 0.1 s [Control/Bkr/Bkr[1]/General Settings]

t-Move OPEN Time to move to the OPEN Position 0.01 – 100.00 s 0.1 s [Control/Bkr/Bkr[1]/General Settings]

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Switchgear/Breaker Input States


CinBkr-52a-I Module Input State: Feed-back signal of the Bkr (52a)


CinBkr-52b-I Module Input State: Feed-back signal of the Bkr. (52b)


Ready-I Module Input State: Breaker Ready [Control/Bkr/Bkr[1]/Pos Indicatrs Wirng]

Sys-in-Sync-I State of the module input: This signals has to become true within the synchronization time. If not, switching is unsuccessful.

[Control/Bkr/Bkr[1]/Synchron Switchg]

Ack TripCmd-I State of the module input: Acknowledgment Signal (only for automatic acknowledgment). Module input signal


Interl CLOSE1-I State of the module input: Interlocking of the CLOSE command






Interl OPEN1-I State of the module input: Interlocking of the OPEN command






SC CLOSE-I State of the module input: Switching CLOSE Command, e.g. the state of the logic or the state of the digital input

[Control/Bkr/Bkr[1]/Ex OPEN/CLOSE Cmd]

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SC OPEN-I State of the module input: Switching OPEN Command, e.g. the state of the logic or the state of the digital input

[Control/Bkr/Bkr[1]/Ex OPEN/CLOSE Cmd]

Switchgear/Breaker Signals (Outputs States)

Name Description

SI SingleContactInd Signal: The Position of the Switchgear is detected by one auxiliary contact (pole) only. Thus indeterminate and disturbed Positions cannot be detected.

Pos not CLOSE Signal: Pos not CLOSEPos CLOSE Signal: Breaker is in CLOSE-PositionPos OPEN Signal: Breaker is in OPEN-PositionPos Indeterm Signal: Breaker is in Indeterminate PositionPos Disturb Signal: Breaker Disturbed - Undefined Breaker Position. The feed-

back signals (Position Indicators) contradict themselves. After expiring of a supervision timer this signal becomes true.

State Signal: Breaker Position (0 = Indeterminate, 1 = OPEN, 2 = CLOSE, 3 = Disturbed)

Ready Signal: Breaker is ready for operation.Interl CLOSE Signal: One or more IL_Close inputs are active.Interl OPEN Signal: One or more IL_Open inputs are active.CES succesf Command Execution Supervision: Switching command executed

successfully.CES Disturbed Command Execution Supervision: Switching Command

unsuccessful. Switchgear in disturbed position.CES Fail TripCmd Command Execution Supervision: Command execution failed

because trip command is pending.CES SwitchgDir Command Execution Supervision respectivly Switching Direction

Control: This signal becomes true, if a switch command is issued even though the switchgear is already in the requested position. Example: A switchgear that is already OPEN should be switched OPEN again (doubly). The same applies to CLOSE commands.

CES CLOSE d OPEN Command Execution Supervision: CLOSE Command during a pending OPEN Command.

CES SG not ready Command Execution Supervision: Switchgear not readyCES Field Interl Command Execution Supervision: Switching Command not

executed because of field interlocking.CES SyncTimeout Command Execution Supervision: Switching Command not

excecuted. No Synchronization signal while t-sync was running.TripCmd Signal: Trip CommandAck TripCmd Signal: Acknowledge Trip CommandBwear Slow Breaker Signal: Slow Breaker AlarmRes Bwear Sl Breaker Signal: Resetting the slow breaker alarm

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Name Description

CLOSE Cmd Signal: CLOSE command issued to the switchgear. Depending on the setting the signal may include the CLOSE command of the Prot module.

OPEN Cmd Signal: OPEN command issued to the switchgear. Depending on the setting the signal may include the OPEN command of the Prot module.

CLOSE Cmd manual Signal: CLOSE Cmd manualOPEN Cmd manual Signal: OPEN Cmd manualSync CLOSE request Signal: Synchronous CLOSE request

Direct Commands of the Switching Authority


Switching Authority

Switching Authority None, Local, Remote, Local and Remote

Local [Control/General Settings]

Signals of the Switching Authority

Name Description Menu Path

Local Switching Authority: Local []Remote Switching Authority: Remote []

Counters of the Switching Authority


CES SAuthority Command Execution Supervision: Switching Command not executed. No switching authority.

[Operation/Status display/Control/Ctrl]

CES DoubleOperating Command Execution Supervision: A second switch command is in conflict with a pending one.

[Operation/Status display/Control/Ctrl]

No. of rej. Com No. of rej. Com because Locked by ParaSystem.

[]

Switchgear Wear

Switchgear Wear Features

The sum of the accumulated interrupted currents.

A »SGwear Slow Switchgear« might indicate malfunction at an early stage.

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The protective relay will calculate the »SG OPEN Capacity« continuously. 100% means, that switchgear maintenance is mandatory now.

The protective relay will make a alarm decision based on the curve that the User provides.

The relay will monitor the frequency of CLOSE/OPEN cycles. The User can set thresholds for the maximum allowed sum of interrupt currents and the maximum allowed sum of interrupt currents per hour. By means of this alarm, excessive switchgear operations can be detected at an early stage.

Slow Switchgear Alarm

An increase of the close or opening time of the switchgear is an indication for the maintenance need. If the measured time exceeds the time »t-Move OPEN« or »t-Move CLOSE«, the signal »SGwear Slow Switchgear« will be activated.

Switchgear Wear Curve

In order to keep the switchgear in good working condition, the switchgear needs to be monitored. The switchgear health (operation life) depends above all on:

• The number of CLOSE/OPEN cycles. • The amplitudes of the interrupting currents.• The frequency that the switchgear operates (Operations per hour).

The User has to maintain the switchgear accordingly to the maintenance schedule that is to be provided by the manufacturer (switchgear operation statistics). By means of up to ten points that the User can replicate the switchgear wear curve within menu [Control/SG/SG[x]/SGW]. Each point has two settings: the interrupt current in kilo amperes and the allowed operation counts. No matter how many points are used, the operation counts the last point as zero. The protective relay will interpolate the allowed operations based on the switchgear wear curve. When the interrupted current is greater than the interrupt current at the last point, the protective relay will assume zero operation counts.

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Global Protection Parameters of the Breaker Wear Module


CT Winding Side


W1 W1 [Control/Bkr/Bkr[1]/Bwear]

Operations Alarm

Service Alarm, too many Operations 1 - 100000 9999 [Control/Bkr/Bkr[1]/Bwear]

Isum Intr Alarm Alarm, the Sum (Limit) of interrupting currents has been exceeded.

0.00 – 2000.00 kA 100.00 kA [Control/Bkr/Bkr[1]/Bwear]

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0.1 1 10 1001

10

100

1 103×

1 104×0.0

100001.2

10000

8.0150

20.012

20.00

Breaker Maintenance Curve for a typical 25kV Breaker

Num

ber o

f Ope

ratio

ns

Interrupted Current in kA per operation

ETR-5000 IM02602013E


Isum Intr ph Alm

Alarm, the per hour Sum (Limit) of interrupting currents has been exceeded.


Bwear Curve Fc

The Breaker Wear Curve defines the maximum allowed CLOSE/OPEN cycles depending on the brake currents. If the breaker maintenance curve is exceeded, an alarm will be issued. The breaker maintenance curve is to be taken from the technical data sheet of the breaker manufactor. By means of the available points this curve is to be replicated.

Inactive, Active

Inactive [Control/Bkr/Bkr[1]/Bwear]

WearLevel Alarm

Breaker Wear curve Alarm

Only available if:Bwear Curve Fc = Active

0.00 - 100.00% 80.00% [Control/Bkr/Bkr[1]/Bwear]

WearLevel Lockout

Breaker Wear Curve Lockout Level


0.00 - 100.00% 95.00% [Control/Bkr/Bkr[1]/Bwear]

Current1 Interrupted Current Level #1



Count1 Open Counts Allowed #1


1 - 32000 10000 [Control/Bkr/Bkr[1]/Bwear]
















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Breaker Wear Signals (Output States)

Name Description

Operations Alarm Signal: Service Alarm, too many OperationsIsum Intr trip: IA Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: IAIsum Intr trip: IB Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: IBIsum Intr trip: IC Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: ICIsum Intr trip Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded in at least one phase.Res TripCmdCr Signal: Resetting of the Counter: total number of trip commandsRes Isum trip Signal: Reset summation of the tripping currentsWearLevel Alarm Signal: Breaker Wear curve AlarmWearLevel Lockout Signal: Breaker Wear Curve Lockout LevelRes Bwear Curve Signal: Reset of the Breaker Wear maintenance curve.Isum Intr ph Alm Signal: Alarm, the per hour Sum (Limit) of interrupting currents has

been exceeded.Res Isum Intr ph Alm Signal: Reset of the Alarm, "the per hour Sum (Limit) of

interrupting currents has been exceeded".

Breaker Wear Counter Values


TripCmd Cr Counter: Total number of trips of the switchgear (breaker, load break switch…). Resettable with Total or All.

[Operation/Count and RevData/Ctrl/Bkr[1]]

Breaker Wear Values


Isum trip IA Summation of the tripping currents phase [Operation/Count and RevData/Ctrl/Bkr[1]]

Isum trip IB Summation of the tripping currents phase [Operation/Count and RevData/Ctrl/Bkr[1]]

Isum trip IC Summation of the tripping currents phase [Operation/Count and RevData/Ctrl/Bkr[1]]

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Isum Intr per hour Sum per hour of interrupting currents. [Operation/Count and RevData/Ctrl/Bkr[1]]

Bkr OPEN capacity Bkr. OPEN capacity. 100% means, that the breaker is to be maintenanced.

[Operation/Count and RevData/Ctrl/Bkr[1]]

Direct Commands of the Breaker Wear Module


Res TripCmdCr Resetting of the Counter: total number of trip commands

Inactive, Active


Res Isum trip Reset summation of the tripping currents Inactive, Active


Res Isum Intr per hour

Sum per hour of interrupting currents. Inactive, Active


Res Bkr OPEN capacity

Resetting of the Bkr. OPEN capacity. 100% means, that the breaker is to be maintenanced.

Inactive, Active


Control - Example: Switching of a BreakerCtrl

The following example shows how to switch a breaker via the HMI at the device.

Change into the menu »Control« or alternatively push the »CTRL« button at the device front.

Change to the control page by pushing the »right arrow« softkey.

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Information only: On the control page a single line diagram with the current switchgear positions is displayed. By means of the softkey »Mode« it can be switched to the menu »General Settings«. In this menu switching authority and interlockings can be set.

By means of the softkey »SG« it can be switched to the menu »SG«. In this menu specific settings for the switch gear can be done.

To execute a switching operation, change into the switching menu by pushing the right arrow softkey button.

Executing a switching command via the devices HMI is only possible when the switching authority is set to »Local«. If no switching authority is given, this has to be set first to »Local« or »Local and Remote«.

With the softkey »OK« it can be switched back to the single line diagram page.

Pushing the softkey »Mode« leads to the menu »General Settings«.

In this menu the switching authority can be changed.

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xQA1

QB1 QB2

xQA1

QB1 QB2

xQA1

QB1 QB2

IM02602013E ETR-5000

Select between »Local« or »Local and Remote«.

Now it is possible to execute switching commands at the HMI.

Push the »right arrow« softkey to get to the control page.

To select a switchgear press the softkey »Select« as long as the desired switchgear is selected. The current selection is displayed by the edges of a rectangle. In this example the breaker is selected. Switchgears that are supervised only, cannot be selected.

The breaker is opened, therefore it can be closed only.

After pushing the softkey »ON« a confirmation window appears.

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xQA1

QB1 QB2

xQA1

QB1 QB2

xQA1

QB1 QB2

xQA1

QB1 QB2

ETR-5000 IM02602013E

When you are sure to proceed with the switching operation, press the softkey »YES«.

The switching command will be given to the breaker. The display shows the intermediate position of the switchgear.

It will be shown on the display when the switchgear reaches the new end position. Further possible switching operations (OPEN) will be displayed by softkeys.

Notice: For the case, the switchgear does not reach the new end position within the set supervision time the following Warning appears on the display.

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xQA1

QB1 QB2

x QA1

QB1 QB2

IM02602013E ETR-5000

Protective Elements87 - Differential Protection

Phase Current Differential ProtectionElements:87

DescriptionThe protective device provides phase restrained differential protection function with the User-configurable multiple slope percentage restrained characteristic that allows the User to compensate both the static error and the dynamic error. The static error accounts for transformer magnetizing current and current measurement circuit calibration errors. The dynamic error may be caused by CT ratio mismatch due to tap changing and by CT secondary currents falsely representing their primary currents due to the increased magnetizing current caused by fault current.

The dynamic error is proportional to the fundamental restraining current. In addition, the static tripping characteristic can be temporarily modified at the User’s choice to prevent some nuisance tripping from the harmonic inrush during energization, over-excitation, or deep CT saturation. The harmonic inrush is evaluated through 2nd, 4th, and 5th harmonics and the transient is monitored through the CT saturation detector.

The direction convention adopted here is as shown in the following drawing.

Protection Principle of the Current Differential Protection by Example of a Two-sided Fed Transformer.

The phase restrained percentage differential protection tripping characteristic can mathematically be expressed as:

∣I d∣≥∣I dmin∣ K1∗∣I r∣Ir Idmin and Id2∗ I b

K 2∗∣I r∣I r2∗ Ib

d H ,m

Where ∣I d∣=∣I W1' 'I W2

' '∣ is defined as the fundamental differential current.I W1 and I W2 are uncompensated winding primary phase current phasors.

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Grid

IW1 IW2

Protective Relay

Protected Zone

Grid

ETR-5000 IM02602013E

I W1' ' and I W2

' ' are the compensated phase current phasors of winding 1 and winding 2.

Under normal conditions, the differential current should be below ∣I dmin∣ . When an internal fault occurs, the different current will raise above the restraining current to trip. To establish this trip criterion, two winding currents must be matched by compensating their magnitudes and phases.

∣I r∣=0.5∗∣I W1' '−I W2

''∣ is the fundamental restraining current, and it is also called the through current for

normal load and external faults. d H ,m is the temporary restraining current, which is a configurable multiple of the base current I b .

Setting the Tripping Curve

∣I dmin∣ is the minimum differential current multiple scaled to the base current in order for the phase restrained differential protection to trip, which should be set based on the static error (no load error, transformer magnetizing current, and measurement circuit noise). K1 and K2 are the restraining slopes that can be determined with the settings I d ∣I r0∣ , I d ∣I r1∣ , and I d ∣I r2∣ that are expressed as multiples of the base current.

K1=∣I d ∣I r1∣−I d ∣I r0∣∣/2

K2=∣I d ∣I r2∣−I d ∣I r1∣∣/8

The base currents can be obtained from the transformer power rating (»SN«, MVA) and voltage ratings (»TrVLL,« line to line voltage).

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Trip Range

Operating Range

Static Base Curve

Ir/IbIr1= 2 x Ib Ir2= 10 x Ib

Id[Ir2]

Id[Ir1]

Id[Ir0]Id min

Id/Ib

Slope1

Slope2

IM02602013E ETR-5000

The base currents are defined as:

I b ,W1=S N

3TrV LLW1

I b ,W2=S N

3TrV LLW2

For settings the tripping characteristics of the 87 Differential Protection, the base current I b=I b , W1 is to be used.

The procedures to configure: I d ∣I r0∣ , I d ∣I r1∣ , and I d ∣I r2∣ :

1. Use I d ∣I r0∣ as a minimum restraining current multiple when the differential current is zero;

2. Select the slope K1 (usually around 15%-40% [typically 25%]);

3. I d ∣I r1∣=I d ∣I r0∣2∗K1 ;

4. Select the slope K2 (usually around 40%-90% [typically 60%]); and

5. I d ∣I r2∣=I d ∣I r1∣8∗K 2 .

Magnitude Compensation

The compensated phase current phasor calculations are performed automatically and involve amplitude and phase adjustments based on the system parameters, voltage ratings, tap position (assuming the tap changer is on the winding 1 side), winding connections and groundings, and the secondary winding phase shift (n) relative to the primary.

I W2'=

V LLW2

V LLW1∗1%Tap ∗T PhaseShift n ∗

CT2Pri

CT2Sec∗I W2

Since the winding 1 is taken as the reference I W1'=

CT1Pri

CT1Sec∗I W1 , I W1 and I W2 are uncompensated

secondary winding phase current phasors.

CT Mismatch

None of the Amplitudes Matching factors must exceed a value of 10.

k CT1=CT1Pri

IbW110 and k CT2=

CT1Pri

IbW210

In addition, the second largest amplitudes matching factor must be greater than 0.5

The ratio between the maximum and second largest must not exceed a value of 3.

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Phase Compensation (ABC Phase System)

Note that the phase shift n is specified as a multiple of -30°. A positive n means the secondary is lagging the primary side. The User must carefully select the right number based on the winding connections. The following table lists the typical transformer connection types and their corresponding phase shifts for ABC phase sequence.

VectorGroup

PhaseShift

Transformer Connection Type

Winding 1 Connection Winding 2 Connection

0 0°

Yy0

Dd0

Dz0

1 30°

Yd1

Dy1

Yz1

2 60° Yy2

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a

b

c

A

a

b

c

A

BC

a

b

c

A

BC

a

bc

A

BC

a

bc

A

BC

a

bc

A

BC

IM02602013E ETR-5000

Dd2

Dz2

3 90°

Yd3

Dy3

Yz3

4 120°

Yy4

Dd4

Dz4

5 150°

Yd5

Dy5

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ab

cA

BC

ab

cA

BC

ab

cA

BC

a

b

cA

C B

a

b

c

C B

A

a

b

cA

BC

a

b

c

a

b

cA

BC

A

C B

a

b

c

C

A

B

a

b

c

C

A

B

ETR-5000 IM02602013E

Yz5

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a

b

cA

BC

a

b

cA

BC

IM02602013E ETR-5000

VectorGroup

PhaseShift



6 180°

Yy6

Dd6

Dz6

7 210°

Yd7

Dy7

Yz7

8 240°Yy8

Dd8

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a

b

c

a

b

c

A

BC

a b

cA

BC

A

BC

a

b

c

A

BC

a

b

c

A

BC

a

b cA

BC

a

b cA

BC

a

b cA

BC

ETR-5000 IM02602013E

VectorGroup

PhaseShift



Dz8

9 270°

Yd9

Dy9

Yz9

10 300°

Yy10

Dd10

Dz10

11 330°

Yd11

Dy11

Yz11

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a

b

c

a

b

c

a

b

c

A

BC

a

b

c

a b

c

a

c

b

a b

c

a

b

c

A

BC

A

BC

A

BC

A

BC

A

BC

A

BC

a

b

c

A

BC

a

b

c

A

BC

IM02602013E ETR-5000

VectorGroup

PhaseShift



Phase Compensation (ACB Phase System)

The phase shift n for the ACB phase sequence should be 12’s complement to the corresponding transformer connection type. For instance, Dy5 for the ABC phase sequence will be Dy7 (12-5) for the ACB sequence, Dy11 becomes Dy1, and so on.

Zero Sequence Removal

Zero sequence currents must be removed to prevent the phase differential protection from tripping on external ground faults. The protective device does not require the zero sequence currents to be removed externally and they will be automatically removed internally if their neutrals are grounded based on the system parameters »W1 Connection/Grounding« and »W2 Connection/Grounding«.

I W1' '=I W1

'−I 0, W1'

I W2' '=I W2

'−I 0 ,W2'

Retrofitting – External Compensation

By using the external removal approach, the relay will not see the zero sequence current on which other functions, such as residual overcurrent functions, ground differential function, etc., will be stopped.

For a retrofit project, if the User has CTs externally connected in such a way that the zero sequence currents are automatically removed, then the internal zero sequence currents compensation will not be needed. However, if the User prefers the external approach of zero sequence current removal, the User must be aware that the protective device is a multi-function, digital protection system and the phase differential function is one of them. By using the external removal approach, the relay will not see the zero sequence current on which other functions such as residual overcurrent functions, ground differential function, etc., will be stopped. If the User is only interested in the phase differential function in this relay, close attention must be paid to the phase shift and CT ratios. Under normal or external fault conditions, the CT secondary currents from two windings should be equal in magnitude, i.e.:

∣ CT1Sec

CT1Pri /3∗I W1∣=∣CT2Sec

CT2Pri∗I W2∣ if the winding 1 CTs are delta-connected; or

∣CT1Sec

CT1Pri∗I W1∣=∣ CT2Sec

CT2Pri/3∗I W2∣ if the winding 2 CTs are delta-connected.

The User must provide the relay with the modified CT primary rating to accommodate the current's effective decrease due to the CT delta connection. The CT primary rating setting on the CT delta connected side should be divided by 3 .

The phase shift n for the CT delta connected case should include the phase shift from transformer winding

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A

BC

ETR-5000 IM02602013E

connections and additional phase shift from CT delta connection. There are only two methods for the CT delta connection:

• DAB (dy1); or• DAC (dy11).

For instance, if the User has a Yd1 transformer and the neutral on the Y side is grounded, the User must have CTs on the Y side connected as DAC (Dy11), then the User has total phase shift 1+11=12 (same as 0 in terms of phase shift). If the User has a Yd5 transformer and the neutral on the Y side is grounded, the User must have CTs on the Y side connected as DAB (Dy1), then the User has total phase shift 5+1=6.

Transformer Winding Connection Type

CT Delta Connection Type on Y or y Side

Total Phase Shift Multiple n

Dy1 DAC (Dy11) 12 (0)

Dy5 DAB (Dy1) 6

Dy7 DAC (Dy11) (18 % 12) =6

Dy11 DAB (Dy1) 12 (0)

Yd1 DAC (Dy11) 12 (0)

Yd5 DAB (Dy1) 6

Yd7 DAC (Dy11) (18 % 12) =6

Yd11 DAB (Dy1) 12 (0)

Once a correct phase shift n is selected, the phase compensation calculations are done automatically using the corresponding phase shifting matrix listed in the table.

Temporarily Restraining

The transient behavior can be evoked by:

1. Directly energizing the transformer (inrush effect);2. Sympathetic inrush current sharing due to adjacent transformer energization; and/or3. Saturation of the CT.

Temporarily restraining can be triggered by:

1. 2nd harmonic trigger is enabled and the percentage of the 2nd harmonic exceeds its threshold;2. 4th harmonic trigger is enabled and the percentage of the 4th harmonic exceeds its threshold;3. 5th harmonic trigger is enabled and the percentage of the 5th harmonic exceeds its threshold; or4. CT saturation trigger is enabled and saturation is detected.

By means of the »Block mode« (Cross Block), the User can specify if an harmonic signal or CT saturation within one phase temporarily causes restraining within this phase only or a cross block (3 phases).

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Temporarily Restraining (by monitoring of the harmonics)

The protective device also offers the temporary restraining feature for further securing phase restrained percentage differential protection against harmonics and other transients such as CT saturation. Separating the temporary restraining from the fundamental restraining can make the differential protection more sensitive to internal faults and more secure when harmonics or other transients occur. The temporary restraining, whenever effective, will essentially add a constant d H ,m to the fundamental restraining. Graphically, the static tripping curve is temporarily raised by d H ,m . The amount of the temporary restraining is configured as multiple of the base current I b . The 2nd, 4th, and 5th harmonics percentage relative to fundamental and CT saturation can trigger the temporary restraining. For each harmonic trigger function to be effective, it must be enabled and the percentage of the harmonic over fundamental must exceed its threshold.

Moreover, for the 2nd and 5th harmonics trigger functions, they can be independently configured as having different trigger levels for transient and stationary harmonics. The transient restraining will be effective for a specified t-Trans beginning with energization, which should be set according to the time duration expected for inrush (IH2) currents. For example, this can vary from around 1 second up to nearly 30 seconds for special applications like auto-transformer banks.

The stationary harmonic restraining will take place after t-Trans for time as long as one of the stationary harmonic triggers is active.

Temporarily Restraining (by CT saturation monitoring)

Beside the harmonic temporary restraining triggers, the protective device offers another trigger function - the Transients Monitor (Gradient Monitor). This monitor supervises the current transformer saturation. This monitor will be triggered by the behavior of the phase currents (their slopes, normalized derivative).

The normalized derivative is defined as:

m=1

∗I peak∗

didt ,

where I peak is the peak value within a half cycle and is the system frequency.

For a pure sinusoidal waveform, the normalized derivative should be equal to 1. Under CT saturation, m will be greater than 1. The setting CT Satur Sensitvn should be set properly to effectively identify CT saturation but not to generate a nuisance trigger.

When the CT saturation monitor is active, it will trigger the temporary restraining if m exceeds an internal threshold. The temporary restraining, whenever effective, will essentially add a constant d H ,m to the fundamental restraining. Graphically, the static tripping curve is temporarily raised by d H ,m by which the sensitivity of the differential protection function is temporarily reduced.

The internal threshold can be modified by means of the CT Saturation Sensitivn. The CT saturation monitor will behave more sensitively the lower the setting value is set.

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Temporary Dynamic Rise of the Static Tripping Characteristic.

The following signals cannot become true if Id<Idmin:

87. Slope Blo87. H2,H4,H5 Blo87. Blo H287. Blo H487. Blo H587. Restraining

The signal restraining will become true if “87. Slope Blo” or “87. H2,H4,H5 Blo” is true.

Example on Setting the Differential Function

Setting the differential module will be described here with focus on the differential functionality.

Please note:

• All other functionality and settings are the same for this example;• Configuring the blocking,• Routing the trip command, and• Device planning.• Others are to be treated as described for other modules and in general in this document.

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87H

Id[Ir1]

Id[Ir0]

Id[Ir1]´

Id[Ir0]´

Id[Ir2]

Id[Ir2]´

d[m]Id min´

Id min

d[H,m]

Ir1= 2 x Ib Ir2= 10 x Ib Ir/Ib

Trip Range

Operating Range

Id/Ib

IM02602013E ETR-5000

The protective device asks for nearly all type-plate data of the transformer to allow for optimal adjustment of the differential function without the need of an auxiliary transformer and other tools like CT tapping (especially that known from non-digital relays in the past).

This results in the fact that the relay automatically takes these numeric values into account:

• CT ratio and its deviation from full load amperage at each winding of the transformer;• Transformer ratio with respect to amplitude and transformer vector-group; and• Ratio change by tap changer displacement.

All this is internally compensated for by numeric means.

SN:Nominal, rated capacity of the transformer - basis for calculating the full load amperage of the transformer.

Example78 MVA

TrV W1:Rated voltage of the transformer regarding winding 1.

Example118 kV

TrV W2:Rated voltage of the transformer regarding winding 2.

Example14.4 kV

By means of these three settings, the following full load amperage Ib is calculated, which is defined as the full load amperage for the maximum allowed apparent power of the transformer. There is one full load amperage for each winding, but differential protection results are always displayed in relation to Ib of the winding 1.

Example:

Ib= 78000000 VA3∗118000 V

=381 A

Ib = Full load current (FLA related to the primary side).

Connection Groups

W1 Winding/GroundingThis is the setting for the connection scheme of the winding 1 and its grounding condition.

Allowed Settings Default (example)Y, D, Z, YN, ZN D

W2 Winding/GroundingThis is the setting for the connection scheme of the winding 2 and its grounding condition.

Allowed Settings Default (example)y, d, z, yn, zn yn

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The combination of W1 Winding/Grounding and W2 Winding/Grounding allows for all possible physical connection schemes of power transformers. The N or n can be set whenever the neutral of the transformer is connected to ground and the grid on that side of the winding is grounded.

Phase Shift:Phase shift in multiples of 0...11 * (-30) degree that the secondary voltage lags the primary voltage.

Default (example)1 (-30 degrees )

Please refer to the Phase Compensation section for a number of typical, preferred transformer types.

For (Y, y, Z, z) connections, the neutral can be connected to ground or not connected to ground. In general, there is a distinction between odd (1, 3, 5, …, 11) and even (0, 2, 4, …,10) connection numbers. Together with the connection scheme (y, d, or z) and the treatment of the neutral of the transformer, the following characteristics can be defined for current transformation from one side of a transformer to the other (described by means of symmetrical components ( I1, I2, I0) and its representation by the protective device).

• The three-phase symmetrical system I1 is rotated counter-clockwise when transferring from winding 1 to winding 2 (applies for ABC phase sequence).

• The three-phase symmetrical system I2 is rotated clockwise when transferring from winding 1 to winding 2. (applies for ABC phase sequence).

• The connection of the transformer to a negative rotating system (ACB) is taken into account according to the parameter.

• The transformation of the zero sequence system I0 depends on the connection of the windings:• Only (Y, y, Z, z) – connections provide for an externally available neutral point;• Only when this neutral point is connected to ground, and at least another ground connection is

available on the grid to which the winding is connected (a zero sequence - respectively ground current can flow); and

• Only when both windings of the transformer allow for ground current flowing, the zero sequence current can be transformed from one side of the transformer to the other without any phase shift.

• Odd connection groups are created by Dy, Yd, Yz, Zy schemes.• Even connection groups are created by Yy, Zd, Dz, Dd.• The primary values of winding 1 are reference values when displaying or evaluating relative values.

This primary voltage level is adapted using an on load tap changer.

Tap Changer:The tap changer changes the transformer voltage ratio k Tap .

k Tap=TrV W11TapChanger % /100%

TrV W2

Default (example)14.4 kV

Principally, the following calculations need to be executed before calculating differential values and restraining values of the transformer differential protection:

• Rotating the measured values of winding 2 to the reference system independent from the count-clockwise rotation number (0, 1, …..11) * 30 degrees;

• Adjustment of measured values for winding 2 with respect to CT ratio mismatch;

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• Adjustment of measured values for winding 2 with respect to winding connection (y, d, z); and• Adjustment of measured values for winding 1 and winding 2 according to neutral connection and ground

treatment (zero sequence current elimination).

Automatic Calculations: Amplitudes, Vector Groups, and Zero Sequence Removal

The calculations performed can be done by matrix calculations. Three steps have to be completed.

1. Adjust the amplitude according to all transformation ratios (power transformer and CTs).2. Adjust the vector group angle by rotating the three-phase system accordingly.3. Remove the zero sequence current where necessary (this being valid for winding 1 and winding 2).

1. Amplitude Adjustment:

I W2A, B,C

´ = I W2A, B,C∗k r k r =

CT pri , W2

I fla , W2∗

I fla ,W1

CT pri , W1=

CT pri ,W2

CT pri , W1∗

TrV W2

TrV W1∗1 ∂Tap

2. Vector Group Adjustment:

The vector group adjustment is calculated using the following formulas and transformation matrices:

I W2ABC

' ' =[ T vector group ] ∗ I W2 ABC

' [T vector group ] [T 0,1 ,2...11 ]

Even Connection Groups Odd Connection Groups

T 0=[1 0 00 1 00 0 1]

T 2=[ 0 −1 00 0 −1−1 0 0 ]

T 4=[0 0 11 0 00 1 0]

T 6=[−1 0 00 −1 00 0 −1]

T 8=[0 1 00 0 11 0 0]

T 10=[ 0 0 −1−1 0 00 −1 0 ]

T 1=13

∗[ 1 −1 00 1 −1−1 0 1 ]

T 3=13

∗[ 0 −1 11 0 −1−1 1 0 ]

T 5=13

∗[−1 0 11 −1 00 1 −1]

T 7=13

∗[−1 1 00 −1 11 0 −1]

T 9=13

∗[ 0 1 −1−1 0 11 −1 0 ]

T 11=13

∗[ 1 0 −1−1 1 00 −1 1 ]

3. Zero sequence removal (elimination of the ground current if this can only flow through one winding at the external asymmetrical faults and will not be transformed to the other winding).

Zero sequence removal will be calculated for the primary winding system, if the W1con value is set to YN or ZN.

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A zero sequence current can only flow:

1. If the neutral is connected to ground; and2. The grid on the primary side is grounded as well.

I W1 A, B,C

* = I A, B ,C' ' − I 0

For the secondary winding system:

Zero sequence removal will be calculated for the secondary winding system, if the W2con value is set to yn or zn.

A zero sequence current can only flow:

1. If the vector group is odd;2. If the neutral is connected to ground; and3. The grid on the secondary side is grounded as well

I W2A, B,C

' ' ' =I W2A ,B ,C

' ' − I 0

After setting the values for the percentage restrained characteristic curve, the settings for harmonic and transient restraining have to be defined. Both the harmonic and transient restraining settings depend on many parameters:

• Transformer type;• Transformer material;• Operational parameter of the grid; and• Time of energizing relative to the sinusoidal phase.

Therefor it is very difficult to give “one for all” settings in this area and to find a compromise between making a differential relay extremely fast and extremely reliable in its trip decisions.

Beginning with the static characteristic curve, typical slopes of 25% and 50% for both sections are recommended. They will be obtained by the following settings:

Id(Ir0)Default (example)0.2

Id(Ir1)Default (example)0.7

Id(Ir2)Default (example)5

In case of harmonic or transient restraint, the curve will be added by an offset d(H,m) - in version 1.0 a static offset.

To be able to withstand magnetizing inrush currents of typical values, the following value of d(H,m) is recommended and given per default.

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d(H,m)

Default (example)8

In case of any harmonic restraint threshold is reached, this value will be added to the characteristic curve.

It is important to estimate the necessary harmonic threshold to obtain stability against magnetizing inrush, CT saturation, and over-excitation. The harmonics seen under different operational conditions like magnetizing inrush and CT saturation depend on many different parameters.

Magnetizing inrush:

Basically, en harmonics can be observed and monitored. Due to this fact, the 2nd and 4th harmonic are monitored. Inrush currents depend on the time of energizing, the remnant magnetizing compared to phase of sinusoidal curve, the voltage (low voltage energizing produce less harmonic), the core material and the core geometry among others. It is generally recommended to set the harmonic restraint as active.

Stab H2Default (example)active


To operate very stably under stationary circumstances, it can be distinguished between a stationary value of harmonic thresholds and a transient harmonic threshold directly after energizing. This transient period is always started if the differential as well the restraining current is below 0.05% of the nominal CT current setting. The following values are recommended for typical cases:

H2 StaDefault (example)25,00%

H2 TraDefault (example)10,00%


For CT saturation, the 5th harmonic is one typical criteria. This feature also should be activated as long as CT saturation is expected due to CT dimensioning and operational current values under external faults. It has to be noted that CT saturation can only be monitored as long as there is a critical rest of the current transformed to the secondary side of the CT. For severe CT saturation, the CT can be nearly short circuited, as seen from the primary side, so that nearly no measurable current can be monitored or analyzed.


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H5 TraDefault (example)15,00%

The so called transient time period directly after energizing strongly depends on the above mentioned influencing parameter. Time spans from nearly zero to more than 15 seconds are known for special auto-transformer banks. A typical setting of 2 s is recommended for commonly used transformers.

t-TransDefault (example)2 s

All harmonic-generating events can occur to a different degree in one, two, or all three phases. That is why there is a choice provided to restrain only those phases with harmonic content or restrain all three phases, which is recommended for typical application, as long as knowledge of the grid and modes of operation do not prove another choice.

Block modeDefault (example)inactive

The Transient Monitor continuously analyzes the differential current signal. If it detects saturation (m>1 or m<-1), it will decide whether the saturation is caused by internal or external faults.

• External Faults: the sign of differential current and of slope are equal (both “-“ or both”+”).• Internal Faults: the sign of differential current and slope are different (one “-“ and the other “+” or the

other way round).

If the saturation is caused by an internal fault, there will be no raising/stabilizing of the tripping curve. If the saturation is caused by an external fault, the tripping curve will be raised by d(H,m).

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Idmax

Id

Pure sinusoidal waveform

t

DerivativeDerivativereal

IM02602013E ETR-5000

CT-satur MonitDefault (example)active

The recommended value of the CT saturation monitor is 80%.

CT Satur SensitvnDefault (example)80,00%

Device Planning Parameters of the Phase Current Differential Protection




Global Protection Parameters of the Phase Current Differential Protection



1..n, Assignment List -.- [Protection Para/Global Prot Para/Tdiff-Prot/87]





Setting Group Parameters of the Phase Current Differential Protection



Inactive, Active

Active [Protection Para/<1..4>/Tdiff-Prot/87]


Inactive, Active

Inactive [Protection Para/<1..4>/Tdiff-Prot/87]

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Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


Id min Constant minimum pickup current (differential current).

0.1 – 1.0 Ib 0.2 Ib [Protection Para/<1..4>/Tdiff-Prot/87]

Id(Ir0) Starting point of the static tripping characteristic when Ir = 0


Id(Ir1) Breaking point of the static tripping characteristic when Ir = 2 x Ib


Id(Ir2) Value of the static tripping characteristic when Ir = 10 x Ib


d(H,m) Restraining factor for rising the static tripping characteristic in case of stationary or transient harmonic components, which are ascertained by Fourier analysis (H) or transients monitor (m).

0.0 – 30.0 Ib 8 Ib [Protection Para/<1..4>/Tdiff-Prot/87]

H2 Restrain Restraining of differential protection function against stationary or transient components of the 2nd harmonic at the phase current (e.g.: rush-effect).

Inactive, Active


H2/H1 Stat Threshold (2nd harmonic - basic wave ratio) for restraining the differential protection function against stationary 2nd harmonic.

10 - 50% 25% [Protection Para/<1..4>/Tdiff-Prot/87]

H2/H1 Trans Threshold (2nd harmonic – basic wave ratio) for temporary restraining of the differential protection function against transient 2nd harmonic.


H4 Restrain Restraining of differential protection function against stationary components of the 4th harmonic at the phase current.

Inactive, Active


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H4/H1 Threshold (4th harmonic - basic wave ratio) for restraining the differential protection function against stationary 4th harmonic.


H5 Restrain Restraining of differential protection function against stationary or transient components of the 5th harmonic at the phase current (e.g.: transformer overexcitation).

Inactive, Active


H5/H1 Stat Threshold (5th harmonic - basic wave ratio) for restraining the differential protection function against stationary 5th harmonic.


H5/H1 Trans Threshold (5th harmonic – basic wave ratio) for temporary restraining of the differential protection function against transient 5th harmonic.


t-Trans Time of temporary restraining of the differential protection function when thresholds for "H2 Tra“ and "H5 Tra“ (transient harmonic) are exceeded.

0.05 – 120.00 s 2 s [Protection Para/<1..4>/Tdiff-Prot/87]

Block mode Phase overlapping restraining of the differential protection function.

Inactive, Active


CT Satur Monit Current Transformer Saturation Supervision Inactive, Active


CT Satur Level Sensitiveness of the Current Transformer Saturation Supervision. The higher the value, the lower the sensitiveness.


Phase Current Differential Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Tdiff-Prot/87]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Tdiff-Prot/87]


[Protection Para/Global Prot Para/Tdiff-Prot/87]

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Phase Current Differential Protection Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandAlarm A Signal: Pickup System Phase AAlarm B Signal: Pickup System Phase BAlarm C Signal: Pickup System CPickup Signal: PickupTrip A Signal: Trip System Phase ATrip B Signal: Trip System Phase BTrip C Signal: Trip System Phase CTrip Signal: TripTripCmd Signal: Trip CommandBlo H2 Signal: Blocked by Harmonic:2Blo H4 Signal: Blocked by Harmonic:4Blo H5 Signal: Blocked by Harmonic:5H2,H4,H5 Blo Signal: Blocked by Harmonics (Inhibit)Slope Blo Signal: Differential protection was blocked by current transformer

saturation. The tripping characteristic was lifted because of current transformer saturation.

Transient Signal: Temporary restraining of the differential protection afterwards the transformer is being engergized.

Restraining Signal: Restraining of the differential protection by means of rising the tripping curve.

Slope Blo: A Slope Blo: ASlope Blo: B Slope Blo: BSlope Blo: C Slope Blo: CRestraining: A Restraining: ARestraining: B Restraining: BRestraining: C Restraining: C

87

Phase Current Differential Protection Module Values


IdA H2 Measured Value (Calculated): Differential Current Phase A Harmonic:2

[Operation/Measured Values/87]

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IdB H2 Measured Value (Calculated): Differential Current Phase B Harmonic:2


IdC H2 Measured Value (Calculated): Differential Current Phase C Harmonic:2















IrA Measured Value (Calculated): Restraint Current Phase A


IrB Measured Value (Calculated): Restraint Current Phase B


IrC Measured Value (Calculated): Restraint Current Phase C


IdA Measured Value (Calculated): Differential Current Phase A


IdB Measured Value (Calculated): Differential Current Phase B


IdC Measured Value (Calculated): Differential Current Phase C


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Phase Current Differential Protection Module Statistics


IdAH2max Maximum Value IdAH2 [Operation/Statistics/Max/87]

IdBH2max Maximum Value IdBH2 [Operation/Statistics/Max/87]

IdCH2max Maximum Value IdCH2 [Operation/Statistics/Max/87]








IrA max Measured Value (Calculated): Restraint Current Phase A Maximum Value


IrB max Measured Value (Calculated): Restraint Current Phase B Maximum Value


IrC max Measured Value (Calculated): Restraint Current Phase C Maximum Value


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IdA max Measured Value (Calculated): Differential Current Phase A Maximum Value


IdB max Measured Value (Calculated): Differential Current Phase B Maximum Value


IdC max Measured Value (Calculated): Differential Current Phase C Maximum Value


Unrestrained High-set Differential Current Protection [87H]

Elements:87H

Irrespective of the set static tripping characteristic and restraining factors d[H,m], a pickup value for a max. differential current 87H can be adjusted and results in undelayed tripping when exceeded. This protection step is referred to as high-set differential step 87H and only trips on faults within the protection zone.

Unrestrained High-set Differential Protection Step 87H

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High-Set Differential Current Protection/

Unrestrained High-phase Fault: Pickup value of the differential current based

on the rated current.

Id[Ir2]

Id[Ir1]

Id[Ir0]Id min

Id/Ib

87H

Ir1= 2 x Ib Ir2= 10 x Ib Ir/Ib

Trip Range

Operating Range

Slope1

Slope2

ETR-5000 IM02602013E

Device Planning Parameters of the Unrestrained High-set Differential Current Protection Module




Global Protection Parameters of the Unrestrained High-set Differential Current Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Tdiff-Prot/87H]





Setting Group Parameters of the Unrestrained High-set Differential Current Protection Module



Inactive, Active

Active [Protection Para/<1..4>/Tdiff-Prot/87H]


Inactive, Active

Inactive [Protection Para/<1..4>/Tdiff-Prot/87H]


Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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Id>> High-Set Differential Current Protection/Unrestrained High-phase Fault: Pickup value of the differential current based on the rated current.

2.0 – 30.0 Ib 10.0 Ib [Protection Para/<1..4>/Tdiff-Prot/87H]

Unrestrained High-set Differential Current Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Tdiff-Prot/87H]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Tdiff-Prot/87H]


[Protection Para/Global Prot Para/Tdiff-Prot/87H]

Signals of the Unrestrained High-set Differential Current Protection Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandAlarm A Signal: Pickup System Phase AAlarm B Signal: Pickup System Phase BAlarm C Signal: Pickup System CPickup Signal: PickupTrip A Signal: Trip System Phase ATrip B Signal: Trip System Phase BTrip C Signal: Trip System Phase CTrip Signal: TripTripCmd Signal: Trip Command

87 GD - Restricted Ground Fault ProtectionElements87GD[1] ,87GD[2]

This protective element protects the wye-side of transformers against ground faults that are close to the neutral.

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DescriptionThis protection principle is based on a restricted ground fault scheme that only can be used in systems with an earthed neutral. The ground differential current is the vector difference of the measured earth current and the calculated zero sequence current from three measured phase currents. Similarly to the phase restrained differential protection, the ground restraining current is the vector sum of the measured earth current and the calculated zero sequence current from three measured phase currents. The trip characteristic is very much similar to the phase restrained differential protection and it does not have the temporary restraining.

The accuracy of the zero current Io determination depends significantly on the tolerances of the phase current CT. This correspondingly applies to the Holmgreen Connection for measuring the earth current lG (instead by using the Toroidal-type CT), but because of its higher accuracy the Toroidal CT is to be preferred to the use of the Holmgreen Connection.

The trip commands generated by the protective function restricted ground fault 87GD have to be assigned within the Breaker Manager.

Please be aware that the protective function Restricted Ground Fault 87GD solely can be applied to the winding end which builds the earthed neutral point.

Device Planning Parameters of the Restricted Ground Fault Protection




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yD

Protected ZoneA

B

C

IB

IC

IA

Protective Relay

IM02602013E ETR-5000

Global Protection Parameters of the Restricted Ground Fault Protection


CT Winding Side


W1, W2

87GD[1]: W187GD[2]: W2

[Protection Para/Global Prot Para/Tdiff-Prot/87GD[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Tdiff-Prot/87GD[1]]





Setting Group Parameters of the Restricted Ground Fault Protection



Inactive, Active

Inactive [Protection Para/<1..4>/Tdiff-Prot/87GD[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


IdG min Constant minimum pickup current (differential current).

0.05 – 1.00 Ib 0.05 Ib [Protection Para/<1..4>/Tdiff-Prot/87GD[1]]

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IdG(Ir0) Starting point of the static tripping characteristic when Ir = 0


IdG(Ir1) Breaking point of the static tripping characteristic when Ir = 2 x Ib


IdG(Ir2) Value of the static tripping characteristic when Ir = 10 x Ib


Restricted Ground Fault Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Tdiff-Prot/87GD[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Tdiff-Prot/87GD[1]]


[Protection Para/Global Prot Para/Tdiff-Prot/87GD[1]]

Restricted Ground Fault Protection Module Signals (Output States)

Name Description


87GDH - High Set Restricted Ground Fault ProtectionElements87GDH[1] ,87GDH[2]

Similar to the unrestrained phase differential protection, unrestrained ground differential protection functions are provided for a high ground differential current.

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Unstabilized High Set Differential Protection Step 87GDH

Device Planning Parameters of the High Set Restricted Ground Fault Protection Module




Global Protection Parameters of the High Set Restricted Ground Fault Protection Module


CT Winding Side


W1, W2

87GDH[1]: W187GDH[2]: W2

[Protection Para/Global Prot Para/Tdiff-Prot/87GDH[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Tdiff-Prot/87GDH[1]]

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IdG/Ib

Ir/IbIr1= 2 x Ib

IdG[Ir2]

87GDH

IdG[Ir1]

IdG[Ir0]

Trip Range

Operating Range

Ir2= 10 x Ib

High-Set / Unrestrained Restricted Ground Fault:

Pickup value of the ground differential current based

on the rated current.

IdG minSlope1

Slope2

ETR-5000 IM02602013E






Setting Group Parameters of the High Set Restricted Ground Fault Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/Tdiff-Prot/87GDH[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


IdG>> High-Set / Unrestrained Restricted Ground Fault: Pickup value of the ground differential current based on the rated current.

2.00 – 20.00 Ib 2.00 Ib [Protection Para/<1..4>/Tdiff-Prot/87GDH[1]]

High Set Restricted Ground Fault Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Tdiff-Prot/87GDH[1]]

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ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Tdiff-Prot/87GDH[1]]


[Protection Para/Global Prot Para/Tdiff-Prot/87GDH[1]]

High Set Restricted Ground Fault Signals (Output States)

Name Description


87GD

Phase Current Differential Protection Module Values


IrG W1 Measured Value (Calculated): Ground Restraint Current Winding 1

[Operation/Measured Values/87GD W1]

IdG W1 Measured Value (Calculated): Ground Differential Current Winding 1


IrG W2 Measured Value (Calculated): Ground Restraint Current Winding 2


IdG W2 Measured Value (Calculated): Ground Differential Current Winding 2


Phase Current Differential Protection Module Statistics


IrG W1 max Measured Value (Calculated): Ground Restraint Current Winding 1 Maximum Value

[Operation/Statistics/Max/87GD W1]

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IdG W1 max Measured Value (Calculated): Ground Differential Current Winding 1 Maximum Value


IrG W2 max Measured Value (Calculated): Ground Restraint Current Winding 2 Maximum Value


IdG W2 max Measured Value (Calculated): Ground Differential Current Winding 2 Maximum Value


Directional Feature – Phase CurrentAll elements can be selected as »Non-directional/Forward/Reverse« operated. This has to be done in the »Device Planning« menu.

For the direction detection it is mandatory, that the required voltages exceed 0.35 V and the required currents exceed 10 mA.

For the case, that the voltage drops below 0.35 V, the last angle between the operating and polarizing quantity will be used for the directional detection.

Overcurrent protection elements, time inverse or instantaneous or time delay, etc, can trip in a specified fault current direction. When the trip direction is set to »Non-directional«, the directon detection takes no effect. When it is set to »Forward«, a trip is only permitted in the forward direction where fault current lies within ± 90° around the maximum torque angle »Phase MTA«. When it is set to »Reverse«, a trip is only permitted in reverse direction where fault current lies within ± 90° around the opposite of the maximum torque angle.

In the case of a 3-phase nearly zero voltage fault, the memorized voltage, or prefault voltages, is used to establish the correct fault direction.

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Prot

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ETR-5000 IM02602013E

Phase Directional Supervision Logic

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Non

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IM02602013E ETR-5000

50P/67P- DEFT Overcurrent ProtectionAvailable Elements50P[1] ,50P[2] ,50P[3] ,50P[4]

If using inrush blockings, the tripping delay of the current protection functions must be at least 30 ms or more in order to prevent faulty trippings (applies only to devices which are equipped with Inrush protection).

All overcurrent protective elements are identically structured.

All ANSI 67 elements (directional overcurrent protection), will be displayed as ANSI 50 elements. That means, that the name of an ANSI 50 element wont change, if it is set within the device planning from “non-directional” to “directional”.

For each element the following characteristic is available:

• DEFT (definite time).

Explanation

This element offers a criterion setting. The criterion setting tells if the threshold is based on the fundamental (Phasor) or RMS.

For Tripping curves, please refer to the “Appendix/Instantaneous Current Curves (Phase)” section.

370 www.eaton.com

t = Tripping delay

I = Fault current

Pickup = If the pickup value is exceeded, the module/element starts to time out to trip .

ETR-5000 IM02602013E

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50P/

67P[

1]...

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Nam

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IM02602013E ETR-5000

Device Planning Parameters of the 50P/67P Module


Mode Mode Non-directional, Forward, Reverse

Non-directional [Device Planning]

Global Protection Parameters of the 50P/67P Module


CT Winding Side


W1, W2

50P[1]: W150P[2]: W150P[3]: W250P[4]: W2

[Protection Para/Global Prot Para/I-Prot/50P[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/I-Prot/50P[1]]





Rvs Blo Reverse Blocking, if Reverse Blocking is activated (allowed) within a parameter set and if the state of the assigned signal is true.


AdaptSet 1 Assignment Adaptive Parameter 1 AdaptSet -.- [Protection Para/Global Prot Para/I-Prot/50P[1]]




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Setting Group Parameters of the 50P/67P Module



Inactive, Active

50P[1]: Active50P[2]: Inactive50P[3]: Inactive50P[4]: Inactive

[Protection Para/<1..4>/I-Prot/50P[1]]


Inactive, Active

Inactive [Protection Para/<1..4>/I-Prot/50P[1]]

Rvs Blo Fc Activate (allow) or inactivate (disallow) reverse blocking of the module/element. This parameter is only effective if a signal is assigned to the corresponding global protection parameter. If the signal becomes true, those modules/element are blocked that are configured "Rvs Blo Fc = active".

Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


Criterion Measuring method: fundamental or RMS Fundamental, True RMS

True RMS [Protection Para/<1..4>/I-Prot/50P[1]]

Pickup

If the pickup value is exceeded, the module/element starts to time out to trip.

Only available if: Characteristic = DEFT Or Characteristic = INV Minimum of the setting range If: VRestraint = Active Minimum of the setting range If: VRestraint = Inactive

0.02 – 40.00 In 50P[1]: 2 In50P[2]: 2.5 In50P[3]: 2.0 In50P[4]: 2.5 In


t

Tripping delay

Only available if: Characteristic = DEFT

0.00 – 300.00 s 50P[1]: 0 s50P[2]: 0.25 s50P[3]: 0.25 s50P[4]: 0.25 s


IH2 Blo

Blocking the trip command, if an inrush is detected.

Inactive, Active


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50P/67P Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/I-Prot/50P[1]]




Rvs Blo-I Module Input State: Reverse Blocking [Protection Para/Global Prot Para/I-Prot/50P[1]]

AdaptSet1-I Module Input State: Adaptive Parameter1 [Protection Para/Global Prot Para/I-Prot/50P[1]]




50P/67P Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandIH2 Blo Signal: Blocking the trip command by IH2Pickup IA Signal: Pickup IAPickup IB Signal: Pickup IBPickup IC Signal: Pickup ICPickup Signal: Pickup

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ETR-5000 IM02602013E

Name Description

Trip Phase A Signal: General Trip Phase ATrip Phase B Signal: General Trip Phase BTrip Phase C Signal: General Trip Phase CTrip Signal: TripTripCmd Signal: Trip CommandActive AdaptSet Active Adaptive ParameterDefaultSet Signal: Default Parameter SetAdaptSet 1 Signal: Adaptive Parameter 1AdaptSet 2 Signal: Adaptive Parameter 2AdaptSet 3 Signal: Adaptive Parameter 3AdaptSet 4 Signal: Adaptive Parameter 4

Commissioning: Overcurrent Protection, directional [ANSI 50P/67P]

Object to be tested:

•For each directional overcurrent element is to be measured: the total tripping time (recommendation) or alternatively tripping delays and the dropout ratios; each time 3 x single-phase and 1 x three-phase.

Especially in Holmgreen connections, wiring errors can happen easily and these are then detected safely. By measuring the total tripping time, it can be ensured that the secondary wiring is OK (from the terminal on, up to the trip coil of the Breaker).

Eaton recommends measuring the total tripping time instead of the tripping delay. The tripping delay should be specified by the User. The total tripping time is measured at the position signaling contact of the breaker (not at the relay output contacts!).

Total tripping time = tripping delay (please refer to the tolerances of the protection elements) + breaker operating time (about 50 ms)

Please take the breaker operating times from the technical data specified in the relevant documentation provided by the breaker manufacturer.

Necessary means• Synchronizable current and voltage sources• Optional: ampere meters• Timer

Procedure

Synchronize the 3-phase current and voltage sources with each other. Then simulate the tripping directions to be tested by the angle between current and voltage.

Testing the threshold values (3 x single-phase and 1 x three-phase)

Each time feed a current which is about 3-5% above the threshold value for activation/tripping. Check then the

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IM02602013E ETR-5000

threshold values.

Testing the total tripping delay (recommendation)

Measure the total tripping times at the auxiliary contacts of the Brk (Brk tripping).

Testing the trip delay (measured at the relay output)

Measure the tripping times at the relay output.

Testing the dropout ratio

Reduce the current to 97% below the trip value and check the dropout ratio.

Successful test result

The measured total tripping delays or individual tripping delays, threshold values and dropout ratios correspond with those values, specified in the adjustment list. Permissible deviations/tolerances can be found under Technical Data.

51P/67P - INV Overcurrent-ProtectionAvailable Elements 51P[3] ,51P[4]

If using inrush blockings, the tripping delay of the current protection functions must be at least 30 ms or more in order to prevent faulty trippings (applies only to devices which are equipped with Inrush protection).

All overcurrent protective elements are identically structured.


For each element, the following characteristics are available:

• NINV (IEC/XInv);• VINV (IEC/XInv);• LINV (IEC/XInv);• EINV (IEC/XInv);• MINV (ANSI/XInv);• VINV (ANSI/XInv);• EINV (ANSI/XInv);• Thermal Flat;• Therm Flat IT;• Therm Flat I2T; and• Therm Flat I4T.

For tripping curves please refer to the “Appendix/Time Current Curves (PHASE)” section.

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378 www.eaton.com

Fund

.

RM

S

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IH2.

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AND

AND

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1516b

17b

18b

24b

25b

26b

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ETR-5000 IM02602013E

Device Planning Parameters of the 51P/67P Module


Mode Mode 51P[3]: Non-directional, Forward, Reverse51P[4]: Do not use, Non-directional, Forward, Reverse


Global Protection Parameters of the 51P/67P Module


CT Winding Side


W1, W2

W2 [Protection Para/Global Prot Para/I-Prot/51P[3]]













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Setting Group Parameters of the 51P/67P Module



Inactive, Active

51P[3]: Active51P[4]: Inactive



Inactive, Active



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active




Pickup


Minimum of the setting range If: VRestraint = Active Minimum of the setting range If: VRestraint = Inactive

0.02 – 40.00 In 1.00 In [Protection Para/<1..4>/I-Prot/51P[3]]

Curve Shape

Characteristic IEC NINV, IEC VINV, IEC EINV, IEC LINV, ANSI MINV, ANSI VINV, ANSI EINV, Therm Flat, IT, I2T, I4T

ANSI MINV [Protection Para/<1..4>/I-Prot/51P[3]]

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t-multiplier

Time multiplier/tripping characteristic factor. The setting range depends on the selected tripping curve.

0.02 - 20.00 51P[3]: 1.051P[4]: 2.0


Reset Mode

Reset Mode Instantaneous, t-delay, Calculated

Calculated [Protection Para/<1..4>/I-Prot/51P[3]]

t-reset

Reset time for intermittent phase failures (INV characteristics only)

Available if:Reset Mode = t-delay

0.00 – 60.00 s 0 s [Protection Para/<1..4>/I-Prot/51P[3]]

IH2 Blo


Inactive, Active


VRestraint

Voltage Restraint Protection Inactive, Active


VRestraint max

Maximum voltage restraint level. Definition of Vn: Vn is dependent on the System Parameter setting of "Main VT con". When the System Parameters "Main VT con" is set to "Open-Delta" , "Vn = Main VT sec ". When the System Parameters "Main VT con" is set to "Wye", "Vn = Main VT sec/SQRT(3)".

Only available if: VRestraint = Active

0.04 – 1.30 Vn 1.00 Vn [Protection Para/<1..4>/I-Prot/51P[3]]

LOP Blo

Measuring Circuit Supervision


Inactive, Active


51P/67P Module Input States






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51P/67P Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandIH2 Blo Signal: Blocking the trip command by IH2Pickup IA Signal: Pickup IAPickup IB Signal: Pickup IBPickup IC Signal: Pickup ICPickup Signal: PickupTrip Phase A Signal: General Trip Phase ATrip Phase B Signal: General Trip Phase BTrip Phase C Signal: General Trip Phase CTrip Signal: TripTripCmd Signal: Trip CommandActive AdaptSet Active Adaptive ParameterDefaultSet Signal: Default Parameter SetAdaptSet 1 Signal: Adaptive Parameter 1AdaptSet 2 Signal: Adaptive Parameter 2AdaptSet 3 Signal: Adaptive Parameter 3

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Name Description

AdaptSet 4 Signal: Adaptive Parameter 4

Commissioning: Overcurrent Protection, Non-directional [ANSI 51P/67P]


• For each directional overcurrent element is to be measured: the total tripping time (recommendation) or alternatively tripping delays and the dropout ratios; each time 3 x single-phase and 1 x three-phase.

Especially in Holmgreen connections, wiring errors can happen easily and these are then detected safely. By measuring the total tripping time, it can be ensured that the secondary wiring is OK (from the terminal on, up to the trip coil of the Breaker).

Eaton recommends measuring the total tripping time instead of the tripping delay. The tripping delay should be specified by the User. The total tripping time is measured at the position signaling contact of the breaker (not at the relay output contacts!).

Total tripping time = tripping delay (please refer to the tolerances of the protection elements) + breaker operating time (about 50 ms)


Necessary means• Synchronizable current and voltage sources• Optional: ampere meters • Timer

Procedure

Synchronize the 3-phase current and voltage sources with each other. Then simulate the tripping directions to be tested by the angle between current and voltage.

Testing the threshold values (3 x single-phase and 1 x three-phase)Each time feed a current which is about 3-5% above the threshold value for activation/tripping. Check then the threshold values.

Testing the total tripping delay (recommendation)Measure the total tripping times at the auxiliary contacts of the Brk (Brk tripping).

Testing the trip delay (measured at the relay output)Measure the tripping times at the relay output.

Testing the dropout ratioReduce the current to 97% below the trip value and check the dropout ratio.

Successful test resultThe measured total tripping delays or individual tripping delays, threshold values and dropout ratios correspond with those values, specified in the adjustment list. Permissible deviations/tolerances can be found under Technical Data.

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IM02602013E ETR-5000

51V – Voltage Restraint Overcurrent-Protection

The 51P[2] and 51P[3] elements can be used for Voltage Restraint if the Parameter »VRestraint« is set to »active« within the Parameter Set.

51P[1] ,51P[2]

All voltage restraint overcurrent protective elements are identically structured.


The 51V element restrains operation which reduces pickup levels. This allows the User to lower the pickup value of the 51V elements with the corresponding phase input voltage (phase-to-phase or phase-to-ground, depending on the setting of »Main VT con« within the System Parameters). When the minimum fault phase current is close to the load current, it may make the phase time overcurrent protection coordination difficult. In this case, an undervoltage function may be used to alleviate this situation. When the voltage (RMS) is low, the phase time overcurrent pickup threshold may be set low accordingly, so that the phase time overcurrent protection may achieve adequate sensitivity and better coordination. The device uses a simple linear model to determine the effective pickup by characterizing the relationship between the voltage and the phase time overcurrent pickup threshold.

Once the voltage restraint is activated, the effective phase time overcurrent pickup threshold will be the calculated Pickup% times the phase time overcurrent pickup setting. The effective pickup threshold must be within the setting range allowed and, if it is less, the minimum pickup value will be used.

That means:Vmin = 0.25*Vmax;• Pickup%min = 25%;• Pickup% = 25%, if V <= Vmin;• Pickup% = 1/Vmax*(V - Vmin) + 25%, if Vmin < V < Vmax;

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Pickup%

VRestraint max25% VRestraint max

25%

100%

V

ETR-5000 IM02602013E

• Pickup% = 100%, if V >= Vmax;

For tripping curves, please refer to the“Appendix/Instantaneous Current Curves (Phase)” section.

If this element should be blocked in case of a Loss Of Potential, »LOP BLO« has to be set to »active«.

Definition of Vn: Vn is dependent on the System Parameter setting of "Main VT con".

In case that within the System Parameters "Main VT con" is set to "Open-Delta":

Vn=Main VT sec .

In case that "Main VT con" is set to "Wye":

Vn= MainVT sec3

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Device Planning Parameters of the 51V Module


Mode Mode 51P[1]: Non-directional, Forward, Reverse51P[2]: Do not use, Non-directional, Forward, Reverse


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Name.TripCmd

Name.Pickup IA

Name.Pickup IB

Name.Pickup IC

Name.Trip

IH2.Blo Phase A

IH2.Blo Phase B

IH2.Blo Phase C

Please Refer to Diagram: Blockings**

51V Pickup = %Pickup * 51P

Pickup

IA

IB

IC

AND

AND

AND

Name.Trip Phase A

Name.Trip Phase B

Name.Trip Phase C

Name.Pickup

Please Refer to Diagram: Trip Blockings

Inactive

Active

Name.IH2 Blo

(Element is not deactivated and no active blocking signals )

AND

AND

AND

Name.IH2 Blo*

Imax

(Tripping command deactivated or blocked . )

5

6

7

4

3

Please Refer to Diagram: IH2*



15

16b

17b

18b

24b

25b

26b

14

OROR

AND

AND

AND

AND

AND

φINV

Imax

Name.t-reset

Name.t-multiplier

Name.Curve Shape

Name.Reset Mode

Based on above parameters , tripping times and reset modes will be calculated by the device .

51V[1]...[n]

Name = 51V[1]...[n]

*=Applies only to devices that offer Inrush P

rotection

VA

VB

VC

φ

Pickup%

25%

100%

V

25%

VRestraint max

%Pickup

RMS

RMS

RMS

RMS

RMS

RMS

38a

Inactive

Name.LOP Blo

Active

AND

ETR-5000 IM02602013E

Global Protection Parameters of the 51V Module


CT Winding Side


W1, W2

W1 [Protection Para/Global Prot Para/I-Prot/51P[1]]













Setting Group Parameters of the 51V Module

In the case that Voltage Restraint is active (Vrestraint=active), the minimum pickup that can be set is 0.1 In.

In the case that Voltage Restraint is inactive (Vrestraint=inactive), the minimum pickup that can be set is 0.01 In.

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IM02602013E ETR-5000



Inactive, Active

51P[1]: Active51P[2]: Inactive



Inactive, Active



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active




Pickup



0.02 – 40.00 In 1.00 In [Protection Para/<1..4>/I-Prot/51P[1]]

Curve Shape


ANSI MINV [Protection Para/<1..4>/I-Prot/51P[1]]

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ETR-5000 IM02602013E


t-multiplier


0.02 - 20.00 51P[1]: 151P[2]: 2


Reset Mode


Calculated [Protection Para/<1..4>/I-Prot/51P[1]]

t-reset



0.00 – 60.00 s 0 s [Protection Para/<1..4>/I-Prot/51P[1]]

IH2 Blo


Inactive, Active


VRestraint


Active [Protection Para/<1..4>/I-Prot/51P[1]]

VRestraint max



0.04 – 1.30 Vn 1.00 Vn [Protection Para/<1..4>/I-Prot/51P[1]]

LOP Blo



Inactive, Active


51V Module Input States






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51V Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandIH2 Blo Signal: Blocking the trip command by IH2Pickup IA Signal: Pickup IAPickup IB Signal: Pickup IBPickup IC Signal: Pickup ICPickup Signal: PickupTrip Phase A Signal: General Trip Phase ATrip Phase B Signal: General Trip Phase BTrip Phase C Signal: General Trip Phase CTrip Signal: TripTripCmd Signal: Trip CommandActive AdaptSet Active Adaptive ParameterDefaultSet Signal: Default Parameter SetAdaptSet 1 Signal: Adaptive Parameter 1AdaptSet 2 Signal: Adaptive Parameter 2AdaptSet 3 Signal: Adaptive Parameter 3

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Name Description

AdaptSet 4 Signal: Adaptive Parameter 4

Commissioning: Voltage Restraint [ANSI 51V]


Signals to be measured for Voltage Restraint element: the threshold values, total tripping time (recommended), or alternatively tripping delays and the dropout ratios; each time 3 x single-phase and 1 x three-phase.

Eaton recommends measuring the total tripping time instead of the tripping delay. The tripping delay should be specified by the customer. The total tripping time is measured at the position signaling contact of the breaker (not at the relay output contacts!).

Total tripping time = tripping delay (please refer to the tolerances of the protection stages)+ breaker operating time (about 50 ms)


Necessary means:

• Current source;• Voltage Source;• Current and Voltage meters; and• Timer.

Procedure:

Testing the threshold values (3 x single-phase and 1 x three-phase)Feed %Pickup voltage. For each test performed, feed a current that is about 3-5% above the threshold value for activation/tripping. Then check if the pickup values are %Pickup of the value according to 51P protection.

Testing the total tripping delay (recommendation)Measure the total tripping times at the auxiliary contacts of the breakers (breaker tripping).

Testing the tripping delay (measuring at the relay output contact)Measure the tripping times at the relay output contact.


Successful test resultThe measured total tripping delays or individual tripping delays, threshold values, and dropout ratios correspond with those values specified in the adjustment list. Permissible deviations/tolerances can be found under Technical Data.

51Q - Negative-Sequence Overcurrent Protection

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Elements51Q[1] ,51Q[2]

The negative-sequence overcurrent element (51Q) is to be seen as an equivalent to the phase overcurrent protection (51P) with the exception that it uses negative-sequence current (I2) as measured quantities instead of the three phase currents used by phase overcurrent elements. The negative-sequence current used by 51Q is derived from the following well-known symmetrical component transformation:

I 2=13 I Aa2 I Ba I C

The pickup set value of a 51Q element should be set in accordance of the negative-sequence current occurrence in the protected object.

Besides that, the negative-sequence overcurrent element (51Q) uses the same setting parameters as the phase overcurrent elements (51P), like trip and reset characteristics from both IEC/ANSI standards, time multiplier, etc.

The negative-sequence overcurrent element (51Q) can be used by line, generator, transformer and motor protection to protect the system from unbalanced faults. Because the 51Q element operates on the negative-sequence current component which is normally absent during load conditions, the 51Q can, therefore, be set more sensitive than the phase overcurrent elements (51P). On the other hand, coordination of negative-sequence overcurrent elements in a radial system does not mean automatically very long fault clearing time for the furthest upstream protection devices, because the tripping time of concerned negative-sequence overcurrent element needs only be coordinate with the next downstream device with the negative-sequence overcurrent element. This makes the 51Q in many cases as an advantageous protection concept in addition to the phase overcurrent elements.

If you are using inrush blockings, the tripping delay of the current protection functions must be at least 30 ms or more in order to prevent faulty trippings.

All elements are identically structured.

For each element, the following characteristics are available:

• NINV (IEC/XInv)• VINV (IEC/XInv)• LINV (IEC/XInv)• EINV (IEC/XInv)• MINV (ANSI/XInv)• VINV (ANSI/XInv)• EINV (ANSI/XInv)• Thermal Flat• Therm Flat IT• Therm Flat I2T• Therm Flat I4T

For Tripping curves please refer to Chapter “Appendix/Instantaneous Current Curves (I2)”.

At the moment of breaker closure, negative-sequence current might be the result of transients.

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Device Planning Parameters of the 51Q Module


Mode Mode Do not use, Non-directional

Non-directional

[Device Plan-ning]

www.eaton.com 393

Nam

e.Tr

ipCm

dNam

e.Tr

ip

Plea

se R

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to D

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am: B

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IH2.

IH2

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Nam

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AND

Nam

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Nam

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5

4 3

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AND

AND

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I251Q

[1]..

.[n]

Nam

e =

51Q

[1]..

.[n]

φ INV

Nam

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Nam

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67

IM02602013E ETR-5000

Global Protection Parameters of the 51Q Module


CT Winding Side


W1, W2

51Q[1]: W151Q[2]: W2

[Protection Para/Global Prot Para/I-Prot/51Q[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/I-Prot/51Q[1]]







AdaptSet 1 Assignment Adaptive Parameter 1 AdaptSet -.- [Protection Para/Global Prot Para/I-Prot/51Q[1]]




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Setting Group Parameters of the 51Q Module



Inactive, Active

Active [Protection Para/<1..4>/I-Prot/51Q[1]]


Inactive, Active

Inactive [Protection Para/<1..4>/I-Prot/51Q[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


Pickup



0.02 – 40.00 In 1.00 In [Protection Para/<1..4>/I-Prot/51Q[1]]

Curve Shape Characteristic IEC NINV, IEC VINV, IEC EINV, IEC LINV, ANSI MINV, ANSI VINV, ANSI EINV, Therm Flat, IT, I2T, I4T

ANSI MINV [Protection Para/<1..4>/I-Prot/51Q[1]]

t-multiplier Time multiplier/tripping characteristic factor. The setting range depends on the selected tripping curve.

0.02 - 20.00 1.0 [Protection Para/<1..4>/I-Prot/51Q[1]]

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Reset Mode


Calculated [Protection Para/<1..4>/I-Prot/51Q[1]]

t-reset



0.00 – 60.00 s 0 s [Protection Para/<1..4>/I-Prot/51Q[1]]

IH2 Blo


Inactive, Active


VRestraint



VRestraint max



0.04 – 2.00 Vn 1.00 Vn [Protection Para/<1..4>/I-Prot/51Q[1]]

LOP Blo



Inactive, Active


51Q Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/I-Prot/51Q[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/I-Prot/51Q[1]]


[Protection Para/Global Prot Para/I-Prot/51Q[1]]

Rvs Blo-I Module Input State: Reverse Blocking [Protection Para/Global Prot Para/I-Prot/51Q[1]]

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AdaptSet1-I Module Input State: Adaptive Parameter1 [Protection Para/Global Prot Para/I-Prot/51Q[1]]




51Q Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandIH2 Blo Signal: Blocking the trip command by IH2Pickup Signal: PickupTrip Signal: TripTripCmd Signal: Trip CommandActive AdaptSet Active Adaptive ParameterDefaultSet Signal: Default Parameter SetAdaptSet 1 Signal: Adaptive Parameter 1AdaptSet 2 Signal: Adaptive Parameter 2AdaptSet 3 Signal: Adaptive Parameter 3AdaptSet 4 Signal: Adaptive Parameter 4

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IM02602013E ETR-5000

Commissioning: Negative Sequence Overcurrent [51Q]

Object to be tested

• Signals to be measured for each current protection element: the threshold values, total tripping time (recommended), or alternatively tripping delays and the dropout ratios.

Eaton recommends measuring the total tripping time instead of the tripping delay. The tripping delay should be specified by the customer. The total tripping time is measured at the position signaling contact of the breaker (not at the relay output contacts!).

Total tripping time = tripping delay (please refer to the tolerances of the protection stages) + breaker operating time (about 50 ms)


Necessary means:• Current source• Current meters• Timer

Procedure:

Testing the threshold valuesIn order to get a negative-sequence current, please change the phase sequence at the terminals of the current source (in case of ABC sequence to ACB – in case of a ACB sequence to ABC).

For each test performed, feed a current that is about 3-5% above the threshold value for activation/tripping. Then check the threshold values.

Testing the total tripping delay (recommendation)Measure the total tripping times at the auxiliary contacts of the breakers (breaker tripping).

Testing the tripping delay (measuring at the relay output contact)Measure the tripping times at the relay output contact.


Successful test resultThe measured total tripping delays or individual tripping delays, threshold values, and dropout ratios correspond with those values specified in the adjustment list. Permissible deviations/tolerances can be found under Technical Data.

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ETR-5000 IM02602013E

IH2 – Inrush BlockingElementsIH2[1] ,IH2[2]


The magnetizing current may have a significant amount of harmonics when energizing an unloaded transformer, in particular, 2nd harmonics. The IH2 module (harmonic blocking) uses a percentage of the 2nd harmonics over its fundamental to generate general or phase-based blocking signals for other protection functions use.

There are two blocking modes.

• If 1-phase block mode is selected, the module will only generate the blocking signals for those phases whose 2nd harmonic percentages exceed their threshold respectively.

• If 3-phase mode is selected, the module will generate the blocking signals for all three phases as long as the 2nd harmonic percentage in one or more phases exceeds their threshold.

Note that the 2nd harmonic percentage in IX shares the same threshold as other phases but it will not be controlled by the blocking mode.

www.eaton.com 399

IM02602013E ETR-5000

400 www.eaton.com

AND

1-ph

Blo

IH2.

Bloc

k M

ode

3-ph

Blo

IH2.

IH2

/ IH

1

IA IB IC

AND

AND

AND

IH2.

Activ

e

IH2.

Blo

Phas

e B

IH2.

Blo

Pha

se C

IH2.

Blo

Pha

se A

IH2

IH1

IH2

IH1

IH2

IH1

IH2

IXIG

H1

IGH

2

AND

IH2.

Blo

IG

IH2.

3-ph

Blo

4

5 6 7 8

Plea

se R

efer

to D

iagr

am: B

lock

ings

OR

OR OR

OR

IH2

IH1

IH2

IH1

IH2

IH1

IGH2

IGH

1

ETR-5000 IM02602013E

Device Planning Parameters of the IH2 Module




Global Protection Parameters of the IH2 module


CT Winding Side


IH2[1]: W1IH2[2]: W2

IH2[1]: W1IH2[2]: W2

[Protection Para/Global Prot Para/I-Prot/IH2[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/I-Prot/IH2[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/I-Prot/IH2[1]]

Setting Group Parameters of the IH2 Module



Inactive, Active

Inactive [Protection Para/<1..4>/I-Prot/IH2[1]]


Inactive, Active

Inactive [Protection Para/<1..4>/I-Prot/IH2[1]]

IH2 / IH1 Maximum permissible percentage of the 2nd harmonic over the fundamental.

10 - 40% 15% [Protection Para/<1..4>/I-Prot/IH2[1]]

Block Mode 1-ph Blo: If an inrush is detected in one phase, the corresponding phase of those modules will be blocked, where inrush blocking is set to active./3-ph Blo: If an inrush is detected in at least one phase, all three phases of those modules where inrush blocking is set to active will be blocked (cross blocking).

1-ph Blo, 3-ph Blo

1-ph Blo [Protection Para/<1..4>/I-Prot/IH2[1]]

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IM02602013E ETR-5000

Inrush Module IH2 States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/I-Prot/IH2[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/I-Prot/IH2[1]]

IH2 Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo Phase A Signal: Blocked Phase ABlo Phase B Signal: Blocked Phase BBlo Phase C Signal: Blocked Phase CBlo IG meas Signal: Blocking of the ground protection module (measured

ground current)Blo IG calc Signal: Blocking of the ground protection module (calculated

ground current)3-ph Blo Signal: Inrush was detected in at least one phase - trip command

blocked.

Commissioning: IH2

Dependent on the configured IH2 module blocking mode (»1-ph Blo or 3-ph Blo«), the test procedure is different.

For mode »1-ph-Blo«, the test has to be carried out first for each individual phase and then for all three phases together.

For mode »3-ph-Blo«, the test is a three-phase test.

Object to be tested:Test of the IH2 module harmonic blocking.

Necessary means:• Three-phase current source with adjustable frequency; and• Three-phase current source (for the fundamental harmonic).

Procedure (dependent on the configured blocking mode):

• Feed the current to the secondary side with nominal frequency.

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ETR-5000 IM02602013E

• Abruptly feed current to the secondary side with double nominal frequency. The amplitude must exceed the pre-set ratio/threshold »IH2/IN«.

• Ascertain that the signal »IH2 ALARM« is now generated.

Successful test results:The signal »IH2 ALARM« is generated and the event recorder indicates the blocking of the current protection element.

Directional Features for Measured (IX) Ground Fault Elements 50X/51XAll ground fault elements can be selected as »Non-directional/Forward/Reverse« operated. This has to be done in the »Device Planning« menu.

For the direction detection, it is mandatory that the required voltages exceed 0.35 V and the required currents exceed 10 mA. An exception is the measured sensitive ground current which has to exceed 1 mA.

Important Definitions

Polarizing Quantity: This is the quantity that is used as a reference value. The polarizing quantity can be selected by the parameter »IX Direction Control« in the [System Para/Direction] menu as follows:

• »IX 3V0«: The neutral voltage selected by the parameter »3V0 Source« will be used as the polarizing quantity. The traditional way to polarize a ground fault element is to use neutral voltage (3V0). The neutral voltage can, however, be either »measured« or »calculated«. This can be selected by the parameter »3V0 Source« in the [System Para/Direction] menu.

• »IX Neg«: With this selection, the negative phase sequence voltage and current (Polarizing: V2/Operating: I2) will be used to detect direction. The monitored current is still the measured residual current IX.

• »IX Dual«: For this method, the negative phase sequence voltage »V2« will be used as polarizing quantity if »V2« and »I2« are available, otherwise 3V0 will be used. The operating quantity is either I2 if »V2« and »I2« are available, else IX.

The following table gives the User a quick overview of the all possible directional settings.50X/51X Direction Decision

by Angle Between: [System Para/ Direction]

The Following Angle Has to Be Set:


IX Dir Cntrl =


3V0 Source =

Measured ground current and neutral voltage:IX, 3V0 (measured)

Ground MTA IX 3V0 Measured

Measured ground current and neutral voltage:IX, 3V0 (calculated)

Ground MTA IX 3V0 Calculated


90° + Phase MTA IX Neg N.A.

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IM02602013E ETR-5000


[System Para/ Direction]



IX Dir Cntrl =


3V0 Source =

Negative phase sequence current and voltage (preferred), measured ground current and neutral voltage (alternatively):I2, V2 (if available)or else:IX, 3V0 (measured)

If V2 and I2 are available: 90° + Phase MTA

else:

Ground MTA

IX Dual Measured

Negative phase sequence current and voltage (preferred), measured ground current and neutral voltage (alternatively):I2, V2 (if available)or else:IX, 3V0 (calculated)

If V2 and I2 are available: 90° + Phase MTA

else:

Ground MTA

IX Dual Calculated

404 www.eaton.com

ETR-5000 IM02602013E

www.eaton.com 405

50X/

51X

-Dire

ctio

n D

etec

tion

Prot

.IX d

ir n

poss

Prot

.IX d

ir re

v

Prot

.IX d

ir fw

d(F

orw

ard)

(Rev

erse

)

(Not

pos

sibl

e)

10b

10b

Pro

t -50

X/5

1X -

Dire

ctio

n D

etec

tion

10b

Mea

sure

d

3V0

Sour

ce

Syst

em P

ara

Cal

cula

ted

VR c

alc

VX m

eas

IX 3

V0

IX N

eg

IX D

ir Cn

trl

IX D

ual

3V0

3V0

If V2

and

I2 a

re a

vaila

ble,

I2 is

the

oper

atin

g qu

antit

y, e

lse IX

is th

e op

erat

ing

quan

tity

V2

IG =

IX m

eas 90

° + P

hase

MTA

Gro

und

MTA

Syst

em P

ara

Syst

em P

ara

If V2

and

I2 a

re a

vaila

ble,

MTA

= 9

0° +

P

hase

MTA

, oth

erw

ise

MTA

= G

roun

d M

TA

Rev

erse

Forw

ard

pola

rizin

g

MTA

pola

rizin

gop

erat

ing

oper

ating

V2*

I2

*=Pr

iorit

y if

avai

labl

e.

IM02602013E ETR-5000

50X/67X DEFT Measured Ground Fault ProtectionElements50X[1] ,50X[2]

If using inrush blockings, the tripping delay of the ground current protection functions must be at least 30 ms or more in order to prevent faulty trippings.

All ground current elements are identically structured.

The following table shows the application options of the earth overcurrent protection element

Applications of the IG-Protection Module Setting in Option

ANSI 50X – Ground overcurrent protection, non-directional

Device Planning menuSetting: Non-directional

Measuring Mode: Fundamental/TrueRMS

ANSI 67X – Ground overcurrent protection, directional

Device Planning menuSetting: Forward/Reverse

Measuring Mode: Fundamental/TrueRMSVX Selection: measured/calculated

CriterionFor all protection elements it can be determined, whether the measurement is done on basis of the »Fundamental« or if »TrueRMS« measurement is used.

VX SelectionWithin the parameter menu, this parameter determines, whether the earth current and the residual voltage is »measured« or »calculated«.

Calculation is only possible, when phase to neutral voltage is applied to the voltage inputs.

At setting »measured« the quantities to be measured, i. e. Residual voltage and the measured ground current have to be applied to the corresponding 4th

measuring input.

All ground current protective elements can be planned User defined as non-directional or as directional stages. This means, for instance, all elements can be projected in forward/reverse direction.

For each element the following characteristics are available:


For tripping curves please refer to the “Appendix/Instantaneous Current Curves (Ground Current Measured)” section.

The ground current can be measured either directly via a zero sequence transformer or detected by a residual connection. The ground current can alternatively be calculated from the phase currents. However, this is only possible if the current transformers are Wye-connected.

406 www.eaton.com

ETR-5000 IM02602013E

www.eaton.com 407

50X[

1]...

[n]

Nam

e =

50X[

1]...

[n]

Nam

e.Tr

ipC

md

Nam

e.Tr

ip

Ple

ase

Ref

er to

Dia

gram

: Blo

ckin

gs**

Nam

e.Pi

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Ple

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Ref

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Dia

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: Trip

Blo

ckin

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(Ele

men

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not d

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bloc

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IH2.

Blo

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e

Nam

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Nam

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e.IG

H2

Blo*

84 3

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ase

Ref

er to

Dia

gram

: IH

2*

151427

a

19a

AND AN

D

AND

φD

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Nam

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Nam

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IX M

easu

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Fund

.

RM

S

Nam

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riter

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φ

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d on

abo

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eter

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tripp

ing

times

and

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t mod

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will

be

calc

ulat

ed b

y th

e de

vice

.


t 0

Nam

e.* F

ault

in P

roje

cted

Dire

ctio

n10

Ple

ase

Ref

er to

Dia

gram

: Dire

ctio

n D

ecis

ion

Gro

und

Faul

t

IM02602013E ETR-5000

Device Planning Parameters of the 50X/67X Ground Fault Protection




Global Protection Parameters of the 50X/67X Ground Fault Protection


CT Winding Side


W1, W1 (sensitive measurement), W2, W2 (sensitive measurement)

W1 [Protection Para/Global Prot Para/I-Prot/50X[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/I-Prot/50X[1]]







AdaptSet 1 Assignment Adaptive Parameter 1 AdaptSet -.- [Protection Para/Global Prot Para/I-Prot/50X[1]]




408 www.eaton.com

ETR-5000 IM02602013E

Setting Group Parameters of the 50X/67X Ground Fault Protection



Inactive, Active

Inactive [Protection Para/<1..4>/I-Prot/50X[1]]


Inactive, Active



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active



True RMS [Protection Para/<1..4>/I-Prot/50X[1]]

Pickup

If the pickup value is exceeded, the module/element will be started.

0.02 – 20.00 In 1 In [Protection Para/<1..4>/I-Prot/50X[1]]

Pickup (sensitive)


0.002 – 2.000 In 0.02 In [Protection Para/<1..4>/I-Prot/50X[1]]

t

Tripping delay


0.00 – 300.00 s 0.5 s [Protection Para/<1..4>/I-Prot/50X[1]]

IH2 Blo


Inactive, Active


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IM02602013E ETR-5000

50X/67X Ground Fault Protection Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/I-Prot/50X[1]]



[Protection Para/Global Prot Para/I-Prot/50X[1]]

Rvs Blo-I Module Input State: Reverse Blocking [Protection Para/Global Prot Para/I-Prot/50X[1]]

AdaptSet1-I Module Input State: Adaptive Parameter1 [Protection Para/Global Prot Para/I-Prot/50X[1]]




50X/67X Ground Fault Protection Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup IX or IRTrip Signal: TripTripCmd Signal: Trip CommandIGH2 Blo Signal: Blocked by IH2

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ETR-5000 IM02602013E

Name Description

Active AdaptSet Active Adaptive ParameterDefaultSet Signal: Default Parameter SetAdaptSet 1 Signal: Adaptive Parameter 1AdaptSet 2 Signal: Adaptive Parameter 2AdaptSet 3 Signal: Adaptive Parameter 3AdaptSet 4 Signal: Adaptive Parameter 4

Commissioning: Ground Fault Protection – Non-directional [ANSI 50X/67X]

Please test the non-directional ground overcurrent analog to the non-directional phase overcurrent protection.

51X/67X INV Measured Ground Fault ProtectionElements51X[1] ,51X[2]




ANSI 51X – Ground overcurrent protection, non-directional



ANSI 67X – Ground overcurrent protection, directional







measuring input.



• NINV (IEC/XInv);• VINV (IEC/XInv);

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IM02602013E ETR-5000

• LINV (IEC/XInv);• EINV (IEC/XInv);• MINV (ANSI/XInv);• VINV (ANSI/XInv);• EINV (ANSI/XInv);• Thermal Flat;• IT;• I2T; and• I4T.

For tripping curves please refer to the “Appendix/Time Current Curves (Ground Current)” section.


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ETR-5000 IM02602013E

www.eaton.com 413

Nam

e.Tr

ipC

md

Nam

e.Tr

ip

Ple

ase

Ref

er to

Dia

gram

: Blo

ckin

gs**

Nam

e.Pi

ckup

Ple

ase

Ref

er to

Dia

gram

: Trip

Blo

ckin

gs

(Ele

men

t is

not d

eact

ivat

ed a

nd n

o ac

tive

bloc

king

sig

nals

)

(Trip

ping

com

man

d no

t dea

ctiv

ated

or b

lock

ed. )

IH2.

Blo

IG

Inac

tive

Activ

e

Nam

e.IG

H2

Blo

AND

Nam

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ckup

Nam

e.IG

H2

Blo*

84 3

Ple

ase

Ref

er to

Dia

gram

: IH

2*

151427

b

19b

AND AN

D

AND

IX M

easu

red

Fund

.

RM

S

Nam

e.C

riter

ion

φ

51X[

1]...

[n]

Nam

e =

51X[

1]...

[n]

φ INV

Nam

e.t-r

eset

Nam

e.t-m

ultip

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Nam

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urve

Sha

pe

Nam

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eset

Mod

e

Bas

ed o

n ab

ove

para

met

ers,

trip

ping

tim

es a

nd re

set m

odes

will

be c

alcu

late

d by

the

devi

ce.


Nam

e.* F

ault

in P

roje

cted

Dire

ctio

n10

Ple

ase

Ref

er to

Dia

gram

: Dire

ctio

n D

ecis

ion

Gro

und

Faul

t

IM02602013E ETR-5000

Device Planning Parameters of the 51X/67X Ground Fault Protection




Global Protection Parameters of the 51X/67X Ground Fault Protection


CT Winding Side



W1 [Protection Para/Global Prot Para/I-Prot/51X[1]]













414 www.eaton.com

ETR-5000 IM02602013E

Setting Group Parameters of the 51X/67X Ground Fault Protection



Inactive, Active

51X[1]: Inactive51X[2]: Active

[Protection Para/<1..4>/I-Prot/51X[1]]


Inactive, Active



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active



True RMS [Protection Para/<1..4>/I-Prot/51X[1]]

Pickup



Pickup (sensitive)



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IM02602013E ETR-5000


Curve Shape


ANSI MINV [Protection Para/<1..4>/I-Prot/51X[1]]

t-multiplier


0.02 - 20.00 1 [Protection Para/<1..4>/I-Prot/51X[1]]

Reset Mode


Calculated [Protection Para/<1..4>/I-Prot/51X[1]]

t-reset


Only available if:Reset Mode = t-delay

0.00 – 60.00 s 0.00 s [Protection Para/<1..4>/I-Prot/51X[1]]

IH2 Blo


Inactive, Active


51X/67X Ground Fault Protection Input States





[Protection Para/Global Prot Para/I-Prot/51X[1]]

Rvs Blo-I Module Input State: Reverse Blocking [Protection Para/Global Prot Para/I-Prot/51X[1]]


416 www.eaton.com

ETR-5000 IM02602013E





51X/67X Ground Fault Protection Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup IX or IRTrip Signal: TripTripCmd Signal: Trip CommandIGH2 Blo Signal: Blocked by IH2Active AdaptSet Active Adaptive ParameterDefaultSet Signal: Default Parameter SetAdaptSet 1 Signal: Adaptive Parameter 1AdaptSet 2 Signal: Adaptive Parameter 2AdaptSet 3 Signal: Adaptive Parameter 3AdaptSet 4 Signal: Adaptive Parameter 4

Commissioning: Ground Fault Protection – Non-directional [ANSI 51X/67X]


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IM02602013E ETR-5000

Directional Features for Calculated (IR) Ground Fault Elements 50R/51RAll ground fault elements can be selected as »Non-directional/Forward/Reverse« operated. This has to be done in the »Device Planning« menu.

For the direction detection, it is mandatory that the required voltages exceed 0.35 V and the required currents exceed 10 mA. An exception is the measured sensitive ground current which has to exceed 1 mA.

Important Definitions

Polarizing Quantity: This is the quantity that is used as a reference value. The polarizing quantity can be selected by the parameter »IR Direction Control« in the [System Para/Direction] menu as follows:

• »IR 3V0«: The neutral voltage selected by the parameter »3V0 Source« will be used as the polarizing quantity. The traditional way to polarize a ground fault element is to use neutral voltage (3V0). The neutral voltage can, however, be either »measured« or »calculated«. This can be selected by the parameter »3V0 Source« in the [System Para/Direction] menu.

• »IR IPol«: The measured neutral current (usually = IX) will be used as polarizing quantity.

• »IR Dual«: For this method, the measured neutral current IPol=IX will be used as polarizing quantity, if available, otherwise 3V0 will be used.

• »IR Neg«: With this selection, the negative phase sequence voltage and current will be used to detect the direction. The monitored current is still the calculated residual current IR.

Operating Quantity: For the directional IR elements, the operating quantity is in general the calculated neutral current IR (except from »IR Neg« mode, where »I2« is the operating quantity).

The ground maximum torque angles (MTA) can be adjusted from 0° to 360°, except, if »IR IPol« is selected. In this case it is set to 0° (fixed).

The following table gives the User a quick overview of the all possible directional settings.





IR Dir Cntrl =


3V0 Source =

Residual current and neutral voltage:IR, 3V0 (measured)

Ground MTA IR 3V0 Measured

Residual current and neutral voltage:IR, 3V0 (calculated)

Ground MTA IR 3V0 Calculated

Residual current and neutral/ground currentIR, IX

0° (fixed) IR IPol N.A.

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ETR-5000 IM02602013E





IR Dir Cntrl =


3V0 Source =

Residual current and neutral/ground current (preferred), residual current and neutral voltage (alternatively):IR, IX (if available)or else:IR, 3V0 (measured)

If Ipol (=IX) is available, MTA = 0° (fixed); else MTA=Ground MTA

IR Dual Measured

Residual current and neutral/ground current (preferred), residual current and neutral voltage (alternatively):IR, IX (if available)or else:IR, 3V0 (calculated)

If Ipol (=IX) is available, MTA = 0° (fixed); else MTA=Ground MTA

IR Dual Calculated


90° + Phase MTA IR Neg N.A.

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IM02602013E ETR-5000

420 www.eaton.com

Rev

erse

Forw

ard

pola

rizin

g

50R/

51R

-Dire

ctio

n D

etec

tion

MTA

Mea

sure

d

3V0

Sour

ce

Sys

tem

Par

a

Calc

ulat

ed

VR c

alc

VX m

eas

IR 3

V0

IR IP

ol

IR D

ir Cn

trl

IR D

ual

IR N

eg

3V0

3V0

IX m

eas

IX m

eas*

I2

V2

I0 =

IR c

alc

Pro

t.IR

dir

n po

ss

Prot

.IR d

ir re

v

Prot

.IR d

ir fw

d(F

orw

ard)

(Rev

erse

)

(Not

pos

sibl

e)

10a

10a

pola

rizin

gop

erat

ing

Pro

t -50

R/5

1R -

Dire

ctio

n D

etec

tion

oper

ating

0° (f

ixed)

Gro

und

MTA

Syst

em P

ara

Syst

em P

ara

10a

Prot

.IR N

eg d

ir n

poss

Prot

.IR N

eg re

v di

r

Pro

t.IR

Neg

dir

fwd

(For

war

d)

(Rev

erse

)

(Not

pos

sibl

e)

10a

10a

10a

If IP

ol is

ava

ilabl

e, M

TA =

0°;

els

e M

TA=G

roun

d M

TA

90° +

Pha

se M

TA

*=P

riorit

y if

avai

labl

e.

ETR-5000 IM02602013E

50R/67R DEFT Calculated Ground Fault ProtectionElements50R[1] ,50R[2]

If using inrush blockings, the tripping delay of the ground current protection functions must be at least 30 ms or more in order to prevent faulty trippings.




ANSI 50R – Ground overcurrent protection, non-directional



ANSI 67R – Ground overcurrent protection, directional







measuring input.




For tripping curves please refer to the “Appendix/Instantaneous Current Curves (Ground Current Calculated)” section.


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IM02602013E ETR-5000

422 www.eaton.com

Nam

e.Tr

ipC

md

Nam

e.Tr

ip

Plea

se R

efer

to D

iagr

am: B

lock

ings

**

Nam

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Plea

se R

efer

to D

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am: T

rip B

lock

ings

(Ele

men

t is

not d

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nd n

o ac

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bloc

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sig

nals

)

(Trip

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com

man

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or b

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IH2.

Blo

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Activ

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Nam

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H2

Blo

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Nam

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: IH

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151427

c

19c

AND AN

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AND

Fund

.

RM

S

Nam

e.C

riter

ion

φ

50R

[1]..

.[n]

Nam

e =

50R

[1]..

.[n]

IX C

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and

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t 0

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ault

in P

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Dire

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irect

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Dec

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ETR-5000 IM02602013E

Device Planning Parameters of the 50R/67R Ground Fault Protection




Global Protection Parameters of the 50R/67R Ground Fault Protection


CT Winding Side



W1 [Protection Para/Global Prot Para/I-Prot/50R[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/I-Prot/50R[1]]







AdaptSet 1 Assignment Adaptive Parameter 1 AdaptSet -.- [Protection Para/Global Prot Para/I-Prot/50R[1]]




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IM02602013E ETR-5000

Setting Group Parameters of the 50R/67R Ground Fault Protection



Inactive, Active

50R[1]: Inactive50R[2]: Active

[Protection Para/<1..4>/I-Prot/50R[1]]


Inactive, Active

Inactive [Protection Para/<1..4>/I-Prot/50R[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active



True RMS [Protection Para/<1..4>/I-Prot/50R[1]]

Pickup


0.02 – 20.00 In 1 In [Protection Para/<1..4>/I-Prot/50R[1]]

t

Tripping delay


0.00 – 300.00 s 0.5 s [Protection Para/<1..4>/I-Prot/50R[1]]

IH2 Blo


Inactive, Active


50R/67R Ground Fault Protection Input States

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ETR-5000 IM02602013E


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/I-Prot/50R[1]]



[Protection Para/Global Prot Para/I-Prot/50R[1]]

Rvs Blo-I Module Input State: Reverse Blocking [Protection Para/Global Prot Para/I-Prot/50R[1]]

AdaptSet1-I Module Input State: Adaptive Parameter1 [Protection Para/Global Prot Para/I-Prot/50R[1]]




50R/67R Ground Fault Protection Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup IX or IRTrip Signal: TripTripCmd Signal: Trip CommandIGH2 Blo Signal: Blocked by IH2Active AdaptSet Active Adaptive ParameterDefaultSet Signal: Default Parameter Set

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IM02602013E ETR-5000

Name Description

AdaptSet 1 Signal: Adaptive Parameter 1AdaptSet 2 Signal: Adaptive Parameter 2AdaptSet 3 Signal: Adaptive Parameter 3AdaptSet 4 Signal: Adaptive Parameter 4

Commissioning: Ground Fault Protection – Non-directional [ANSI 50R/67R]

Please test the non-directional ground overcurrent using the procedure for non-directional phase overcurrent protection.

51R/67R INV Calculated Ground Fault ProtectionElements51R[1] ,51R[2]




ANSI 51R – Ground overcurrent protection, non-directional



ANSI 67R – Ground overcurrent protection, directional







measuring input.



• NINV (IEC/XInv);• VINV (IEC/XInv);• LINV (IEC/XInv);

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ETR-5000 IM02602013E

• EINV (IEC/XInv);• MINV (ANSI/XInv);• VINV (ANSI/XInv);• EINV (ANSI/XInv);• Thermal Flat;• IT;• I2T; and• I4T.

For tripping curves please refer to the “Appendix/Time Current Curves (Ground Current)” section.


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IM02602013E ETR-5000

428 www.eaton.com

Nam

e.Tr

ipC

md

Nam

e.Tr

ip

Ple

ase

Ref

er to

Dia

gram

: Blo

ckin

gs**

Nam

e.Pi

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Ple

ase

Ref

er to

Dia

gram

: Trip

Blo

ckin

gs

(Ele

men

t is

not d

eact

ivat

ed a

nd n

o ac

tive

bloc

king

sig

nals

)

(Trip

ping

com

man

d no

t dea

ctiv

ated

or b

lock

ed. )

IH2.

Blo

IG

Inac

tive

Activ

e

Nam

e.IG

H2

Blo

AND

Nam

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Nam

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ase

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: IH

2*

151427

d

19d

AND AN

D

AND

Fund

.

RM

S

Nam

e.C

riter

ion

φ

φ INV

Nam

e.t-r

eset

Nam

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ultip

lier

Nam

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urve

Sha

pe

Nam

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eset

Mod

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eter

s, tr

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times

and

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es w

ill be

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ted

by th

e de

vice

.

IX C

alcu

late

d

51R

[1]..

.[n]

Nam

e =

51R

[1]..

.[n]


Nam

e.* F

ault

in P

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cted

Dire

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Ple

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Ref

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Dia

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: Dire

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Gro

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ETR-5000 IM02602013E

Device Planning Parameters of the 51R/67R Ground Fault Protection




Global Protection Parameters of the 51R/67R Ground Fault Protection


CT Winding Side



W1 [Protection Para/Global Prot Para/I-Prot/51R[1]]













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IM02602013E ETR-5000

Setting Group Parameters of the 51R/67R Ground Fault Protection



Inactive, Active

51R[1]: Inactive51R[2]: Active

[Protection Para/<1..4>/I-Prot/51R[1]]


Inactive, Active



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active



True RMS [Protection Para/<1..4>/I-Prot/51R[1]]

Pickup


0.02 – 20.00 In 0.1 In [Protection Para/<1..4>/I-Prot/51R[1]]

Curve Shape


ANSI MINV [Protection Para/<1..4>/I-Prot/51R[1]]

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ETR-5000 IM02602013E


t-multiplier


0.02 - 20.00 1 [Protection Para/<1..4>/I-Prot/51R[1]]

Reset Mode


Calculated [Protection Para/<1..4>/I-Prot/51R[1]]

t-reset


Only available if:Reset Mode = t-delay

0.00 – 60.00 s 0.00 s [Protection Para/<1..4>/I-Prot/51R[1]]

IH2 Blo


Inactive, Active


51R/67R Ground Fault Protection Input States





[Protection Para/Global Prot Para/I-Prot/51R[1]]

Rvs Blo-I Module Input State: Reverse Blocking [Protection Para/Global Prot Para/I-Prot/51R[1]]




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IM02602013E ETR-5000



51R/67R Ground Fault Protection Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup IX or IRTrip Signal: TripTripCmd Signal: Trip CommandIGH2 Blo Signal: Blocked by IH2Active AdaptSet Active Adaptive ParameterDefaultSet Signal: Default Parameter SetAdaptSet 1 Signal: Adaptive Parameter 1AdaptSet 2 Signal: Adaptive Parameter 2AdaptSet 3 Signal: Adaptive Parameter 3AdaptSet 4 Signal: Adaptive Parameter 4

Commissioning: Ground Fault Protection – Non-directional [ANSI 51R/67R]


24 - Volts/HertzAvailable Elements24[1] ,24[2]

This protective element of the device provides over-excitation protection for the generator and unit connected transformers. It incorporates two elements that can be programmed to specific times and used to create traditional, two-step over-excitation protection.

In addition, the protective elements can be programmed as inverse time elements to provide advanced protection by closely approximating the combined generator/unit transformer over-excitation curve. Standard inverse time curves can be selected along with a linear reset rate that may be programmed to match the specific machine cooling characteristics.

The percent pickup is based on the Nominal Voltage and Frequency settings. The V/Hz function provides reliable measurements of V/Hz up to 200% for a frequency range of 2 - 80 Hz (normal 8-80Hz).

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ETR-5000 IM02602013E

Tripping Characteristic Inverse A

www.eaton.com 433

t = t-multiplier

-1( )PickupV / f

1 1.2 1.4 1.6 1.8 20.01

0.1

1

10

100

1000

10

3

1

0.3

0.1

Tim

e To

Trip

[s]

Multiples of volts per hertz pickup

t-mul

tiplie

r

t = t-multiplier

-12( )V / f

Pickup

IM02602013E ETR-5000

Tripping Characteristic Inverse B

434 www.eaton.com

1 1.2 1.4 1.6 1.8 20.1

1

10

100

1000

10

3

1

0.3

0.1

Tim

e To

Trip

[s]


t-mul

tiplie

r

t = t-multiplier

-10.5( )Pickup

V / f

ETR-5000 IM02602013E

Tripping Characteristic Inverse C

www.eaton.com 435

1 1.2 1.4 1.6 1.8 20.1

1

10

100

1000

10000

10

3

1

0.3

0.1

Tim

e To

Trip

[s]


t-mul

tiplie

r

IM02602013E ETR-5000

Tripping Characteristic DEFT (definite time)

Device Planning Parameters of the Volts/Hertz Element




Global Protection Parameters of the Volts/Hertz Element



1..n, Assignment List -.- [Protection Para/Global Prot Para/Volts/Hertz/24[1]]



436 www.eaton.com

1 1.2 1.4 1.6 1.8 20.01

0.1

1

10

100

1000


Tim

e To

Trip

[s] 80 400

600

0

ETR-5000 IM02602013E




Setting Group Parameters of the Volts/Hertz Element



Inactive, Active

Inactive [Protection Para/<1..4>/Volts/Hertz/24[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


Pickup If the pickup value is exceeded, the element will be started.

80.0 - 400.0% 100.0% [Protection Para/<1..4>/Volts/Hertz/24[1]]

Curve Shape Tripping characteristics of V/f Over-Excitation protection.

DEFT, INV A, INV B, INV C

DEFT [Protection Para/<1..4>/Volts/Hertz/24[1]]

t Tripping delay


0.00 – 600.00 s 1.00 s [Protection Para/<1..4>/Volts/Hertz/24[1]]

t-multiplier Time Multiplier for inverse characteristics.

Only available if: Characteristic = INV

0.05 - 600.00 1.00 [Protection Para/<1..4>/Volts/Hertz/24[1]]

t-reset Reset time for inverse characteristics.

Only available if: Characteristic = INV

0.0 – 1000.0 s 1.0 s [Protection Para/<1..4>/Volts/Hertz/24[1]]

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IM02602013E ETR-5000

Input States of the Volts/Hertz Element


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Volts/Hertz/24[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Volts/Hertz/24[1]]


[Protection Para/Global Prot Para/Volts/Hertz/24[1]]

Signals of the Volts/Hertz (Output States)

Name Description


ZI - Zone InterlockingElementsZI[1] ,ZI[2]


The purpose of zone interlocking is to speed up tripping for some faults without sacrificing the coordination of the system and interjecting nuisance trips into the system. Zone interlocking devices can communicate across distribution zones to determine whether or not a device sees a fault condition.

Zone interlocking is a communication scheme used with breakers and protective relays to improve the level of protection in a power distribution system. This is achieved through communication between the downstream and upstream devices in a power system. The zones are classified by their location downstream of the main circuit protective device which is generally defined as Zone 1.

By definition, a selectively coordinated system is one where by adjusting the trip unit pickup and time delay settings, the breaker closest to the fault trips first. The upstream breaker serves two functions: (1) back-up protection to the downstream breaker and (2) protection of the conductors between the upstream and downstream breakers.

For faults which occur on the conductors between the upstream and downstream breakers, it is ideal for the upstream breaker to trip with no time delay. This is the feature provided by Zone Selective Interlocking.

The zone interlocking information can be transferred to or received from other compatible zone interlocking

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ETR-5000 IM02602013E

devices by means of suitable communication cables. The single zone interlock terminal block, with its 3-wire scheme, can be used for either phase zone interlocking, ground zone interlocking, or a combination of the two. If phase and ground zone interlocking are combined, the potential consequences must be understood before implementation.

Systems containing multiple sources, or where the direction of power flow varies, require special considerations, or may not be suitable for this feature.

The breaker failure pickup signal »BF.PICKUP« is implicitly connected to zone interlocking, so that NO zone interlock output signal can be sent to the upstream device if a breaker failure on a downstream device is detected.

Description of the Functions and Features

• Configurable protection functions to initiate the zone interlocking OUTPUT signal (start functions).

• Remove zone interlocking OUTPUT signal immediately after detection of a breaker failure.

• Reset time (about ten cycles - settable) to interrupt OUTPUT signal for durable trip signal.

• Small trip delay (about three cycles – settable) to wait for downstream devices interlocking signals.

• Zone interlocking trip signal only possible by absence of zone interlocking INPUT signals.

• Configurable zone interlocking trip functions (protective functions serve as zone interlocking trip functions).

• Zone interlocking trip function pickup and tripping characteristic adaption using adaptive settings controlled by the zone interlocking input signals.

Device Planning Parameters of the Zone Interlocking


Mode Mode Use Use [Device Planning]

Global Protection Parameters of the Zone Interlocking

In the global parameter menu for zone interlocking, two external blocking inputs (»Ex Block1/Ex Block2«), as with other protection modules, can be assigned to the input of the zone interlocking function so that the zone interlock function can be blocked by an assigned function.

Via an external input signal, the zone interlocking can also be blocked if the parameter »ExtBlockTripCMD« is assigned.

Breaker Failure Pickup flag BF.Pickup is implicitly connected to zone interlocking, so that NO zone interlock output signal can be sent to the upstream device if a breaker failure on downstream device is detected.

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IM02602013E ETR-5000



1..n, Assignment List -.- [Protection Para/Global Prot Para/ZI-Prot/ZI[1]]





Setting Group Parameters of the Zone Interlocking

The zone interlocking Setting Group Parameters consists of three groups of setting to configure the zone interlocking module to adapt to various application philosophies accordingly:

• General: This group comprises the settings used to control the general usage of the zone interlocking module.

• OUTPUT: What should be assigned to the Zone Out?- Phase,- Ground, or

• - Both.

The OUTPUT group comprises the settings to configure the zone interlocking output logic. If the zone interlocking application is used to a downstream device, the settings in OUTPUT group should be programmed accordingly. If the zone interlocking application is only used for an upstream device (main breaker or Zone 1), the setting ZoneInterlockOut within the OUTPUT group should be disabled.

• TRIP: Activate the Zone Trip.

The TRIP group comprises the settings used to configure the zone interlocking TRIP logic. If the zone interlocking application is applied to an upstream device, (main breaker or Zone 1), the settings in the TRIP group should be programmed accordingly. If the zone interlocking application is only used for a downstream device (feeder breaker or Zone 2), the setting ZoneInterlockTrip in TRIP group should be disabled.

Setting the above mentioned setting groups accordingly the zone interlocking module can be configured as:

• Downstream device application (using only OUTPUT logic);,

• Upstream device application (using only TRIP logic); or

• Midstream device application (using both OUTPUT and TRIP logic together).

The following menu and tables show the detailed information about the settings.

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ETR-5000 IM02602013E


Function Permanent activation or deactivation of module/stage. The elements, that are associated with Zone Interlocking depend on the protective device. Transformer relays: ZI[1]: 50P[1], 50P[2], 51P[1], 50X[1], 51X[1], 50R[1], 51R[1] ZI[2]: 50P[3], 50P[4], 51P[3], 50X[2], 51X[2], 50R[2], 51R[2] All other Protective Devices: ZI: 50P[1], 50P[2], 51P[1], 50X[1], 50X[2], 51X[1], 50R[1], 50R[2], 51R[1] .

Inactive, Active

Inactive [Protection Para/<1..4>/ZI-Prot/ZI[1]/General Settings]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


ZI OUT Fc Zone Interlocking Out activate (allow) / inactivate (disallow).

Inactive, Active

Inactive [Protection Para/<1..4>/ZI-Prot/ZI[1]/Zone Out]

Fault Type Fault Type Phase, Ground, Both

Phase [Protection Para/<1..4>/ZI-Prot/ZI[1]/Zone Out]

Trip Signal: Zone Interlocking Trip Inactive, Active

Inactive [Protection Para/<1..4>/ZI-Prot/ZI[1]/Zone Trip]

Fault Type Fault Type Phase, Ground, Both

Phase [Protection Para/<1..4>/ZI-Prot/ZI[1]/Zone Trip]

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IM02602013E ETR-5000

Zone Interlocking Output Logic [X2]

The following current protective function elements serve as the Phase Zone Interlock OUTPUT start functions:

• 51P[1];• 50P[1]; and• 50P[2].

The following current protective function serves as the Ground Zone Interlock OUTPUT start functions:

• 51X[1];• 50X[1];• 50X[2];• 51R[1];• 50R[1] and• 50R[2].

442 www.eaton.com

ZI.OUT

Zone Interlocking OUTPUT Logic Timing

STARTEDSTANDBY TRIPPED RESET STANDBYSTATETRANSFER

51P[1].Trip

51P[1].Pickup

ZI.Bkr Blo

t

t

0

1

0

1

t

0

1

t

0

1

t

0

1

Reset Timer

10 Cycles

ETR-5000 IM02602013E

www.eaton.com 443

OR

OR OR

OR

OR

OR

OR

AND

AND

AND

AND

AND

AND

Phas

e

Gro

und

Faul

t Typ

e

Both

50P[

1].P

icku

p

51P[

1].P

icku

p

50P[

2].P

icku

p

50P[

1].T

ripCm

d

51P[

1].T

ripC

md

50P[

2].T

ripC

md

50X[

1].P

icku

p

51X[

1].P

icku

p

50X[

2].P

icku

p

50R

[1].P

ickup

51R

[1].P

ickup

50R

[2].P

ickup

50X[

1].T

ripC

md

51X[

1].T

ripC

md

50X[

2].T

ripC

md

50R

[1].T

ripC

md

51R

[1].T

ripC

md

50R[

2].T

ripCm

d

Activ

e

ZI O

UT F

c

Inac

tive

BF.T

rip

ZI.B

kr B

lo

ZI.G

roun

d O

UT

ZI.P

hase

OU

T

ZI.O

UT

166 m

st

166 m

st

ZI.Z

one

Out

Plea

se R

efer

to D

iagr

am: B

lock

ings

2(E

lem

ent i

s not

dea

ctiva

ted

and

no a

ctive

blo

ckin

g si

gnal

s)

(Har

dwar

e O

utpu

t)

IM02602013E ETR-5000

Zone Interlocking Trip Logic [X2]

The following overcurrent protection elements trigger Phase Zone-Interlock trip functions:

• 1.5 * 51P[1];• 50P[1]; and• 50P[2].

The following overcurrent protection elements trigger Ground Zone Interlock trip functions:

• 51X[1];• 50X[1];• 50X[2];• 51R[1]; • 50R[1], and• 50R[2].

444 www.eaton.com

Zone Interlocking TRIP Logic Timing

STARTEDSTANDBY TRIPPED STANDBY INTERLOCKED STANDBY

ZI.Trip

STATETRANSFER

51P[1].Pickup

ZI.Pickup

t

t

0

1

0

1

t

0

1

t

0

1

t0

1

Trip Delay Timer

3 Cycles

ZI.IN

ETR-5000 IM02602013E

www.eaton.com 445

AND

AND

OR

50 m

st

50 m

st

OR OR OR

OR

AND

AND

Phas

e

Gro

und

Faul

t Typ

e

Both

50P[

1].P

ickup

1.5*

51P[

1].P

ickup

50P[

2].P

ickup

50X[

1].P

ickup

51X[

1].P

ickup

50X[

2].P

ickup

50R[

1].P

icku

p

51R[

1].P

icku

p50

R[2]

.Pic

kup

Activ

e

Trip

Inac

tive

ZI.G

roun

d P

icku

p

ZI.P

hase

Pic

kup

ZI.P

hase

Trip

ZI.G

roun

d T

rip

ZI.T

rip

ZI.IN

ZI.Z

one

Trip

Plea

se R

efer

to D

iagr

am: B

lock

ings

2(E

lem

ent i

s no

t dea

ctiv

ated

and

no

activ

e bl

ocki

ng s

igna

ls)

ZI.T

ripCm

d

Ple

ase

Ref

er to

Dia

gram

: Trip

Blo

ckin

gs

(Trip

ping

com

man

d de

activ

ated

or b

lock

ed. )

3

15A

ND

14O

R

1414

ZI.P

icku

p

Har

dwar

e In

put

IM02602013E ETR-5000

Zone Interlocking Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/ZI-Prot/ZI[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/ZI-Prot/ZI[1]]


[Protection Para/Global Prot Para/ZI-Prot/ZI[1]]

Zone Interlocking Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandBkr Blo Signal: Blocked by Breaker FailurePhase Pickup Signal: Zone Interlocking Phase PickupPhase Trip Signal: Zone Interlocking Phase Trip Ground Pickup Signal: Zone Interlocking Ground PickupGround Trip Signal: Zone Interlocking Ground Trip Pickup Signal: Pickup Zone InterlockingTrip Signal: Zone Interlocking TripTripCmd Signal: Zone Interlocking Trip CommandPhase OUT Signal: Zone Interlocking Phase OUTGround OUT Signal: Zone Interlocking Ground OUTOUT Signal: Zone Interlocking OUTIN Signal: Zone Interlocking IN

Zone Interlocking Wiring

The ZI Outputs are for use with connection to electronic inputs only.

The zone interlocking connection between relays is done by means of a twisted shielded cable. Downstream zone interlock outputs may be paralleled from up to ten devices (FP-5000 or DT-3000 or a combination of both) for connection to upstream zone interlocked relays.

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ETR-5000 IM02602013E

Hardware Terminals for Zone Interlocking

By means of the zone interlocking terminals, the device can be connected to other Eaton protective devices such as an FP5000, DT3000, etc.

As an upstream device, the terminals - Phase/Ground IN should be connected to the OUT terminals of up to ten downstream device(s) by means of a dedicated cable wired in parallel. As a downstream device, the terminals - Phase/Ground OUT should be connected to the IN terminals of an upstream device by means of a dedicated cable.

www.eaton.com 447

Zone 1

J3

FP-X000

1

4

2

Out

In

Com

X2

13

14

15

Shield

Out

Com

Zone 2

16

17

18

Shield

In

Com

EDR-X000

Zone 3

J3

FP-X000

1

4

2

Out

In

Com

DT-3000

13

14

15

Out

In

Out

16

18

In

Com

Ground

Phase

J3

FP-X000

1

4

2

Out

In

Com

X2

13

14

15

Shield

Out

Com

16

17

18

Shield

In

Com

EDR-X000

IM02602013E ETR-5000

Terminal Marking X2 for Device: EDR-3000

448 www.eaton.com

123456789

101112131415161718

RO3

X?.

SC

IRIG-B+

IRIG-B-

COM

OUT

IN

COM

RO1

RO2

ETR-5000 IM02602013E

Terminal Marking X2 for Device: EDR-4000, EDR-5000, EMR-4000, EMR-5000, EGR-4000 and EGR-5000

49 - Thermal Overload Protection49

One thermal overload protection function is provided for tripping and alarming based on the thermal model using the maximum phase current (transformer only - from either winding 1 or winding 2) based on the User’s choice.

This thermal overload protection function applies to transformers ONLY.

The thermal model, with preload current taken into account, is in compliance with IEC255-8 (VDE 435 T301). The thermal tripping limit is determined by the so called overload factor K multiplying the maximum permissible continuous phase current Ib. Ib is also referred to as the base current or rated current, which can be found from the transformer (or other equipment to be protected) name plate. The overload factor K must be determined based on the transformer type and its cooling method (or other equipment to be protected). The transformer with natural cooling may have less tolerance on overload while other types of transformer with forced cooling (oil or air) may be allowed to run under substantial overload for a relatively long time.

The warming and cooling process of the thermal overload model is dictated by the warming, cooling constants (» t-warm«, »t-cool«). t-warm« is the time in which the temperature of the operating equipment to be protected

has reached 63% of the stationary operating temperature under rated load current after switching on. »t-cool«is the time in which the temperature of the operating equipment to be protected has dropped 63% of the stationary operating temperature when switching off from the rated load condition. These time constants may be found in the data sheet of the transformer or may be derived from test reports.

The tripping time is determined by the tripping time characteristic according to the thermal model. The alarm

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101112131415161718

RO3

X?.Do not useDo not use

COM

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IM02602013E ETR-5000

threshold is defined as a percentage of the thermal tripping limit.

Legend:

Tripping characteristic with initial load:

Characteristic with complete memory function - the heating caused by the current before the overload happens is taken into account for the thermal model of the electrical equipment to be protected.

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(K*Ib)2=100%

(K*Ib)2=67%

t

Thermal Cap max

Thermal Cap Used

t = Tripping delay

t -cool = Cooling time constant

K =

I = Measured current (x In)

Ip = Preload Current

Ib = Base Current: Maximum permissible thermal continuous current.

Overload Factor: The maximum thermal limit is defined as k*IB, the product of the overload factor and the basic current.

t -warm = Warming-up time constant

( )t = t -warm ln I2 - Ip2

I2 - (K*Ib)2

ETR-5000 IM02602013E

The curves below are valid for Ip=0 and K=1.

Thermal Overload Characteristic Example – IEC Trip Characteristic for Overload Protection

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1 10 1000.01

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IM02602013E ETR-5000

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49

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ETR-5000 IM02602013E

Direct Commands of the Thermal Overload Module


Reset Reset the Thermal Replica Inactive, Active


Device Planning Parameters of the Thermal Overload Module




Global Protection Parameters of the Thermal Overload Module


CT Winding Side


W1, W2

W1 [Protection Para/Global Prot Para/I-Prot/49]


1..n, Assignment List -.- [Protection Para/Global Prot Para/I-Prot/49]





Setting Group Parameters of the Thermal Overload Module



Inactive, Active

Inactive [Protection Para/<1..4>/I-Prot/49]


Inactive, Active


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Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


Ib Base Current: Maximum permissible thermal continuous current.

0.01 – 4.00 In 1.00 In [Protection Para/<1..4>/I-Prot/49]

K Overload Factor: The maximum thermal limit is defined as k*IB, the product of the overload factor and the basic current.

0.80 - 1.20 1.00 [Protection Para/<1..4>/I-Prot/49]

Alarm Threshold

Alarm Threshold 50 - 100% 80% [Protection Para/<1..4>/I-Prot/49]

τ-warm Warming-up time constant 1 – 60000 s 10 s [Protection Para/<1..4>/I-Prot/49]

τ-cool Cooling time constant 1 – 60000 s 10 s [Protection Para/<1..4>/I-Prot/49]

Thermal Overload Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/I-Prot/49]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/I-Prot/49]


[Protection Para/Global Prot Para/I-Prot/49]

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Signals of the Thermal Overload Module (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandAlarm Signal: Alarm Thermal OverloadTrip Signal: TripTripCmd Signal: Trip CommandRes Thermal Cap Signal: Resetting Thermal Replica

Thermal Overload Module Values


Thermal Cap Used Measured value: Thermal Capacity Used [Operation/Measured Values/49]

Time To Trip Measured value (calculated/measured): Remaining time until the thermal overload module will trip


Thermal Overload Module Statistics


Thermal Cap max Thermal Capacity maximum value [Operation/Statistics/Max/49]

Thermal Cap min Thermal Capacity minimum value [Operation/Statistics/Min/49]

Commissioning: Thermal Overload Model [49]

Object to be tested:Protective function ThR

Necessary means:• Three-phase current source; and• Timer.

Procedure:Calculate the tripping time based on the formula provided.

The warming-up time constant has to be known to guarantee optimal protection.

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Legend:

Testing the threshold values:Apply the current on which the mathematical calculation was based.

Testing the trip delay:

The thermal capacity should be zero before the test is started (see »Measuring Values«).

For testing the trip delay, a timer is to be connected to the contact of the associated trip relay. Apply the current on which the mathematical calculation was based. The timer is started as soon as the current is applied and it is stopped when the relay trips.

Successful test result:The calculated tripping time and the drop-out ratio comply with the measured values. For permissible deviations/tolerances, please see the Technical Data section.

46 - Current Unbalance ProtectionElements:46[1] ,46[2]

This is the 46 device Current Unbalance setting, which works similar to the 47 device Voltage Unbalance setting. The positive and negative sequence currents are calculated from the 3-phase currents. The Threshold setting defines a minimum operating current magnitude of either I1 or I2 for the 46 function to operate, which insures that the relay has a solid basis for initiating a current unbalance trip. The »%(I2/I1)« setting is the unbalance trip pickup setting. It is defined by the ratio of negative sequence current to positive sequence current »%(I2/I1)« for ABC rotation and »%(I1/I2)« for ACB rotation. The device will automatically select the correct ratio based on the Phase Sequence setting in the System Configuration group described above.

This function requires positive or negative sequence current magnitude above the threshold setting and the percentage current unbalance above the »%(I2/I1)« setting before allowing a current unbalance trip. Therefore, both the threshold and percent settings must be met for the specified Delay time setting before the relay initiates a trip for current unbalance.

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t = Tripping delay

t -cool = Cooling time constant

K =

I = Measured current (x In)

Ip = Preload Current

Ib = Base Current: Maximum permissible thermal continuous current.

Overload Factor: The maximum thermal limit is defined as k*IB, the product of the overload factor and the basic current.

t -warm = Warming-up time constant

( )t = t -warm ln I2 - Ip2

I2 - (K*Ib)2

ETR-5000 IM02602013E


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IM02602013E ETR-5000

Device Planning Parameters of the Current Unbalance Module




Global Protection Parameters of the Current Unbalance Module


CT Winding Side


W1, W2

46[1]: W146[2]: W2

[Protection Para/Global Prot Para/Unbalance-Prot/46[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Unbalance-Prot/46[1]]





Setting Group Parameters of the Current Unbalance Module



Inactive, Active

Inactive [Protection Para/<1..4>/Unbalance-Prot/46[1]]


Inactive, Active



Inactive, Active


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ExBlo TripCmd Fc


Inactive, Active


Threshold The Threshold setting defines a minimum operating current magnitude of I2 for the 46 function to operate, which ensures that the relay has a solid basis for initiating a current unbalance trip. This is a supervisory function and not a trip level.

Only available if:CurrentBase = Protected Object Rating

0.01 – 4.00 In 0.1 In [Protection Para/<1..4>/Unbalance-Prot/46[1]]

%(I2/I1) The %(I2/I1) setting is the unbalance trip pickup setting. It is defined by the ratio of negative sequence current to positive sequence current (% Unbalance=I2/I1). Phase sequence will be taken into account automatically.

Only available if: %(I2/I1) = Use

2 - 40% 46[1]: 40%46[2]: 20%

[Protection Para/<1..4>/Unbalance-Prot/46[1]]

t Tripping delay


0.00 – 300.00 s 46[1]: 10 s46[2]: 20 s


Current Unbalance Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Unbalance-Prot/46[1]]




Current Unbalance Module Signals (Output States)

Name Description


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Name Description

Blo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup Negative SequenceTrip Signal: TripTripCmd Signal: Trip Command

Commissioning: Current Unbalance Module

Object to be tested:Test of the unbalanced load protection function.

Necessary means:• Three-phase current source with adjustable current unbalance; and• Timer.

Procedure:

Check the phase sequence:

• Ensure that the phase sequence is the same as that set in the system parameters.

• Feed-in a three-phase nominal current.

• Change to the »Measuring Values« menu.

• Check the measuring value for the unbalanced current »I2 Fund.«. The measuring value displayed for »I2 Fund.« should be zero (within the physical measuring accuracy).

If the displayed magnitude for I2 Fund. is the same as that for the balanced nominal currents fed to the relay, it implies that the phase sequence of the currents seen by the relay is reversed.

• Now turn-off phase A.

• Again check the measuring value of the unbalanced current »I2 Fund.« in the »Measuring Values« menu.The measuring value of the unbalanced current »I2 Fund.« should now be 33%.

• Turn-on phase A, but turn-off phase B.

• Once again check the measuring value of the unbalanced current I2 Fund. in the »Measuring Values« menu. The measuring value of the asymmetrical current »I2 Fund.« should be again 33%.

• Turn-on phase B, but turn-off phase C.

• Again check the measuring value of unbalanced current »I2 Fund.« in the »Measuring Values« menu. The measuring value of the unbalanced current »I2 Fund.« should still be 33%.

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• Apply a balanced three-phase current system (nominal currents).

• Switch off IA (the threshold value »Threshold« for »I2 Fund.« must be below 33%).

• Measure the tripping time.

The present current unbalance »I2 Fund.« corresponds with 1/3 of the existing phase current displayed.

Testing the threshold values

• Configure minimum »%(I2/I1)« setting (2%) and an arbitrary threshold value »Threshold« (I2 Fund.).

• For testing the threshold value, a current has to be fed to phase A which is lower than three times the adjusted threshold value »Threshold« (I2 Fund.).

• Feeding only phase A results in »%(I2/I1) = 100%«, so the first condition »%(I2/I1) >= 2%« is always fulfilled.

• Now increase the phase A current until the relay is activated.

Testing the dropout ratio of the threshold values

Having tripped the relay in the previous test, now decrease the phase A current. The dropout ratio must not be higher than 0.97 times the threshold value.

Testing %(I2/I1)

• Configure minimum threshold value »Threshold« (I2 Fund.) (0.01 x In) and set »%(I2/I1)« greater or equal to 10%.

• Apply a balanced three-phase current system (nominal currents). The measuring value of »%(I2/I1)« should be 0%.

• Now increase the phase A current. With this configuration, the threshold value »Threshold« (I2 Fund.) should be reached before the value »%(I2/I1)« reaches the set »%(I2/I1)« ratio threshold.

• Continue increasing the phase 1 current until the relay is activated.

Testing the dropout ratio of %(I2/I1)

Having tripped the relay in the previous test, now decrease the phase A current. The dropout of »%(I2/I1)« has to be 1% below the »%(I2/I1)«setting.

Successful test result:

The measured trip delays, threshold values, and dropout ratios are within the permitted deviations/tolerances, specified under Technical Data.

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SOTF - Switch Onto Fault ProtectionSOTF

In case a faulty line is energized (e.g.: when an grounding switch is in the CLOSE position), an instantaneous trip is required. The SOTF module is provided to generate a permissive signal for other protection functions such as overcurrents to accelerate their trips. The SOTF condition is recognized according to the User’s operation mode that can be based on:

• The breaker state;• No current flowing;• Breaker state and no current flowing;• Breaker switched on manually; and/or• An external trigger.

This protection module can initiate a high speed trip of the overcurrent protection modules. The module can be started via a digital input that indicates that the breaker is manually closed.

This module issues a signal only (the module is not armed and does not issue a trip command).

In order to influence the trip settings of the overcurrent protection in case of switching onto a fault, the User has to assign the signal “SOTF.ENABLED“ to an Adaptive Parameter Set. Please refer to Parameter / Adaptive Parameter Sets sections. Within the Adaptive Parameter Set, the User has to modify the trip characteristic of the overcurrent protection according to the User's needs.

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IM02602013E ETR-5000

Device Planning Parameters of the Switch Onto Fault Module




Global Protection Parameters of the Switch Onto Fault Module


CT Winding Side


W1, W2

W1 [Protection Para/Global Prot Para/SOTF]

Mode Mode Bkr State, I<, Bkr State And I<, Bkr manual CLOSE, Ext SOTF

Bkr manual CLOSE

[Protection Para/Global Prot Para/SOTF]


1..n, Assignment List -.- [Protection Para/Global Prot Para/SOTF]





Assigned Bkr Assigned Breaker

Only available if: Mode = Bkr State Or Bkr State And I<

-, Bkr[1], Bkr[2]

Bkr[1] [Protection Para/Global Prot Para/SOTF]

Ext SOTF External Switch Onto Fault

Only available if: Mode = Ext SOTF

1..n, DI-LogicList -.- [Protection Para/Global Prot Para/SOTF]

Setting Group Parameters of the Switch Onto Fault Module



Inactive, Active

Inactive [Protection Para/<1..4>/SOTF]


Inactive, Active


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ETR-5000 IM02602013E



Inactive, Active


I< The breaker is in the OPEN Position, if the measured current is less than this parameter.

0.01 – 1.00 In 0.01 In [Protection Para/<1..4>/SOTF]

t-enable While this timer is running, and while the module is not blocked, the Switch Onto Fault Module is effective (SOTF is armed).

0.10 – 10.00 s 2 s [Protection Para/<1..4>/SOTF]

Switch Onto Fault Module Input States


ExBlo1-I Module Input State: External Blocking [Protection Para/Global Prot Para/SOTF]

ExBlo2-I Module Input State: External Blocking [Protection Para/Global Prot Para/SOTF]

Rvs Blo-I Module Input State: Reverse Blocking [Protection Para/Global Prot Para/SOTF]

Ext SOTF-I Module Input State: External Switch Onto Fault Alarm

[Protection Para/Global Prot Para/SOTF]

Signals of the Switch Onto Fault Module (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse Blockingenabled Signal: Switch Onto Fault enabled. This Signal can be used to

modify Overcurrent Protection Settings.I< Signal: No Load Current.

Commissioning: Switch Onto Fault [ANSI 50HS]


Testing the module Switch Onto Fault according to the configured operating mode:

• I< (No current);• Bkr state (Breaker position);

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IM02602013E ETR-5000

• I< (No current) and Bkr state (Breaker position); and• Bkr manual CLOSE.

Necessary means:

• Three-phase current source (if the Enable Mode depends on current);• Ampere meters (may be needed if the Enable Mode depends on current); and• Timer.

Test Example for Mode Bkr Manual CLOSE

Mode I< (In order to test the effectiveness): Initially, do not feed any current. Start the timer and feed with an abruptly changing current that is distinctly greater than the I<-threshold to the measuring inputs of the relay.

Mode I< and Bkr state: Simultaneously, manually switch on the breaker and feed with an abrupt change current that is distinctly greater than the I<-threshold.

Mode Bkr state: The breaker has to be in the OFF position. The signal „SOTF.ENABLED“=0 is false. If the breaker is switched on, the signal „SOTF.ENABLED“=1 becomes true as long as the timer t-effective is running.

• The breaker has to be in the OPEN position. There must be no load current.

• The status display of the device shows the signal "SOTF.ENABLED“=1.

Testing:

• Manually switch the breaker to the CLOSE position and start the timer at the same time.

• After the hold time t-enable is expired, the state of the signal has to change to "SOTF.enabled“=0.

• Write down the measured time.


The measured total tripping delays or individual tripping delays, threshold values, and drop-out ratios correspond with those values, specified in the adjustment list. Permissible deviations/tolerances can be found in the Tech-nical Data section.

CLPU - Supervision Module Cold Load PickupAvailable Elements:CLPU

When manually or automatically closing a breaker after it has been open for a prolonged time, a greater than normal load current may be experienced due to the load inrush . This high starting current causes some overcurrent elements to unnecessarily trip the breaker. The cold load pickup (CLPU) function prevents this from happening.

The cold load pickup function detects a warm-to-cold load transition according to the four selectable cold load

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detection modes:

• Breaker state;• Undercurrent (I<);• Breaker state AND undercurrent; and• Breaker state OR undercurrent.

After a warm-to-cold load transition has been detected, a specified load-off timer will be started. This User-settable load-off timer is used in some cases to make sure that the load is really “cold” enough. After the load-off timer times out, the CLPU function issues an “enable” signal »CLPU.ENABLED« that can be used to block User-selected, sensitive protection elements such as instantaneous overcurrent elements, current unbalance, or power protection elements. Using this enable signal, some User-selected time inverse overcurrent elements may also be desensitized by means of activating adaptive settings of the corresponding overcurrent elements.

When a cold load condition is finished (a cold-to-warm load condition is detected) due to, for example, breaker closing or load current injection, a load inrush detector will be initiated that supervises the coming and going of the load inrush current process. A load inrush is detected if the coming load current exceeds a User-specified inrush current threshold. This load inrush is considered as finished if the load current is decreased to 90% of the inrush current threshold.

After the inrush current is diminished, a settle timer starts. The cold load pickup enable signal can only be reset after the settle timer times out. Another max-Block timer, which is started parallel with the load inrush detector after a cold load condition is finished, may also terminate the CLPU enable signal if a load inrush condition is prolonged abnormally.

The cold load pickup function can be blocked manually by external or internal signal at the User´s choice. For the devices with the Auto-Reclosing function, the CLPU function will be blocked automatically if auto-reclosure is initiated (AR is running).

This module issues a signal only (it is not armed).

In order to influence the tripping settings of the overcurrent protection, the User has to assign the signal “CLPU.ENABLED“ to an adaptive parameter set. Please refer to the Parameter / Adaptive Parameter Sets section. Within the adaptive parameter set, the User has to modify the tripping characteristic of the overcurrent protection according to the needs.

Please be aware of the meaning of the two delay timers.

t load Off (Pickup Delay): After this time expires, the load is no longer diversified.

t Max Block (Release Delay): After the starting condition is fulfilled (e.g.: breaker switched on manually), the “CLPU.enabled” signal will be issued for this time. That means for the duration of this time, the tripping thresholds of the overcurrent protection can be desensitized by means of adaptive parameters (please refer to the Parameters section). This timer will be stopped if the current falls below 0.9 times of the threshold of the load inrush detector and remains below 0.9 times of the threshold for the duration of the settle time.

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Example Mode: Breaker Position

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ETR-5000 IM02602013E

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IM02602013E ETR-5000

Device Planning Parameters of the Cold Load Pickup Module




Global Protection Parameter of the Cold Load Pickup Module


CT Winding Side


W1, W2

W1 [Protection Para/Global Prot Para/CLPU]

Mode Mode Bkr State, I<, Bkr State Or I<, Bkr State And I<

Bkr State [Protection Para/Global Prot Para/CLPU]


1..n, Assignment List -.- [Protection Para/Global Prot Para/CLPU]





Bkr Pos Detect Criterion by which the Breaker Switch Position is to be detected.

Only available if: CLPU.Mode = I<

-.-, Bkr[1].State, Bkr[2].State

Bkr[1].State [Protection Para/Global Prot Para/CLPU]

Set Parameters of the Cold Load Pickup Module



Inactive, Active

Inactive [Protection Para/<1..4>/CLPU]


Inactive, Active


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ETR-5000 IM02602013E



Inactive, Active


t-Load Off Select the outage time required for a load to be considered cold. If the Pickup Timer (Delay) has run out, a Cold Load Signal will be issued.

0.00 – 7200.00 s 10 s [Protection Para/<1..4>/CLPU]

t-Max Block Select the maximum amount of time allowed for cold load pickup to be active; if the time has elapsed a warm load signal will be issued.

0.00 – 300.00 s 10 s [Protection Para/<1..4>/CLPU]

I< The breaker is in the OPEN Position, if the measured current is less than this parameter.

0.01 – 1.00 In 0.01 In [Protection Para/<1..4>/CLPU]

Threshold Set the load current inrush threshold. 0.10 – 4.00 In 1.2 In [Protection Para/<1..4>/CLPU]

Settle Time Select the time for the cold load inrush. 0.00 – 300.00 s 1.00 s [Protection Para/<1..4>/CLPU]

States of the Inputs of the Cold Load Pickup Module


ExBlo1-I Module Input State: External Blocking [Protection Para/Global Prot Para/CLPU]

ExBlo2-I Module Input State: External Blocking [Protection Para/Global Prot Para/CLPU]

Rvs Blo-I Module Input State: Reverse Blocking [Protection Para/Global Prot Para/CLPU]

Signals of the Cold Load Pickup Module (States of the Outputs)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingRvs Blo Signal: Reverse Blockingenabled Signal: Cold Load enableddetected Signal: Cold Load detectedI< Signal: No Load Current.

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IM02602013E ETR-5000

Name Description

Load Inrush Signal: Load InrushSettle Time Signal: Settle Time

Commissioning of the Cold Load Pickup Module


Testing the Cold Load Pickup module according to the configured operating mode:

• I< (No current);• Bkr state (Breaker position);• I< (No Current) and Bkr state (Breaker position); and• I< (No Current) or Bkr state (Breaker position).

Necessary means:

• Three-phase current source (if the Enable Mode depends on current);• Ampere meters (may be needed if the Enable Mode depends on current); and• Timer.

Test Example for Mode Bkr State (Breaker Position)

Mode I<: In order to test the tripping delay, start the timer then feed with an abruptly changing current that is distinctly less than the I<-threshold. Measure the tripping delay. In order to measure the drop-out ratio, feed an abruptly changing current that is distinctly above the I<-threshold.

Mode I< and Bkr state: Combine the abruptly changing current(switching the current ON and OFF) with the manual switching ON and OFF of the breaker.

Mode I< or Bkr state: Initially carry out the test with an abruptly changing current that is switched ON and OFF (above and below the I<-threshold). Measure the tripping times. Finally, carry out the test by manually switching the breaker ON and OFF.

• The breaker has to be in the OFF position. There must not be any load current.

• The Status Display of the device shows the signal "CLPU.ENABLED“=1.

• The Status Display of the device shows the signal ”CLPU.I<“=1.

Testing the tripping delay and the resetting ratio:

• Manually switch the breaker ON and simultaneously start the timer.

• After the the »t Max Block (Release Delay)« timer has expired, the signal "CPLU.Enabled “=0 has to be false.


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• Manually switch the breaker OFF and simultaneously start the timer.

• After the »t load Off« timer has expired, the signal ”CPLU.ENABLED “=1 has to become true.



The measured total tripping delays or individual tripping delays, threshold values, and drop-out ratios correspond with those values specified in the adjustment list. Permissible deviations/tolerances can be found in the Tech-nical Data section.

27M - Undervoltage ProtectionAvailable elements:27M[1] ,27M[2]

M is for “Main” referring to protection metered by the Main Voltage transformer in the System Configuration.

All undervoltage elements are identically structured.



Vn=Main VT sec .


Vn= MainVT sec3

This is the 27 device undervoltage setting for the main three phase VT. This function consists of a Phase, a Pickup, a Delay setting. The Phase setting allows the User to select at which phase (any one, any two, or all) the undervoltage function operates. The Pickup setting is the magnitude at which the undervoltage element operates. The Delay setting is the time period an undervoltage must occur before the device initiates a trip. Depending on the settings within the System Parameters, the element works based on phase-to-phase (»Open-Delta«) or phase-to-ground (»wye«) voltages. This element will operate depending on the phase setting: if any one, any two, or all of the voltage(s) that is/are selected by the Phase setting drop(s) below the set point. This element works based on RMS values.

An undervoltage pickup occurs when the measured voltage drops below the UV Threshold setting. The undervoltage trip is set when the voltage stays below the threshold setting for the delay time specified (within the number of phases specified by the phase setting). The undervoltage pickup and trip is reset when the voltage rises above the dropout ratio specified in Specifications section for the undervoltage protection.

If the element should be blocked in the event of a “Loss of Potential”, the »LOP BLO« parameter must be set to »active«.

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If the VT measurement location is not at the bus bar side but at the output side, the following has to be taken into account. When disconnecting the line, it has to be ensured by an »External Blocking« that undervoltage tripping cannot happen. In order to block the 27M element in case that the breaker is open:

• Assign the »Bkr.POS OPEN« signal to a blocking input (»ExBlo1« or »ExBlo2« within the Global Parameters) of the 27M element,and

• »ExBlo Fc« has to be set to “active” within the parameter sets of the the 27M element.

When the auxiliary voltage is switched on and the measuring voltage has not yet been applied, undervoltage tripping has to be prevented by an »External Blocking«. Otherwise a continuous tripping would occur, disabling the ability to energize again.

If phase voltages are applied to the measuring inputs of the device and system parameter »Main VT Con« is set to »Wye«, the messages issued by the voltage protection module in case of actuation or trip should be interpreted as follows:

»27M[1].PICKUP A« or »27M[1].TRIP A« => pickup or trip caused by phase voltage »VA«.»27M[1].PICKUP B« or »27M[1].TRIP B« => pickup or trip caused by phase voltage »VB«.»27M[1].PICKUP C« or »27M[1].TRIP C« => pickup or trip caused by phase voltage »VC«.

However, if line-to-line voltages are applied to the measuring inputs and system parameter »Main VT Con« is set to »Phase to Phase«, then the messages should be interpreted as follows:

»27M[1].PICKUP A« or »27M[1].TRIP A« => pickup or trip caused by phase-to-phase voltage »VAB«.»27M[1]. PICKUP B« or »27M[1].TRIP B« => pickup or trip caused by phase-to-phase voltage »VBC«.»27M[1]. PICKUP C« or »27M[1].TRIP C« => pickup or trip caused by phase-to-phase voltage »VCA«

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Device Planning Parameters of the Undervoltage Protection Module




Global Protection Parameters of the Undervoltage Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Main-V-Prot/27M[1]]





Setting Group Parameters of the Undervoltage Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/Main-V-Prot/27M[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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True RMS [Protection Para/<1..4>/Main-V-Prot/27M[1]]

Phases Indicates if one, two of three or all phases are required for operation

any one, any two, all

any one [Protection Para/<1..4>/Main-V-Prot/27M[1]]

Pickup If the pickup value is exceeded, the module/element will be started. Definition of Vn: Vn is dependent on the System Parameter setting of "Main VT con". In case that within the System Parameters "Main VT con" is set to "Open-Delta" , "Vn = Main VT sec ". In case that "Main VT con" is set to "Wye", "Vn = Main VT sec/SQRT(3)".

Only available if: Device Planning: V.Mode = V<

0.01 – 1.30 Vn 27M[1]: 0.80 Vn27M[2]: 0.90 Vn

[Protection Para/<1..4>/Main-V-Prot/27M[1]]

t Tripping delay 0.00 – 300.00 s 27M[1]: 10 s27M[2]: 2.00 s


LOP Blo Measuring Circuit Supervision Inactive, Active

Active [Protection Para/<1..4>/Main-V-Prot/27M[1]]

Undervoltage Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Main-V-Prot/27M[1]]



[Protection Para/Global Prot Para/Main-V-Prot/27M[1]]

Undervoltage Protection Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blocked

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Name Description

ExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Phase A Signal: Pickup Phase APickup Phase B Signal: Pickup Phase BPickup Phase C Signal: Pickup Phase CPickup Signal: Pickup Voltage ElementTrip Phase A Signal: General Trip Phase ATrip Phase B Signal: General Trip Phase BTrip Phase C Signal: General Trip Phase CTrip Signal: TripTripCmd Signal: Trip Command

Commissioning: Undervoltage Protection [27M]

This test can be carried out similar to the test for overvoltage protection 59M (by using the related undervoltage values).

Please consider the following deviations:

• For testing the threshold values, the test voltage has to be decreased until the relay is activated.

• For detection of the dropout ratio, the measuring quantity has to be increased to achieve more than 103% of the trip value. At 103% of the trip value, the relay is to dropout at the earliest moment.

59M - Overvoltage ProtectionAvailable elements:59M[1] ,59M[2]

M is for “Main” referring to protection metered by the Main Voltage transformer in the System Configuration.




Vn=Main VT sec .


Vn= MainVT sec3

This is the 59 device Overvoltage setting for the Main VT. This element consists of a Phase, a Pickup, and a Delay setting. The Phase setting allows the User to select which phase (any one, any two, or all) the

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Overvoltage function operates. Depending on the settings within the System Parameters, the element works based on phase-to-phase (»Open-Delta«) or phase-to-ground (»wye«) voltages. This element will operate depending on the phase setting: if any one, any two, or all of the voltage(s) that is/are selected by the Phase setting rise(s) above the set point. This element works based on RMS values.

An overvoltage pickup occurs when the measured voltage rises above the overvoltage Threshold setting. The overvoltage trip is set when the voltage stays above the threshold setting for the delay time specified (within the number of phases specified by the phase setting). The overvoltage pickup and trip is reset when the voltage falls below the dropout ratio specified in Specifications section for the overvoltage protection.

If phase voltages are applied to the measuring inputs of the device and system parameter »Main VT con« is set to »Wye«, the messages issued by the voltage protection module in case of actuation or trip should be interpreted as follows:

»59M[1].PICKUP A« or »59M[1].TRIP A« => pickup or trip caused by phase voltage »VA«.»59M[1].PICKUP B« or »59M[1].TRIP B« => pickup or trip caused by phase voltage »VB«.»59M[1].PICKUPC« or »59M[1].TRIP B« => pickup or trip caused by phase voltage »VC«.

However,if line-to-line voltages are applied to the measuring inputs and system parameter »Main VT con« is set to »Wye«, then the messages should be interpreted as follows:

»59M[1].PICKUP A« or »59M[1].TRIP A« => pickup or trip caused by line-to-line voltage »VAB«.»59M[1]. PICKUP B« or »59M[1].TRIP B« => pickup or trip caused by line-to-line voltage »VBC«.»59M[1]. PICKUP C« or »59M[1].TRIP C« => pickup or trip caused by line-to-line voltage »VCA«

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Device Planning Parameters of the Overvoltage Protection Module




Global Protection Parameters of the Overvoltage Protection Module








Setting Group Parameters of the Overvoltage Protection Module



Inactive, Active



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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True RMS [Protection Para/<1..4>/Main-V-Prot/59M[1]]

Phases Indicates if one, two of three or all phases are required for operation

any one, any two, all

any one [Protection Para/<1..4>/Main-V-Prot/59M[1]]

Pickup If the pickup value is exceeded, the module/element will be started. Definition of Vn: Vn is dependent on the System Parameter setting of "Main VT con". In case that within the System Parameters "Main VT con" is set to "Open-Delta" , "Vn = Main VT sec ". In case that "Main VT con" is set to "Wye", "Vn = Main VT sec/SQRT(3)".

Only available if: Device Planning: V.Mode = V>

0.01 – 1.30 Vn 59M[1]: 1.2 Vn59M[2]: 1.1 Vn


t Tripping delay

Only available if: Device Planning: V.Mode = V> Or V<

0.00 – 300.00 s 59M[1]: 10 s59M[2]: 2.00 s


Overvoltage Protection Module Input States





[Protection Para/Global Prot Para/Main-V-Prot/59M[1]]

Overvoltage Protection Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Phase A Signal: Pickup Phase APickup Phase B Signal: Pickup Phase B

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Name Description

Pickup Phase C Signal: Pickup Phase CPickup Signal: Pickup Voltage ElementTrip Phase A Signal: General Trip Phase ATrip Phase B Signal: General Trip Phase BTrip Phase C Signal: General Trip Phase CTrip Signal: TripTripCmd Signal: Trip Command

Commissioning: Overvoltage Protection [59M]

Object to be tested:Test of the overvoltage protection elements, 3 x single-phase and 1 x three-phase (for each element).

Necessary means:• Three phase AC voltage source;• Timer for measuring of the tripping time; and• Voltmeter.

Procedure (3 x single-phase, 1 x three-phase, for each element)

Testing the threshold values:For testing the threshold values and dropout values, the test voltage has to be increased until the relay is activ-ated. When comparing the displayed values with those of the voltmeter, the deviation must be within the per-missible tolerances.

Testing the trip delay:For testing the trip delay, a timer is to be connected to the contact of the associated trip relay. The timer is started when the limiting value of the tripping voltage is exceeded and it is stopped when the relay trips.

Testing the dropout ratio:Reduce the measuring quantity to less than 97% of the trip value. The relay must only dropout at a minimum of 97% of the trip value.

Successful test result:The measured threshold values, trip delays, and dropout ratios comply with those specified in the adjustment list. Permissible deviations/tolerances can be taken from the Technical Data.

27A - Auxiliary Undervoltage ProtectionAvailable elements:27A[1] ,27A[2]

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This is the 27A device Undervoltage setting for the Auxiliary VT. This device setting works exactly the same as the 27M except it is a single-phase element only operating from the Auxiliary VT input. The Alarm Delay is the time period a LOP must occur before the device initiates a »LOP BLO« signal that can be used to block other elements like 51V (Voltage Restraint).

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IM02602013E ETR-5000

Device Planning Parameters of the Aux. Undervoltage Module




Global Protection Parameters of the Aux. Undervoltage Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Aux-V-Prot/27A[1]]





Setting Group Parameters of the Aux. Undervoltage Module



Inactive, Active

Inactive [Protection Para/<1..4>/Aux-V-Prot/27A[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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Pickup Vn refers to either the primary or secondary voltage of the aux VT.

Only available if: Device Planning: 59.Mode = V<

0.01 – 1.30 Vn 27A[1]: 0.8 Vn27A[2]: 0.9 Vn

[Protection Para/<1..4>/Aux-V-Prot/27A[1]]

t Tripping delay 0.00 – 300.00 s 27A[1]: 5 s27A[2]: 2.00 s


Aux. Undervoltage Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Aux-V-Prot/27A[1]]



[Protection Para/Global Prot Para/Aux-V-Prot/27A[1]]

Aux. Undervoltage Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup Residual Voltage Supervision-ElementTrip Signal: TripTripCmd Signal: Trip Command

Commissioning: Aux. Undervoltage

Object to be tested:Aux. undervoltage protection elements.

Necessary components:• Single-phase AC voltage source with adjustable frequency.• Timer for measuring of the tripping time; and• Voltmeter.

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Procedure:

Testing the threshold valueFor measuring criterion »Fundamental« or »True RMS« set the frequency to 50/60 Hz according to the set rated frequency.

For measuring criterion VX meas H3 set the frequency to 150/180 Hz according to the set rated frequency (3 x fn).

To test the threshold and dropout value, the test voltage at the measuring input for the residual voltage has to be decreased until the relay is activated. When comparing the displayed value with this of the voltmeter, the devi-ation must be within the permissible tolerances.

Testing the trip delayFor testing the trip delay, a timer is to be connected to the contact of the associated trip relay. The timer is started when the limiting value of the tripping voltage is reached and it is stopped when the relay trips.

Testing the dropout ratio Increase the measuring quantity to more than 103% of the trip value. The relay must only dropout at a maximum of 103% of the trip value.

Successful test result The measured threshold value, trip delay, and dropout ratio comply with those specified in the adjustment list. Permissible deviations/tolerances can be taken from the Technical Data.

59A - Auxiliary Overvoltage ProtectionAvailable elements:59A[1] ,59A[2]


This is the 59 device Overvoltage setting for the Auxiliary VT. This device setting works exactly the same as the 59M, except it is a single-phase element only operating from the Auxiliary VT input (this element works based on True RMS).

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IM02602013E ETR-5000

Device Planning Parameters of the Aux. Overvoltage Module




Global Protection Parameters of the Aux. Overvoltage Module








Setting Group Parameters of the Aux. Overvoltage Module



Inactive, Active



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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Pickup Vn refers to either the primary or secondary voltage of the aux VT.

Only available if: Device Planning: 59.Mode = V>

0.01 – 1.30 Vn 59A[1]: 1.1 Vn59A[2]: 1.2 Vn


t Tripping delay 0.00 – 300.00 s 59A[1]: 5 s59A[2]: 2.00 s


Aux. Overvoltage Module Input States





[Protection Para/Global Prot Para/Aux-V-Prot/59A[1]]

Aux. Overvoltage Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup Residual Voltage Supervision-ElementTrip Signal: TripTripCmd Signal: Trip Command

Commissioning: Aux. Overvoltage

Object to be tested:Aux. Overvoltage protection elements.

Necessary components:• One-phase AC voltage source;• Timer for measuring of the tripping time; and• Voltmeter.

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Procedure (for each element):

Testing the threshold valuesFor testing the threshold and dropout values, the test voltage at the measuring input for the voltage has to be in-creased until the relay is activated. When comparing the displayed values with those of the voltmeter, the devi-ation must be within the permissible tolerances.

Testing the trip delayFor testing the trip delay a timer is to be connected to the contact of the associated trip relay. The timer is started when the limiting value of the tripping voltage is exceeded and it is stopped when the relay trips.

Testing the dropout ratioReduce the measuring quantity to less than 97% of the trip value. The relay must only dropout at a minimum of 97% of the trip value.

Successful test resultThe measured threshold values, trip delays, and dropout ratios comply with those specified in the adjustment list. Permissible deviations/tolerances can be taken from the Technical Data.

59N - Neutral OvervoltageAvailable elements:


This is the 59 device for the Neutral Overvoltage settings (this element works based on fundamental).

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Commissioning: Neutral Overvoltage Protection

Object to be tested:Neutral overvoltage protection elements.

Necessary components:• One-phase AC voltage source;• Timer for measuring of the tripping time; and• Voltmeter.

Procedure (for each element):

Testing the threshold values For testing the threshold and dropout values, the test voltage at the measuring input for the voltage has to be in-creased until the relay is activated. When comparing the displayed values with those of the voltmeter, the devi-ation must be within the permissible tolerances.

Testing the trip delayFor testing the trip delay, a timer is to be connected to the contact of the associated trip relay. The timer is started when the limiting value of the tripping voltage is exceeded and it is stopped when the relay trips.

Testing the dropout ratioReduce the measuring quantity to less than 97% of the trip value. The relay must only dropout at a minimum of 97% of the trip value.

Successful test resultThe measured threshold values, trip delays, and dropout ratios comply with those specified in the adjustment list. Permissible deviations/tolerances can be taken from the Technical Data.

47 - Voltage Unbalance ProtectionAvailable elements:47[1] ,47[2]

This is the 47 device Voltage Unbalance setting, which consists of the Threshold, %(V2/V1), and Delay settings. The voltage unbalance function is based on the Main VT system 3-phase voltages.

The positive and negative sequence voltages are calculated from the 3-phase voltages. The Threshold setting defines a minimum operating voltage magnitude of either V1 or V2 for the 47 function to operate, which ensures that the relay has a solid basis for initiating a voltage unbalance trip. This is a supervisory function and not a trip level.

The %(V2/V1) setting is the unbalance trip pickup setting. It is defined by the ratio of negative sequence voltage to positive sequence voltage (% Unbalance=V2/V1), or %(V2/V1) for ABC rotation and %(V1/V2) for ACB rotation. The device will automatically select the correct ratio based on the Phase Sequence setting in the System Configuration group described above.

This function requires positive or negative sequence voltage magnitude above the threshold setting and the percentage voltage unbalance above the %(V2/V1) setting before allowing a voltage unbalance trip. Therefore, both the threshold and percent settings must be met for the specified Delay time setting before the relay initiates a trip for voltage unbalance.

The voltage unbalance pickup and trip functions are reset when the positive and negative sequence voltages V1 and V2 drop below the Threshold setting or (V2/V1) drops below the %(V2/V1) setting minus 1%.

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IM02602013E ETR-5000

Device Planning Parameters of the Voltage Unbalance Module


Mode Unbalance Protection: Supervision of the Voltage System

Do not use, Use


Global Protection Parameters of the Voltage Unbalance Module


ExBlo1 External blocking of the module, if blocking is activated (allowed) within a parameter set and if the state of the assigned signal is true.1


ExBlo2 External blocking of the module, if blocking is activated (allowed) within a parameter set and if the state of the assigned signal is true.2




Parameter Set Parameters of the Voltage Unbalance Module



Inactive, Active



Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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Threshold The Threshold defines a minimum operating voltage magnitude of either V1 or V2 for the 47 function to operate, which ensures that the relay has a solid basis for initiating a voltage unbalance trip. This is a supervisory function and not a trip level. The meaning of Vn: Phase to Phase: Vn = Main VT sec. Phase to Ground: Vn = Main VT / SQRT(3).

Only available if: Device Planning: 47.Mode = Threshold

0.01 – 1.30 Vn 0.2 Vn [Protection Para/<1..4>/Unbalance-Prot/47[1]]

%(V2/V1) The %(V2/V1) setting is the unbalance trip pickup setting. It is defined by the ratio of negative sequence voltage to positive sequence voltage (% Unbalance=V2/V1). Phase sequence will be taken into account automatically.

Only available if: %(V2/V1) = Use

2 - 40% 47[1]: 40%47[2]: 20%


t Tripping delay 0.00 – 300.00 s 47[1]: 10.0 s47[2]: 20 s


LOP Blo Measuring Circuit Supervision Inactive, Active


States of the Inputs of the Voltage Unbalance Module






Signals of the Voltage Unbalance Module (States of the Outputs)

Name Description


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Name Description

Blo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup Voltage AsymmetryTrip Signal: TripTripCmd Signal: Trip Command

Commissioning: Voltage Unbalance Module

Object to be tested:Test of the unbalanced load protection function.

Necessary means:• Three-phase AC voltage source with adjustable voltage unbalance; and• Timer.

Procedure:

Check the phase sequence:

• Ensure that the phase sequence is the same as that set in the system parameters.

• Feed-in a three-phase nominal voltage.

• Change to the [Measured Values/Voltage] menu.

• Check the measuring value for the unbalanced voltage »V2 Fund.«. The measuring value displayed for »V2 Fund.« should be zero (within the physical measuring accuracy).

If the displayed magnitude for V2 Fund. is the same as that for the balanced nominal voltages fed to the relay, it implies that the phase sequence of the voltages seen by the relay is reversed.

• Now turn-off phase A.

• Again check the measuring value of the unbalanced voltage »V2 Fund.« in the [Measured Values/Voltage] menu.The measuring value of the unbalanced voltage »V2 Fund.« should now be 33% of the nominal voltage.

• Turn-on phase A, but turn-off phase B.

• Once again check the measuring value of the unbalanced voltage »V2 Fund.« in the [Measured Values/Voltage] menu. The measuring value of the unbalanced voltage »V2 Fund.« should be again 33%.

• Turn-on phase B, but turn-off phase C.

• Again check the measuring value of unbalanced voltage »V2 Fund.« in the [Measured Values/Voltage] menu. The measuring value of the unbalanced voltage »V2 Fund.« should still be 33%.

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• Apply a balanced three-phase voltage system (nominal voltages).

• Switch off VA (the threshold value »Threshold« for »V2 Fund.« must be below 33% of the nominal voltage Vn).

• Measure the tripping time.

The present voltage unbalance »V2 Fund.« corresponds with 1/3 of the existing phase voltage displayed.

Testing the threshold values

• Configure minimum »%(V2/V1)« setting (2%) and an arbitrary threshold value »Threshold« (V2 Fund.).

• For testing the threshold value, a voltage has to be fed to phase A which is lower than three times the adjusted threshold value »Threshold« (V2 Fund.).

• Feeding only phase A results in »%(V2/V1) = 100%«, so the first condition »%(V2/V1) >= 2%« is always fulfilled.

• Now increase the phase A voltage until the relay is activated.

Testing the dropout ratio of the threshold values

Having tripped the relay in the previous test, now decrease the phase A voltage. The dropout ratio must not be higher than 0.97 times the threshold value.

Testing %(V2/V1)

• Configure minimum threshold value »Threshold« (V2 Fund.) (0.01 x Vn) and set »%(V2/V1)« greater or equal to 10%.

• Apply a balanced three-phase voltage system (nominal voltages). The measuring value of »%(V2/V1)« should be approximately 0%.

• Now increase the phase A voltage. With this configuration, the threshold value »Threshold« (V2 Fund.) should be reached before the value »%(V2/V1)« reaches the set »%(V2/V1)« ratio threshold.

• Continue increasing the phase 1 voltage until the relay is activated.

Testing the dropout ratio of %(V2/V1)

Having tripped the relay in the previous test, now decrease the phase A voltage. The dropout of »%(V2/V1)« has to be 1% below the »%(V2/V1)«setting.


The measured trip delays, threshold values, and dropout ratios are within the permitted deviations/tolerances, specified under Technical Data.

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81O/U, 81R, 78V Frequency ProtectionAvailable elements: 81[1] ,81[2] ,81[3] ,81[4] ,81[5] ,81[6]

All frequency protective elements are identically structured.

Frequency - Measuring Principle

The frequency is calculated as the average of the measured values of the three phase frequencies. Only valid measured frequency values are taken into account. If a phase voltage is no longer measurable, this phase will be excluded from the calculation of the average value.

The measuring principle of the frequency supervision is based in general on the time measurement of complete cycles, whereby a new measurement is started at each zero passage. The influence of harmonics on the measuring result is thus minimized.

Frequency tripping is sometimes not desired by low measured voltages which, for instance. occur during alternator acceleration. All frequency supervision functions are blocked if the voltage is lower 0.15 times Vn.

Frequency Functions

Due to its various frequency functions, the device is very flexible. That makes it suitable for a wide range of applications where frequency supervision is an important criterion.

In the Device Planning menu, the User can decide how to use each of the six frequency elements.

f[1] to f[6] can be assigned as:

• 81U – under-frequency;• 81O – over-frequency;• 81R – Rate of Change of Frequency (df/dt);• 81UR – under-frequency and Rate of Change of Frequency (df/dt);• 81OR – over-frequency and Rate of Change of Frequency (df/dt);• 81UΔR – under-frequency and DF/DT (absolute frequency change per definite time interval);• 81OΔR – over-frequency and DF/DT (absolute frequency change per definite time interval); and• 78V – Vector Surge.

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V(t)

t

T

T

ETR-5000 IM02602013E

81U – under-frequency

This protection element provides a pickup threshold and a tripping delay. If the frequency falls below the set pickup threshold, an alarm will be issued instantaneously. If the frequency remains under the set pickup threshold until the tripping delay has elapsed, a tripping command will be issued.

With this setting, the frequency element protects electrical generators, loads, or electrical operating equipment in general against under-frequency.

81O – over-frequency

This protection element provides a pickup threshold and a tripping delay. If the frequency exceeds the set pickup threshold, an alarm will be issued instantaneously. If the frequency remains above the set pickup threshold until the tripping delay has elapsed, a tripping command will be issued.

With this setting, the frequency element protects electrical generators, loads, or electrical operating equipment in general against over-frequency.

Working Principle

(Please refer to the block diagram on next page.)

The frequency element supervises the three phase voltages »VA«, »VB« and »VC«. If all of the three phase voltages are below 15% Vn, the frequency calculation is blocked. According to the frequency supervision mode set in the Device Planning (81U or 81O), the phase voltages are compared to the set pickup threshold for over- or under-frequency. If in any of the phases, the frequency exceeds or falls below the set pickup threshold and if there are no blocking commands for the frequency element, an alarm is issued instantaneously and the tripping delay timer is started. When the frequency still exceeds or is below the set pickup threshold after the tripping delay timer has elapsed, a tripping command will be issued.

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ETR-5000 IM02602013E

81R Rate of Change of Frequency (df/dt)

Electrical generators running in parallel with the mains (e. g.: industrial internal power supply plants) should be separated from the mains when failure in the intra-system occurs for the following reasons:

• Damage to electrical generators must be prevented when mains voltage is recovering asynchronously (e. g.: after a short interruption).

• The industrial internal power supply must be maintained.

A reliable criterion of detecting mains failure is the measurement of the rate of change of frequency 81R (df/dt). The precondition for this is a load flow via the mains coupling point. At mains failure, the load flow change spontaneously leads to an increasing or decreasing frequency. At active power deficit of the internal power station, a linear drop of the frequency occurs and a linear increase occurs at power excess. Typical frequency gradients during application of "mains decoupling" are in the range of 0.5 Hz/s up to over 2 Hz/s.

The protective device detects the instantaneous frequency gradient 81R (df/dt) of each mains voltage period. Through multiple evaluations of the frequency gradient in sequence, the continuity of the directional change (sign of the frequency gradient) is determined. Because of this special measuring procedure, a high safety in tripping and thus a high stability against transient processes (e. g.: switching procedure) are achieved.

The frequency gradient (rate of change of frequency [df/dt]) may have a negative or positive sign, depending on frequency increase (positive sign) or decrease (negative sign).

In the frequency parameter sets, the User can define the kind of df/dt mode:

• Positive df/dt = the frequency element detects an increase in frequency;• Negative df/dt = the frequency element detects a decrease in frequency; and• Absolute df/dt (positive and negative) = the frequency element detects both, increase and decrease in

frequency.

This protection element provides a tripping threshold and a tripping delay. If the frequency gradient df/dt exceeds or falls below the set tripping threshold, an alarm will be issued instantaneously. If the frequency gradient remains still above/below the set tripping threshold until the tripping delay has elapsed, a tripping command will be issued.

Working Principle

(Please refer to block diagram on next page.)

The frequency element supervises the three phase voltages »VA«, »VB« and »VC«. If any of the three phase voltages is below 15% Vn, the frequency calculation is blocked. According to the frequency supervision mode set in the Device Planning (81R), the phase voltages are compared to the set frequency gradient (df/dt) threshold. If in any of the phases, the frequency gradient exceeds or falls below the set pickup threshold (acc. to the set df/dt mode) and if there are no blocking commands for the frequency element, an alarm is issued instantaneously and the tripping delay timer is started. When the frequency gradient still exceeds or is below the set pickup threshold after the tripping delay timer has elapsed, a tripping command will be issued.

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ETR-5000 IM02602013E

81UR – under-frequency and Rate of Change of Frequency (df/dt)

With this setting, the frequency element supervises if the frequency falls below a set pickup threshold and if the frequency gradient exceeds a set threshold at the same time.

In the selected frequency parameter set 81[X], an under-frequency pickup threshold f<, a frequency gradient df/dt, and a tripping delay can be set.

Whereby:

• Positive df/dt = the frequency element detects an increase in frequency;• Negative df/dt = the frequency element detects a decrease in frequency; and • Absolute df/dt (positive and negative) = the frequency element detects both, increase and decrease in

frequency.

81OR – over-frequency and Rate of Change of Frequency (df/dt)

With this setting, the frequency element supervises if the frequency exceeds a set pickup threshold and if the frequency gradient exceeds a set threshold at the same time.

In the selected frequency parameter set 81[X], an over-frequency pickup threshold f>, a frequency gradient df/dt, and a tripping delay can be set.

Whereby:

• Positive df/dt = the frequency element detects an increase in frequency;• Negative df/dt = the frequency element detects a decrease in frequency; and• Absolute df/dt (positive and negative) = the frequency element detects both, increase and decrease in

frequency.

Working Principle


The frequency element supervises the three phase voltages »VA«, »VB« and »VC«. If any of the three phase voltages is below 15% Vn, the frequency calculation is blocked. According to the frequency supervision mode set in the Device Planning (81UR & df/dt or 81OR & dt/dt), the phase voltages are compared to the set frequency pickup threshold and the set frequency gradient (df/dt) threshold. If in any of the phases, both the frequency and the frequency gradient exceed or falls below the set thresholds and if there are no blocking commands for the frequency element, an alarm is issued instantaneously and the tripping delay timer is started. When the frequency and the frequency gradient still exceed or are below the set threshold after the tripping delay timer has elapsed, a tripping command will be issued.

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ETR-5000 IM02602013E

81UΔR – under-frequency and DF/DT

With this setting, the frequency element supervises the frequency and the absolute frequency difference during a definite time interval.

In the selected frequency parameter set 81[X], an under-frequency pickup threshold f<, a threshold for the absolute frequency difference (frequency decrease) DF and supervision interval DT can be set.

81OΔR – over-frequency and DF/DT

With this setting, the frequency element supervises the frequency and the absolute frequency difference during a definite time interval.

In the selected frequency parameter set 81[X], an over-frequency pickup threshold f>, a threshold for the absolute frequency difference (frequency increase) DF and supervision interval DT can be set.

Working Principle


The frequency element supervises the three phase voltages »VA«, »VB« and »VC«. If any of the three phase voltages is below 15% Vn, the frequency calculation is blocked. According to the frequency supervision mode set in the Device Planning (81UR & DF/DT or 81OR & DF/DT), the phase voltages are compared to the set frequency pickup threshold and the set frequency decrease or increase threshold DF.

If in any of the phases, the frequency exceeds or falls below the set pickup threshold and if there are no blocking commands for the frequency element, an alarm is issued instantaneously. At the same time the timer for the supervision interval DT is started. When, during the supervision interval DT, the frequency still exceeds or is below the set pickup threshold and the frequency decrease/increase reaches the set threshold DF, a tripping command will be issued.

Working Principle of DF/DT Function

(Please refer to f(t) diagram after the block diagram.)

Case 1:When the frequency falls below a set f< threshold (81U) at t1, the DF/DT element energizes. If the frequency difference (decrease) does not reach the set value DF before the time interval DT has expired, no trip will occur. The frequency element remains blocked until the frequency falls below the under-frequency threshold f< (81U) again.

Case 2:When the frequency falls below a set f< threshold (81U) at t4, the DF/DT element energizes. If the frequency difference (decrease) reaches the set value DF before the time interval DT has expired (t5), a trip command is issued.

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ETR-5000 IM02602013E

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IM02602013E ETR-5000

78V Vector Surge

The vector surge supervision protects synchronous generators in mains parallel operation due to very fast decoupling in case of mains failure. Very dangerous are mains auto reclosings for synchronous generators. The mains voltage returning typically after 300 ms can hit the generator in asynchronous position. A very fast decoupling is also necessary in case of long time mains failures.

Generally there are two different applications.

• Only mains parallel operation - no single operation:In this application, the vector surge supervision protects the generator by tripping the generator breaker in case of mains failure.

• Mains parallel operation and single operation:For this application, the vector surge supervision trips the mains breaker. Here it is insured that the gen.-set is not blocked when it is required as an emergency set.

A very fast decoupling in case of mains failures for synchronous generators is very difficult. Voltage supervision units cannot be used because the synchronous alternator, as well as the load impedance, support the decreasing voltage.

In this situation, the mains voltage drops only after some 100 ms below the pickup threshold of the voltage supervision and, therefore, a safe detection of mains auto reclosings is not possible with voltage supervision only.

Frequency supervision is partially unsuitable because only a highly loaded generator decreases its speed within 100 ms. Current relays detect a fault only when short-circuit type currents exist, but cannot avoid their development. Power relays are able to pickup within 200 ms, but they also cannot prevent the power from rising to short-circuit values. Since power changes are also caused by sudden loaded alternators, the use of power relays can be problematic.

Whereas the vector surge supervision of the device detects mains failures within 60 ms without the restrictions described above because it is specially designed for applications where very fast decoupling from the mains is required. Adding the typical operating time of a breaker or contactor, the total disconnection time remains below 150 ms.

Basic requirement for tripping of the generator/mains monitor is a change in load of more than 15 - 20% of the rated load. Slow changes of the system frequency, for instance at regulating processes (adjustment of speed regulator), do not cause the relay to trip.

Trippings can also be caused by short-circuits within the grid, because a voltage vector surge higher than the preset value can occur. The magnitude of the voltage vector surge depends on the distance between the short-circuit and the generator. This function is also of advantage to the Power Utility Company because the mains short-circuit capacity and, consequently, the energy feeding the short-circuit is limited.

To prevent a possible false tripping, the vector surge measuring is blocked at a low input voltage <15% Vn. The undervoltage lockout acts faster then the vector surge measurement.

Vector surge tripping is blocked by a phase loss so that a VT fault (e. g.: faulty VTs fuse) does not cause false tripping.

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Measuring Principle of Vector Surge Supervision

Equivalent circuit at synchronous generator in parallel with the mains.

Voltage vectors at mains parallel operation.

The rotor displacement angle between stator and rotor is dependent on the mechanical moving torque of the generator shaft. The mechanical shaft power is balanced with the electrical fed mains power and, therefore, the synchronous speed keeps constant.

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Grid/Load

Generator

VPV1

V = I1* j Xd

Grid

V = I1* j Xd

VP V1

I1 I2

IM02602013E ETR-5000

Equivalent circuit at mains failure.

In case of mains failure or auto-reclosing, the generator suddenly feeds a very high load. The rotor displacement angle is decreased repeatedly and the voltage vector V1 changes its direction (V1').

Voltage vectors at mains failure.

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Generator Load

VPV1 V´1

V´ = I´1* j Xd

Grid

V´ = I´1* j Xd

VP V´1

I1

ETR-5000 IM02602013E

Voltage vector surge.

As shown in the voltage/time diagram, the instantaneous value of the voltage jumps to another value and the phase position changes. This is called phase or vector surge.

The relay measures the cycle duration. A new measuring is started at each zero passage. The measured cycle duration is internally compared with a reference time and from this the deviation of the cycle duration of the voltage signal is ascertained. In case of a vector surge as shown in the above graphic, the zero passage occurs either earlier or later. The established deviation of the cycle duration is in compliance with the vector surge angle. If the vector surge angle exceeds the set value, the relay trips immediately.

Tripping of the vector surge is blocked in case of loss of one or more phases of the measuring voltage.

Working Principle


The vector surge element supervises the three phase voltages »VA«, »VB« and »VC«. If any of the three phase voltages is below 15% Vn, the vector surge calculation is blocked. According to the frequency supervision mode set in the Device Planning (78V), the phase voltages are compared to the set vector surge threshold. If in any of the phases, the vector surge exceeds the set threshold and if there are no blocking commands for the frequency element, an alarm and a trip command is issued instantaneously.

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V(t) V(t) V(t)`

Trip

tt=0

78V vector surge

Voltage Vector Surge

IM02602013E ETR-5000

514 www.eaton.com

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ETR-5000 IM02602013E

Device Planning Parameters of the Frequency Protection Module


Mode Mode Do not use, 81U-Under, 81O-Over, 81UR- Under & df/dt, 81OR- Over & df/dt, 81UDR- Under & DF/DT, 81ODR- Over & DF/DT, 81R-Rate of Change, 78V vector surge

81[1]: 81O-Over81[2]: 81O-Over81[3]: 81U-Under81[4]: 81U-Under81[5]: 81R-Rate of Change81[6]: 81R-Rate of Change

[Device Planning]

Global Protection Parameters of the Frequency Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Freq-Prot/81[1]]





Setting Group Parameters of the Frequency Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/Freq-Prot/81[1]]


Inactive, Active



Inactive, Active


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ExBlo TripCmd Fc


Inactive, Active


81O-Over Pickup value for over-frequency.

Only available if: Device Planning: 81.Mode = 81O-Over Or 81OR- Over & df/dt Or 81ODR- Over & DF/DT

40.00 – 69.95 Hz 81[1]: 61.00 Hz81[2]: 61.0 Hz81[3]: 51.00 Hz81[4]: 51.00 Hz81[5]: 51.00 Hz81[6]: 51.00 Hz

[Protection Para/<1..4>/Freq-Prot/81[1]]

81U-Under Pickup value for under-frequency.

Only available if: Device Planning: 81.Mode = 81U-Under Or 81UR- Under & df/dt Or 81UDR- Under & DF/DT

40.00 – 69.95 Hz 81[1]: 59.0 Hz81[2]: 49.00 Hz81[3]: 59.0 Hz81[4]: 59.0 Hz81[5]: 59.0 Hz81[6]: 59.0 Hz

[Protection Para/<1..4>/Freq-Prot/81[1]]

t Tripping delay

Only available if: Device Planning: 81.Mode = 81U-Under Or 81O-OverOr 81OR- Over & df/dt Or 81UR- Under & df/dt

0.00 – 3600.00 s 1.00 s [Protection Para/<1..4>/Freq-Prot/81[1]]

81R-Rate of Change

Measured value (calculated): Rate-of-frequency-change.

Only available if: Device Planning: 81.Mode = 81R-Rate of Change Or 81UR- Under & df/dt Or 81OR- Over & df/dt

0.1 – 10.0 Hz/s 1.0 Hz/s [Protection Para/<1..4>/Freq-Prot/81[1]]

t-df/dt Trip delay df/dt 0.00 – 300.00 s 1.00 s [Protection Para/<1..4>/Freq-Prot/81[1]]

DF Frequency difference for the maximum admissable variation of the mean of the rate of frequency-change. This function is inactive if DF=0.

Only available if: Device Planning: 81.Mode = 81UDR- Under & DF/DT Or 81ODR- Over & DF/DT

0.0 – 10.0 Hz 1.00 Hz [Protection Para/<1..4>/Freq-Prot/81[1]]

DT Time interval of the maximum admissable rate-of-frequency-change.

Only available if: Device Planning: 81.Mode = 81UDR- Under & DF/DT Or 81ODR- Over & DF/DT

0.1 – 10.0 s 1.00 s [Protection Para/<1..4>/Freq-Prot/81[1]]

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df/dt Mode df/dt Mode

Only available if: Device Planning: 81.Mode = 81R-Rate of Change Or 81UR- Under & df/dt Or 81OR- Over & df/dt Only available if: Device Planning: 81.Mode = 81R-Rate of Change Or 81UR- Under & df/dt Or 81OR- Over & df/dt Only available if: Device Planning: 81.Mode = 81R-Rate of Change

Absolute df/dt, Positive df/dt, Negative df/dt

Absolute df/dt [Protection Para/<1..4>/Freq-Prot/81[1]]

78V vector surge

Measured Value (Calculated): Vector Surge

Only available if: Device Planning: 81.Mode = 78V vector surge

1 - 30° 10° [Protection Para/<1..4>/Freq-Prot/81[1]]

Frequency Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Freq-Prot/81[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Freq-Prot/81[1]]


[Protection Para/Global Prot Para/Freq-Prot/81[1]]

Frequency Protection Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo by V< Signal: Module is blocked by undervoltage.Blo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup 81 Signal: Pickup Frequency ProtectionPickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change Pickup Vector Surge Signal: Pickup Vector SurgePickup Signal: Pickup Frequency Protection (collective signal)Trip 81 Signal: Frequency has exceeded the limit.Trip df/dt | DF/DT Signal: Trip df/dt or DF/DTTrip Vector Surge Signal: Trip delta phiTrip Signal: Trip Frequency Protection (collective signal)

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Name Description

TripCmd Signal: Trip Command

Commissioning: over-frequency [ANSI 81O]

Object to be tested:All configured over-frequency protection stages.

Necessary means:• Three-phase voltage source with variable frequency; and• Timer

Procedure:

Testing the threshold values• Keep on increasing the frequency until the respective frequency element is activated;• Note the frequency value; and• Disconnect the test voltage.

Testing the trip delay• Set the test voltage to nominal frequency and• Now connect a frequency jump (activation value) and then start a timer. Measure the tripping time at the

relay output.

Testing the drop-out ratio:Reduce the measuring quantity to less than 99.95% of the trip value (or 0.05% fn). The relay must only fall back at 99.95% of the trip value at the earliest (or 0.05% fn).

Successful test result:Permissible deviations/tolerances can be taken from the Technical Data.

Commissioning: Under-frequency [ANSI 81U]

For all configured under-frequency elements, this test can be carried out similar to the test for over-frequency protection (by using the related under-frequency values).

Please consider the following deviations:

• For testing the threshold values, the frequency has to be decreased until the protection element is activated.

• For detection of the drop-out ratio, the measuring quantity has to be increased to more than 100.05% of the trip value (or 0.05% fn). At 100.05% of the trip value the relay is to fall back at the earliest (or 0.05% fn).

Commissioning: 81R Rate of Change (df/dt)

Object to be tested:All frequency protection stages that are projected as df/dt.

Necessary means:• Three-phase voltage source and

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• Frequency generator that can generate and measure a linear, defined rate of change of frequency.

Procedure:

Testing the threshold values• Keep on increasing the rate of change of frequency until the respective element is activated and• Note the value.

Testing the trip delay • Set the test voltage to nominal frequency:• Now apply a step change (sudden change) that is 1.5 times the setting value (example: apply 3 Hz per

second if the setting value is 2 Hz per second); and• Measure the tripping time at the relay output. Compare the measured tripping time to the configured

tripping time.

Successful test result:Permissible deviations/tolerances and dropout ratios can be taken from the Technical Data.

Commissioning: 81U and Rate of Change (f< and -df/dt)

Object to be tested:All frequency protection stages that are projected as f< and -df/dt.

Necessary means:• Three-phase voltage source and• Frequency generator that can generate and measure a linear, defined rate of change of frequency.

Procedure:

Testing the threshold values• Feed nominal voltage and nominal frequency to the device:• Decrease the frequency below the f< threshold: and• Apply a rate of change of frequency (step change) that is below the setting value (example: apply -1 Hz

per second if the setting value is -0.8 Hz per second). After the tripping delay is expired the relay has to trip.


Commissioning: 81O and Rate of Change (f> and df/dt)

Object to be tested:All frequency protection stages that are projected as f> and df/dt.

Necessary means:• Three-phase voltage source and• Frequency generator that can generate and measure a linear, defined rate of change of frequency.

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Procedure:

Testing the threshold values• Feed nominal voltage and nominal frequency to the device;• Increase the frequency above the f> threshold; and• Apply a rate of change of frequency (step change) that is above the setting value (example: apply 1 Hz

per second if the setting value is 0.8 Hz per second). After the tripping delay is expired the relay has to trip.


Commissioning: 81UΔR – Under-frequency and DF/DT

Object to be tested:All frequency protection stages that are projected as f< and Df/Dt.

Necessary means:• Three-phase voltage source and• Frequency generator that can generate and measure a defined frequency change.

Procedure:

Testing the threshold values• Feed nominal voltage and nominal frequency to the device;• Decrease the frequency below the f< threshold; and• Apply a defined frequency change (step change) that is above the setting value (example: apply a

frequency change of 1 Hz during the set time interval DT if the setting value DF is 0.8 Hz ). The relay has to trip immediately.


Commissioning: 81OΔR – Over-frequency and DF/DT

Object to be tested:All frequency protection stages that are projected as f> and Df/Dt.

Necessary means:• Three-phase voltage source and• Frequency generator that can generate and measure a defined frequency change.

Procedure:

Testing the threshold values• Feed nominal voltage and nominal frequency to the device;• Increase the frequency above the f> threshold; and• Apply a defined frequency change (step change) that is above the setting value (example: apply a

frequency change of 1 Hz during the set time interval DT if the setting value DF is 0.8 Hz ). The relay has to trip immediately.

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Commissioning: Vector Surge 78V

Object to be tested:All frequency protection stages that are projected as vector surge (78V).

Necessary means:• Three-phase voltage source that can generate a definite step (sudden change) of the voltage pointers

(phase shift).

Procedure:

Testing the threshold values • Apply a vector surge (sudden change) that is 1.5 times the setting value (example: if the setting value is

10° apply 15°).

Successful test result:Permissible deviations/tolerances and dropout ratio can be taken from the Technical Data.

32 - Power ProtectionAvailable Elements:32[1] ,32[2] ,32[3]

This is the 32 device Power Protection setting. Each element can be set to one of five settings:

• Do Not Use;• Over Forward Power (P>);• Under Forward Power (P<);• Over Reverse Power (Pr>); and• Under Reverse Power (Pr<).

Each element consists of a Pickup and a Delay setting. These elements are based on rated apparent power VAn.

Definition for VAn is as follows:

VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye; or

VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

The following graphics show the areas that are protected by the corresponding modes.

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32 - Forward Power - Over and Under

522 www.eaton.com

Q

P

Trip Region

Pickup P>

Q

P

Trip Region

Pickup P<

No Trip

No Trip

ETR-5000 IM02602013E

32 - Reverse Power - Over and Under

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Q

P

Trip Region

Pickup Pr>

Q

P

Trip Region

Pickup Pr<

No Trip

No Trip

IM02602013E ETR-5000

524 www.eaton.com

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ETR-5000 IM02602013E

Device Planning Parameters of the Power Protection Module


Mode Mode Do not use, Over forward, Under forward, Over reverse, Under reverse

32[1]: Over forward32[2]: Under forward32[3]: Over reverse

[Device Planning]

Global Protection Parameters of the Power Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Power-Prot/32[1]]





Parameter Set Parameters of the Power Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/Power-Prot/32[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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LOP Blo Measuring Circuit Supervision Voltage Inactive, Active


CTS Blo Measuring Circuit Supervision Current Inactive, Active


Pickup P> Over(load) Active Power Pickup Value. Can be used for monitoring the maximum allowed forward power limits of transformers or overhead lines. Definition for VAn is as follows: VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye or VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

Only available if: Device Planning: PQS.Mode = Pickup P>

0.02 – 10.00 VAn 1.20 VAn [Protection Para/<1..4>/Power-Prot/32[1]]

Pickup P< Under(load) Active Power Pickup Value (e.g.: caused by idling motors). Definition for VAn is as follows: VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye or VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

Only available if: Device Planning: PQS.Mode = Pickup P<


Pickup Pr> Over Reverse Definition for VAn is as follows: VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye or VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

Only available if: Device Planning: PQS.Mode = Pickup Pr>


Pickup Pr< Under Reverse Definition for VAn is as follows: VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye or VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

Only available if: Device Planning: PQS.Mode = Pickup Pr<


t Tripping delay 0.00 – 1100.00 s 0.01 s [Protection Para/<1..4>/Power-Prot/32[1]]

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States of the Inputs of the Power Protection Module


ExBlo1-I Module Input State: External Blocking [Protection Para/Global Prot Para/Power-Prot/32[1]]

ExBlo2-I Module Input State: External Blocking [Protection Para/Global Prot Para/Power-Prot/32[1]]


[Protection Para/Global Prot Para/Power-Prot/32[1]]

Signals of the Power Protection Module (States of the Outputs)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup Power ProtectionTrip Signal: Trip Power ProtectionTripCmd Signal: Trip Command

Commissioning Examples for the Power Protection Module


Testing the projected Power Protection Modules:

• P>;• P<;• Pr>; and• Pr<.

Necessary means:

• 3-phase AC voltage source ;• 3-phase AC current source; and• Timer.

Procedure – Testing the wiring:

• Feed rated voltage and rated current to the measuring inputs of the relay.

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• Adjust the current pointers 30 degrees lagging to the voltage pointers.

• The following measuring values have to be shown:• P=0.86 Pn;• Q=0.5 Qn; and• S=1 Sn.

If the measured values are shown with a negative (algebraic) sign, check the wiring.

The examples shown within this chapter have to be carried out with the tripping values and tripping delays that apply to the User's switchboard.

If the User is testing „greater than thresholds“ (e.g.: P>), start at 80% of the tripping value and increase the object to be tested until the relay picks up.

In case the User is testing „less than thresholds“ (e.g.: P<), start at 120% of the tripping value and reduce the object to be tested until the relay picks up.

If the User is testing tripping delays of „greater than“ modules (e.g.: P>), start a timer simultaneously with an abrupt change of the object to be tested from 80% of the tripping value to 120% of the tripping value.

If the User is testing tripping delays of „less than“ modules (e.g.: P<), start a timer simultaneously with an abrupt change of the object to be tested from 120% of the tripping value to 80% of the tripping value.

P>

Testing the threshold values (Example, Threshold 1.1 Pn)

• Feed rated voltage and 0.9 times rated current in phase to the measuring inputs of the relay (PF=1).

• The measured values for the active power „P“ must show a positive algebraic sign.

• Set the pickup threshold (e.g.: 1.1 Pn).

• In order to test the pickup thresholds, feed 0.9 times rated current to the measuring inputs of the relay. Increase the current slowly until the relay picks up. Ensure that the angle between current and voltage remains constant. Compare the measured pickup value to the configured value.

Testing the tripping delay (Example, Threshold 1.1 Pn)




• In order to test the tripping delay, feed 0.9 times rated current to the measuring inputs of the relay. Increase the current with an abrupt change to 1.2 In. Ensure that the angle between current and voltage remains constant. Measure the tripping delay at the output of the relay.

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The measured total tripping delays or individual tripping delays, threshold values, and dropout ratios correspond with those values specified in the adjustment list. Permissible deviations/tolerances can be found in the Tech-nical Data section.

P<





• In order to test the pickup thresholds, feed 0.5 times rated current to the measuring inputs of the relay. Decrease the current slowly until the relay picks up. Ensure that the angle between current and voltage remains constant. Compare the measured pickup value to the configured.





• In order to test the tripping delay feed, 0.5 times rated current to the measuring inputs of the relay. Decrease the current with an abrupt change to 0.2 In. Ensure that the angle between current and voltage remains constant. Measure the tripping delay at the output of the relay.



Pr>


• Feed rated voltage and 0.9 times rated current with 180 degree phase angle between voltage and current pointers to the measuring inputs of the relay.

• The measured values for the active power „P“ must show a negative algebraic sign.

• Set the pickup threshold (e. g.: 1.1 Pn).

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• Feed rated voltage and 0.9 times rated current with 180 degree phase shift between voltage and current pointers to the measuring inputs of the relay.






Pr<




• Set the pickup threshold (e. g.: 0.3 Pn).

• In order to test the pickup thresholds, feed 0.5 times rated current to the measuring inputs of the relay. Decrease the current slowly until the relay picks up. Ensure that the angle between current and voltage remains constant. Compare the measured pickup value to the configured value.





• In order to test the tripping delay, feed 0.5 times rated current to the measuring inputs of the relay. Decrease the current with an abrupt change to 0.2 In. Ensure that the angle between current and voltage remains constant. Measure the tripping delay at the output of the relay.


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32V - Reactive Power ProtectionAvailable Elements:32V[1] ,32V[2] ,32V[3]

This is the 32V device Reactive Power Protection setting. Each element can be set to one of five settings:

• Do Not Use;• Over Forward Reactive Power (Q>);• Under Forward Reactive Power (Q<);• Over Reverse Reactive Power (Qr>); and• Under Reverse Reactive Power (Qr<).

Each element consists of a Pickup and a Delay setting. These elements are based on rated apparent power Van.

Definition for VAn is as follows:

VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye; or

VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

The following graphics show the areas that are protected by the corresponding modes.

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32V Forward Reactive Power - Over and Under

532 www.eaton.com

Q

P

P

Q

Trip Region

No Trip

Trip Region

No Trip

Pickup Q>

Pickup Q<

.

ETR-5000 IM02602013E

32V Reverse Reactive Power - Over and Under

www.eaton.com 533

Q

P

Trip Region

No Trip

Pickup Qr>

Q

P

Trip Region

No Trip

Pickup Qr<

IM02602013E ETR-5000

534 www.eaton.com

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ETR-5000 IM02602013E

Device Planning Parameters of the Reactive Power Protection Module


Mode Mode Do not use, Over forward, Under forward, Over reverse, Under reverse

32V[1]: Over forward32V[2]: Under forward32V[3]: Over reverse

[Device Planning]

Global Protection Parameters of the Reactive Power Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Power-Prot/32V[1]]





Parameter Set Parameters of the Reactive Power Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/Power-Prot/32V[1]]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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LOP Blo Measuring Circuit Supervision Voltage Inactive, Active


CTS Blo Measuring Circuit Supervision Current Inactive, Active


Pickup Q> Over(load) Reactive Power Pickup Value. Monitoring the maximum allowed reactive power of the electrical equipment like transformers or overhead lines). If the maximum value is exceeded, a condensator bank could be switched off. Definition for VAn is as follows: VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye or VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

Only available if: Device Planning: PQS.Mode = Pickup Q>

0.02 – 10.00 VAn 1.20 VAn [Protection Para/<1..4>/Power-Prot/32V[1]]

Pickup Q< Under(load) Reactive Power Pickup Value. Monitoring the minimum value of the reactive power. If it falls below the set value, a condensator bank could be switched on. Definition for VAn is as follows: VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye or VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

Only available if: Device Planning: PQS.Mode = Pickup Q<


Pickup Qr> Over Reverse Definition for VAn is as follows: VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye or VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

Only available if: Device Planning: PQS.Mode = Pickup Qr>


Pickup Qr< Under Reverse Definition for VAn is as follows: VAn = SQRT(3) * VT secondary rating * CT secondary rating (I=1/5A) for wye or VAn = 3 * VT secondary rating/SQRT(3) * CT secondary rating (I=1/5A) for delta connections.

Only available if: Device Planning: PQS.Mode = Pickup Qr<


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t Tripping delay 0.00 – 1100.00 s 0.01 s [Protection Para/<1..4>/Power-Prot/32V[1]]

States of the Inputs of the Reactive Power Protection Module


ExBlo1-I Module Input State: External Blocking [Protection Para/Global Prot Para/Power-Prot/32V[1]]

ExBlo2-I Module Input State: External Blocking [Protection Para/Global Prot Para/Power-Prot/32V[1]]


[Protection Para/Global Prot Para/Power-Prot/32V[1]]

Signals of the Reactive Power Protection Module (States of the Outputs)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandPickup Signal: Pickup Power ProtectionTrip Signal: Trip Power ProtectionTripCmd Signal: Trip Command

Commissioning Examples for the Reactive Power Protection Module


Testing the projected Power Protection Modules.

• Q>;• Q<;• Qr>; and• Qr<.

Necessary means:

• 3-phase AC voltage source;• 3-phase AC current source; and• Timer.

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Procedure – Testing the wiring:

• Feed rated voltage and rated current to the measuring inputs of the relay.

• Adjust the current pointers 30° lagging to the voltage pointers.

• The following measuring values have to be shown:• P=0.86 Pn;• Q=0.5 Qn; and• S=1 Sn.

If the measured values are shown with a negative (algebraic) sign, check the wiring.

The examples shown within this chapter have to be carried out with the tripping values and tripping delays that apply to the User's switchboard.

If the User is testing „greater than thresholds“ (e.g.: Q>), start at 80% of the tripping value and increase the object to be tested until the relay picks up.

In case the User is testing „less than thresholds“ (e.g.: Q<), start at 120% of the tripping value and reduce the object to be tested until the relay picks up.

If the User is testing tripping delays of „greater than“ modules (e.g.: Q>), start a timer simultaneously with an abrupt change of the object to be tested from 80% of the tripping value to 120% of the tripping value.

If the User is testing tripping delays of „less than“ modules (e.g.: Q<), start a timer simultaneously with an abrupt change of the object to be tested from 120% of the tripping value to 80% of the tripping value.

Q>

Testing the threshold values (Example, Threshold 1,1 Qn)

• Feed rated voltage and 0.9 times rated current (90 degrees phase shift) to the measuring inputs of the relay (PF=0).

• The measured values for the active power „Q“ must show a positive algebraic sign.

• Set the pickup threshold (e.g.: 1.1. Qn).


Testing the tripping delay (Example, Threshold 1.1 Qn)

• Feed rated voltage and 0.9 times rated current (90 degree phase shift) to the measuring inputs of the relay (PF=0).


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• Set the pickup threshold (e.g. 1.1. Qn).




Q<

Testing the threshold values (Example, Threshold 0.3 Qn)



• Set the pickup threshold (e.g.: 0.3 Qn).





• Set the pickup threshold (e.g.: 0.3 Qn).




Qr>


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• Feed rated voltage and 0.9 times rated current with -90 degree phase shift between voltage and current pointers to the measuring inputs of the relay.

• The measured values for the active power „Q“ must show a negative algebraic sign.

• Set the pickup threshold (e. g.: 1.1 Qn).





• Set the pickup threshold (e. g. 1.1 Qn).




Qr<




• Set the pickup threshold (e. g.: 0.3 Qn).





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• Set the pickup threshold (e. g. 0.3 Qn).




55A and 55DAvailable elements:

Definition Apparent Power Factor 55A (RMS - Includes Harmonics):

The Apparent Power Factor is computed by dividing real power (watts) by volt-amperes. The apparent power factor computation includes harmonics.

PF apparent=WattVA

Definition Displacement Power Factor 55D (Fundamental):

The Displacement Power Factor is computed by dividing the fundamental watts by the fundamental volt-amperes as shown below. This definition is only valid at the system fundamental operating frequency. The Displacement Power Factor isolates the fundamental portion of the Power Factor from the effects of harmonics.

PF displacement=Watt

Watt 2var2

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ExP - External ProtectionAvailable elements:ExP[1] ,ExP[2] ,ExP[3] ,ExP[4]

All elements of the external protection ExP[1]...[4] are identically structured.

By means of these elements, the protective device can detect and execute pickups and trips that are issued by other external devices. This can be helpful, for logging purposes, if the other device is not equipped with an event or waveform recorder. This might also be helpful if the other device has no communication (SCADA) interface.

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Q

P

leading

leading

lagging

lagging

PF>0

PF>0 PF<0

PF<0

0°<phi<90°

270°<phi<360°

90°<phi<180°

180°<phi<270°

ETR-5000 IM02602013E

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1..n

, Ass

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ent L

ist

Nam

e.Al

arm

Nam

e.Tr

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1..n

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AND

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-I2 3

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Device Planning Parameters of the External Protection Module



Do not use [Device Planning]

Global Protection Parameters of the External Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/ExP/ExP[1]]





Alarm Assignment for External Alarm 1..n, Assignment List -.- [Protection Para/Global Prot Para/ExP/ExP[1]]

Trip External trip of the Bkr. if the state of the assigned signal is true.


Setting Group Parameters of the External Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/ExP/ExP[1]]


Inactive, Active



Inactive, Active


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ExBlo TripCmd Fc


Inactive, Active


External Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/ExP/ExP[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/ExP/ExP[1]]


[Protection Para/Global Prot Para/ExP/ExP[1]]

Alarm-I Module Input State: Alarm [Protection Para/Global Prot Para/ExP/ExP[1]]

Trip-I Module Input State: Trip [Protection Para/Global Prot Para/ExP/ExP[1]]

External Protection Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandAlarm Signal: AlarmTrip Signal: TripTripCmd Signal: Trip Command

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Commissioning: External Protection


• Test of the External Protection Module.

Necessary means:

• Dependent on the application.

Procedure:

• Simulate the functionality of the External Protection (pickup, trip, and blockings) by (de-)energizing the digital inputs.


All external pickups, external trips, and external blockings are correctly recognized and processed by the device.

Ext Temp Superv – External Temperature SupervisionElements:Ext Temp Superv[1] ,Ext Temp Superv[2] ,Ext Temp Superv[3]

All elements of the external protection Ext Temp Superv are identically structured.

By using the Ext Temp Superv module, the following can be incorporated into the device function: trip commands, alarms (pickups), and blockages of digital external temperature protection.

Since the Ext Temp Superv module is functionally identical to the Ext. Protection module, it is the User’s responsibility to select the proper assignments for the settings Alarm (Pickup) and Trip for reflecting the purpose of this module.

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-I2 3

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Device Planning Parameters of the External Temperature Supervision Module




Global Protection Parameters of the External Temperature Supervision Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Temp-Prot/Ext Temp Superv[1]]





Alarm Assignment for External Alarm 1..n, Assignment List -.- [Protection Para/Global Prot Para/Temp-Prot/Ext Temp Superv[1]]



Setting Group Parameters of the External Temperature Supervision Module



Inactive, Active

Inactive [Protection Para/<1..4>/Temp-Prot/Ext Temp Superv[1]]


Inactive, Active



Inactive, Active


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ExBlo TripCmd Fc


Inactive, Active


External Temperature Supervision Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Temp-Prot/Ext Temp Superv[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Temp-Prot/Ext Temp Superv[1]]


[Protection Para/Global Prot Para/Temp-Prot/Ext Temp Superv[1]]

Alarm-I Module Input State: Alarm [Protection Para/Global Prot Para/Temp-Prot/Ext Temp Superv[1]]

Trip-I Module Input State: Trip [Protection Para/Global Prot Para/Temp-Prot/Ext Temp Superv[1]]

External Temperature Supervision Module Signals (Output States)

Name Description


Commissioning: External Temperature Supervision

Object to be tested:• Test of the External Temperature Supervision module.

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Necessary means:• Dependent on the application.

Procedure:• Simulate the functionality of the External Temperature Supervision (pickup, trip, blockings) by

(de-)energizing of the digital inputs.

Successful test result:All external pickups, external trips, and external blockings are correctly recognized and processed by the device.

Ext Oil Temp – External Oil Temperature ProtectionAvailable elements:Ext Oil Temp

By using the Ext Oil Temp module, the following can be incorporated into the device function: trip commands, alarms (pickups), and blockages of digital external temperature facilities.

Since the Ext Oil Temp module is functionally identical to the Ext. Protection module, it is the User’s responsibility to select the proper assignments for the settings Alarm (Pickup) and Trip for reflecting the purpose of this module.

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Device Planning Parameters of the External Oil Temperature Protection Module




Global Protection Parameters of the External Oil Temperature Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Temp-Prot/Ext Oil Temp]





Alarm Assignment for External Alarm 1..n, Assignment List -.- [Protection Para/Global Prot Para/Temp-Prot/Ext Oil Temp]



Setting Group Parameters of the External Oil Temperature Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/Temp-Prot/Ext Oil Temp]


Inactive, Active



Inactive, Active


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ExBlo TripCmd Fc


Inactive, Active


External Oil Temperature Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Temp-Prot/Ext Oil Temp]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Temp-Prot/Ext Oil Temp]


[Protection Para/Global Prot Para/Temp-Prot/Ext Oil Temp]

Alarm-I Module Input State: Alarm [Protection Para/Global Prot Para/Temp-Prot/Ext Oil Temp]

Trip-I Module Input State: Trip [Protection Para/Global Prot Para/Temp-Prot/Ext Oil Temp]

External Oil Temperature Protection Module Signals (Output States)

Name Description


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Commissioning: External Protection

Object to be tested:• Test of the External Oil Temperature Protection module.


Procedure:• Simulate the functionality of the External Oil Temperature Protection (pickup, trip, blockings) by

(de-)energizing of the digital inputs.


Sudden Pressure ProtectionAvailable elements:Sudden Press


Most large size transformers (5000 KVA or above) are recommended to be equipped with a sudden pressure relay that detects rapid change in oil or gas pressure within the tank as result of internal arcing. The sudden pressure relay can detect internal faults such as turn to turn faults that other protection functions such as differential and overcurrents may not be sensitive enough to sense. The sudden pressure relay is usually equipped with output contacts that can be directly used for tripping and alarming, but it does not have recording and communication capabilities built in.

A sudden pressure protection module is provided in the protective device to take the output signals from the conventional sudden pressure relay and to form more secure and intelligent transformer protections. Through this module, the events of sudden pressure relay operations can be recorded and communicated to the control center.

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1..n

, Ass

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2 3

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Device Planning Parameters of the Sudden Pressure Protection Module




Global Protection Parameters of the Sudden Pressure Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Sudden Press]





Alarm Assignment for External Alarm 1..n, Assignment List -.- [Protection Para/Global Prot Para/Sudden Press]



Setting Group Parameters of the Sudden Pressure Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/Sudden Press]


Inactive, Active



Inactive, Active


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ExBlo TripCmd Fc


Inactive, Active


Sudden Pressure Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Sudden Press]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Sudden Press]


[Protection Para/Global Prot Para/Sudden Press]

Alarm-I Module Input State: Alarm [Protection Para/Global Prot Para/Sudden Press]

Trip-I Module Input State: Trip [Protection Para/Global Prot Para/Sudden Press]

Sudden Pressure Protection Module Signals (Output States)

Name Description


Commissioning: Sudden Pressure Protection

Object to be tested:• Test of the Sudden Pressure Protection module.


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Procedure:• Simulate the functionality of the Sudden Protection Relay.


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Supervision50BF – Breaker Failure Supervision

BF[1] ,BF[2]


The breaker failure (BF) protection is used to provide backup protection in the event that a breaker fails to oper-ate properly during fault clearing. A breaker failure condition is recognized if current is still flowing through the breaker after tripping or opening breaker commands have been issued for a specified time. The User can select different trigger modes. In addition, up to three additional trigger events (trip commands) can be assigned from all the protection modules.

Trigger Modes

There are three trigger modes for the breaker failure available. In addition, there are three assignable trigger inputs available.

• All Trips: The Trip Command of the Breaker will be used to trigger the Breaker Failure.

• Current Trips: All current trips that are assigned to this breaker (within the breaker manager) will start the BF module. The list/section “Current Functions” shows all current trips in tabular form.

•

• External Trips: All external trips that are assigned to this breaker (within the breaker manager) will start the BF module. The list/section “External Trips” shows all external trips in tabular form.

• In addition, the User can also select none (e.g.: if the User intends to use only one of the three additional assignable trigger inputs).

Those trips can exclusively start the breaker failures that are assigned within the breaker manager to the breaker that is to be supervised.

Select the winding side from which the measured currents should be taken in case this protective device is a transformer differential protection.

In case, that an External Trip Module is used, this trip has to be assigned also within the Trip Manager. Otherwise, this trip cannot trigger the BF-Failure module.

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φ

BF.I-

BF >

BF.t-

BF

S

1

R1

1

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All T

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BF Nam

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2 11 15 15

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IM02602013E ETR-5000

Explanation:

By triggering the BF element, a delay timer will be started. Once the timer is started, it won´t be stopped if the trigger falls back.

The timer will be stopped, if the current magnitudes fall below the set threshold. The BF function is now in the rejected mode until the trigger falls back.

Once the delay timer has expired and if the current magnitudes of any of the three phase currents still exceed the set threshold, the Breaker Failure signal will be issued (becomes active).

This signal will remain active as long as the current magnitudes exceed the set threshold. This signal will become inactive (falls back) as soon as all current magnitudes fall below the set threshold, e.g. if the upstream protective device has interrupted the current (OFF command to the upstream breaker) by processing the BF signal of the downstream device.

Once a Breaker Failure is detected, the Breaker Failure signal will set a Lockout Signal. The Lockout Signal is a persistent alarm and has to be acknowledged manually at the HMI.

Direct Commands


Res Lockout Reset Lockout Inactive, Active


Device Planning Parameters of the BF Module


Mode Mode Use Use [Device Planning]

Global Protection Parameters of the BF Module


CT Winding Side


BF[1]: W1BF[2]: W2

BF[1]: W1BF[2]: W2

[Protection Para/Global Prot Para/Supervision/BF[1]]

Bkr Selection of the Breaker to be monitored. BF[1]: Bkr[1].BF[2]: Bkr[2].

BF[1]: Bkr[1].BF[2]: Bkr[2].

[Protection Para/Global Prot Para/Supervision/BF[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Supervision/BF[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Supervision/BF[1]]

Trigger Determining the trigger mode for the Breaker Failure.

- . -, All Trips, Current Trips, ExP Fc

All Trips [Protection Para/Global Prot Para/Supervision/BF[1]]

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Trigger1 Trigger that will start the BF Trigger -.- [Protection Para/Global Prot Para/Supervision/BF[1]]



Setting Group Parameters of the BF Module

In order to prevent a faulty activation of the BF Module, the pickup (alarm) time must be greater than the sum of:

• The open time of the breaker (please refer to the technical data of the manufacturer of the breaker);

• + The tripping delay of the device (please refer to the Technical Data section);

• + The security margin; and

• + The operating time.



Inactive, Active

Inactive [Protection Para/<1..4>/Supervision/BF[1]]


Inactive, Active

Inactive [Protection Para/<1..4>/Supervision/BF[1]]

I-BF > Current level that needs to exist after Trip Command has been given.

0.02 – 0.10 In 0.02 In [Protection Para/<1..4>/Supervision/BF[1]]

t-BF If the delay time is expired, an BF alarm is given out.

0.00 – 10.00 s 0.20 s [Protection Para/<1..4>/Supervision/BF[1]]

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BF Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Supervision/BF[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Supervision/BF[1]]

Trigger1 Module Input: Trigger that will start the BF [Protection Para/Global Prot Para/Supervision/BF[1]]



BF Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingPickup Signal: BF-Module Started (Pickup)Trip Signal: Breaker Failure TripLockout Signal: LockoutRes Lockout Signal: Reset Lockout

Trigger Functions - All Trips

These signals will start the BF module if all trips have been selected as the trigger event.

In case that the protective device is equipped with directional overcurrent protection. All ANSI 67 elements (directional overcurrent protection), will be displayed as ANSI 50/51 elements. That means, that the name of an ANSI 50/51 element wont change, if it is set within the device planning from “non-directional” to “directional”.

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Trigger Functions - Current Trips

These signals will start the BF module if current trips have been selected as the trigger event.

In case that the protective device is equipped with directional overcurrent protection. All ANSI 67 elements (directional overcurrent protection), will be displayed as ANSI 50/51 elements. That means, that the name of an ANSI 50/51 element wont change, if it is set within the device planning from “non-directional” to “directional”.

Name Description

-.- No assignment87.TripCmd Signal: Trip Command87H.TripCmd Signal: Trip Command87GD[1].TripCmd Signal: Trip Command87GDH[1].TripCmd Signal: Trip Command87GD[2].TripCmd Signal: Trip Command87GDH[2].TripCmd Signal: Trip Command50P[1].TripCmd Signal: Trip Command50P[2].TripCmd Signal: Trip Command50P[3].TripCmd Signal: Trip Command50P[4].TripCmd Signal: Trip Command51P[1].TripCmd Signal: Trip Command51P[2].TripCmd Signal: Trip Command51P[3].TripCmd Signal: Trip Command51P[4].TripCmd Signal: Trip Command50X[1].TripCmd Signal: Trip Command50X[2].TripCmd Signal: Trip Command51X[1].TripCmd Signal: Trip Command51X[2].TripCmd Signal: Trip Command50R[1].TripCmd Signal: Trip Command50R[2].TripCmd Signal: Trip Command51R[1].TripCmd Signal: Trip Command51R[2].TripCmd Signal: Trip Command49.TripCmd Signal: Trip Command51Q[1].TripCmd Signal: Trip Command51Q[2].TripCmd Signal: Trip Command46[1].TripCmd Signal: Trip Command46[2].TripCmd Signal: Trip CommandZI[1].TripCmd Signal: Zone Interlocking Trip CommandZI[2].TripCmd Signal: Zone Interlocking Trip Command

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Trigger Functions - External Trips

These trips will start the BF module if external trips have been selected as the trigger event.

Name Description

-.- No assignmentExP[1].TripCmd Signal: Trip CommandExP[2].TripCmd Signal: Trip CommandExP[3].TripCmd Signal: Trip CommandExP[4].TripCmd Signal: Trip CommandSudden Press.TripCmd Signal: Trip CommandExt Oil Temp.TripCmd Signal: Trip CommandExt Temp Superv[1].TripCmd Signal: Trip CommandExt Temp Superv[2].TripCmd Signal: Trip CommandExt Temp Superv[3].TripCmd Signal: Trip Command

Trigger Functions - Additional Trips

Name Description

-.- No assignment87.TripCmd Signal: Trip Command87H.TripCmd Signal: Trip Command87GD[1].TripCmd Signal: Trip Command87GDH[1].TripCmd Signal: Trip Command87GD[2].TripCmd Signal: Trip Command87GDH[2].TripCmd Signal: Trip Command50P[1].TripCmd Signal: Trip Command50P[2].TripCmd Signal: Trip Command50P[3].TripCmd Signal: Trip Command50P[4].TripCmd Signal: Trip Command51P[1].TripCmd Signal: Trip Command51P[2].TripCmd Signal: Trip Command51P[3].TripCmd Signal: Trip Command51P[4].TripCmd Signal: Trip Command50X[1].TripCmd Signal: Trip Command50X[2].TripCmd Signal: Trip Command51X[1].TripCmd Signal: Trip Command51X[2].TripCmd Signal: Trip Command50R[1].TripCmd Signal: Trip Command50R[2].TripCmd Signal: Trip Command51R[1].TripCmd Signal: Trip Command51R[2].TripCmd Signal: Trip Command

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Name Description

49.TripCmd Signal: Trip Command51Q[1].TripCmd Signal: Trip Command51Q[2].TripCmd Signal: Trip Command27M[1].TripCmd Signal: Trip Command27M[2].TripCmd Signal: Trip Command59M[1].TripCmd Signal: Trip Command59M[2].TripCmd Signal: Trip Command27A[1].TripCmd Signal: Trip Command27A[2].TripCmd Signal: Trip Command59A[1].TripCmd Signal: Trip Command59A[2].TripCmd Signal: Trip Command46[1].TripCmd Signal: Trip Command46[2].TripCmd Signal: Trip Command47[1].TripCmd Signal: Trip Command47[2].TripCmd Signal: Trip Command81[1].TripCmd Signal: Trip Command81[2].TripCmd Signal: Trip Command81[3].TripCmd Signal: Trip Command81[4].TripCmd Signal: Trip Command81[5].TripCmd Signal: Trip Command81[6].TripCmd Signal: Trip Command32[1].TripCmd Signal: Trip Command32[2].TripCmd Signal: Trip Command32[3].TripCmd Signal: Trip Command32V[1].TripCmd Signal: Trip Command32V[2].TripCmd Signal: Trip Command32V[3].TripCmd Signal: Trip CommandZI[1].TripCmd Signal: Zone Interlocking Trip CommandZI[2].TripCmd Signal: Zone Interlocking Trip Command24[1].TripCmd Signal: Trip Command24[2].TripCmd Signal: Trip CommandExP[1].TripCmd Signal: Trip CommandExP[2].TripCmd Signal: Trip CommandExP[3].TripCmd Signal: Trip CommandExP[4].TripCmd Signal: Trip CommandRTD.TripCmd Signal: Trip CommandDI-8P X1.DI 1 Signal: Digital InputDI-8P X1.DI 2 Signal: Digital InputDI-8P X1.DI 3 Signal: Digital Input

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Name Description

DI-8P X1.DI 4 Signal: Digital InputDI-8P X1.DI 5 Signal: Digital InputDI-8P X1.DI 6 Signal: Digital InputDI-8P X1.DI 7 Signal: Digital InputDI-8P X1.DI 8 Signal: Digital InputLogic.LE1.Gate Out Signal: Output of the logic gateLogic.LE1.Timer Out Signal: Timer OutputLogic.LE1.Out Signal: Latched Output (Q)Logic.LE1.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE2.Gate Out Signal: Output of the logic gateLogic.LE2.Timer Out Signal: Timer OutputLogic.LE2.Out Signal: Latched Output (Q)Logic.LE2.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE3.Gate Out Signal: Output of the logic gateLogic.LE3.Timer Out Signal: Timer OutputLogic.LE3.Out Signal: Latched Output (Q)Logic.LE3.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE4.Gate Out Signal: Output of the logic gateLogic.LE4.Timer Out Signal: Timer OutputLogic.LE4.Out Signal: Latched Output (Q)Logic.LE4.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE5.Gate Out Signal: Output of the logic gateLogic.LE5.Timer Out Signal: Timer OutputLogic.LE5.Out Signal: Latched Output (Q)Logic.LE5.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE6.Gate Out Signal: Output of the logic gateLogic.LE6.Timer Out Signal: Timer OutputLogic.LE6.Out Signal: Latched Output (Q)Logic.LE6.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE7.Gate Out Signal: Output of the logic gateLogic.LE7.Timer Out Signal: Timer OutputLogic.LE7.Out Signal: Latched Output (Q)Logic.LE7.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE8.Gate Out Signal: Output of the logic gateLogic.LE8.Timer Out Signal: Timer OutputLogic.LE8.Out Signal: Latched Output (Q)Logic.LE8.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE9.Gate Out Signal: Output of the logic gateLogic.LE9.Timer Out Signal: Timer Output

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Name Description

Logic.LE77.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE78.Gate Out Signal: Output of the logic gateLogic.LE78.Timer Out Signal: Timer OutputLogic.LE78.Out Signal: Latched Output (Q)Logic.LE78.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE79.Gate Out Signal: Output of the logic gateLogic.LE79.Timer Out Signal: Timer OutputLogic.LE79.Out Signal: Latched Output (Q)Logic.LE79.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE80.Gate Out Signal: Output of the logic gateLogic.LE80.Timer Out Signal: Timer OutputLogic.LE80.Out Signal: Latched Output (Q)Logic.LE80.Out inverted Signal: Negated Latched Output (Q NOT)

Commissioning: Breaker Failure Protection

The time that is configured for the BF MUST NOT be below the sum of breaker control time + security margin + operation time of the protective device, otherwise an unwanted operation of the BF is caused by any protective trip.

Object to Be Tested:

• Test of the breaker failure protection.

Necessary Means:

• Current source;• Current meter; and• Timer.

When testing, the applied test current must always be higher than the tripping threshold »I-BF«. If the test current falls below the threshold while the the delay timer is running, no pickup will be generated.

Procedure (Single-Phase):

For testing the tripping time of the BF protection, a test current has to be higher than the threshold value of one of the current protection modules that are assigned to trigger the BF protection. The BF trip delay can be measured from the time when one of the triggering inputs becomes active to the time when the BF protection trip is asserted.

To avoid wiring errors, checked to make sure the breaker in the upstream system switches off.

The time, measured by the timer, should be in line with the specified tolerances.

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Re-connect the control cable to the breaker!

Successful Test Result:

The actual times measured comply with the setpoint times. The breaker in the higher-level section switches off.

CTS – Current Transformer SupervisionCTS[1] ,CTS[2]

Most functions of metering, protection, and control in the relay rely on correct current measurements. It is important to make sure the CT connections and their operations are correct. The failures (including CT secondary wire broken, insulation broken down, broken wiring between CT and relay, and mismatched polarities) will cause the incorrect current measurements. The other CT errors (due to the magnetizing current that is proportional to the primary current, CT saturation, and measuring circuit and quantization error) can also cause inaccurate current measurements.

The CTS utilizes the Kirchhoff’s current law to detect a CT failure and can differentiate the wiring errors from the measurement errors by adding biases to offset the measurement related errors. The biases include two terms, one of which is related to the static error that accounts for CT magnetizing characteristic differences and current measurement circuit calibration errors and other is the dynamic error that is proportional to the measured maximum current due to CT transformation characteristics. The CTs are assumed to be used in the wye-grounded winding sides. Under normal conditions, the mismatch between the calculated and the measured zero sequence current should be less than the bias value. However, if there is a CT wiring error, such relationship will not hold true. If the mismatch exceeds the bias for a specified time, an alarm will be generated.

The operating principle can be expressed in terms of CT secondary currents as follow:

IL1IL2IL3KI∗IG=3∗I 0KI ∗ IG∆IKd∗Imax

KI is the ratio of the ground CT ratio over the phase CT ratio, and it is automatically calculated from the rated system parameters.

∆I = The static error, a minimum mismatch allowed between the calculated and measured zero sequence current.

Kd = The dynamic error factor, a restrain slope that defines a percentage error generated by a high current.

Imax = maximum phase current.Total bias value = ∆I + Kd x Imax.

The current transformer supervision operation can be graphically represented as follows.

If the current is measured in two phases only (for example only IA/IB) or if there is no separate ground current measuring (e.g.: normally via a zero sequence CT), the supervision function should be deactivated.

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Ple

ase

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ETR-5000 IM02602013E

Device Planning Parameters of the Current Transformer Supervision



Do not use [Device Planning]

Global Protection Parameter of the Current Transformer Supervision


CT Winding Side


CTS[1]: W1CTS[2]: W2

CTS[1]: W1CTS[2]: W2

[Protection Para/Global Prot Para/Supervision/CTS[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Supervision/CTS[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Supervision/CTS[1]]

Setting Group Parameters of the Current Transformer Supervision



Inactive, Active

Inactive [Protection Para/<1..4>/Supervision/CTS[1]]


Inactive, Active

Inactive [Protection Para/<1..4>/Supervision/CTS[1]]

ΔI In order to prevent faulty tripping of phase selective protection functions that use the current as tripping criterion. If the difference of the measured ground current and the calculated value I0 is higher than the pick up value ΔI, an pickup event is generated after expiring of the excitation time. In such a case, a fuse failure, a broken wire or a faulty measuring circuit can be assumed.

0.10 – 1.00 In 0.50 In [Protection Para/<1..4>/Supervision/CTS[1]]

Pickup delay Pickup delay 0.1 – 9999.0 s 1.0 s [Protection Para/<1..4>/Supervision/CTS[1]]

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Kd Dynamic correction factor for the evaluation of the difference between calculated and measured ground current. This correction factor allows transformer faults, caused by higher currents, to be compensated.

0.00 - 0.99 0.00 [Protection Para/<1..4>/Supervision/CTS[1]]

Current Transformer Supervision Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Supervision/CTS[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Supervision/CTS[1]]

Current Transformer Supervision Signals (Outputs States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingPickup Signal: Pickup Current Transformer Measuring Circuit Supervision

Commissioning: Current Transformer Failure Supervision

Preconditions:1.Measurement of all three-phase currents (are applied to the measuring inputs of the device).

2.The ground current is detected via a zero sequence transformer (not in residual connection).

Object to Be Tested:

• Check of the CT Supervision (by comparing the calculated with the measured ground current).

Necessary Means:

• Three-phase current source.

Procedure, Part 1:

• Set the limiting value of the CTs to »delta I=0.1*In«.• Feed a three-phase, symmetrical current system (approx. nominal current) to the secondary side.

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• Disconnect the current of one phase from one of the measuring inputs (the symmetrical feeding at the secondary side has to be maintained).

• Make sure that the »CTS.ALARM« signal is generated.

Successful Test Result, Part 1:

The »CTS.ALARM« signal is generated.

Procedure, Part 2:

• Feed a three-phase, symmetrical current system (approx. nominal current) to the secondary side.• Feed a current that is higher than the threshold value for the measuring circuit supervision to the ground

current measuring input.• Make sure that the »CTS.ALARM« signal is generated.

Successful Test Result, Part 2:

The »CTS.ALARM« signal is generated.

74TC - Trip Circuit MonitoringTCM[1] ,TCM[2]

The trip circuit monitoring is used for monitoring if the trip circuit is ready for opening operations. The monitoring can be fulfilled by two ways. The first assumes only 52a is used in the trip circuit. The second assumes that, in addition to 52a, 52b is also used for the circuit monitoring. Two options either 52a only (or breaker closed) or both (52a and 52b) are provided for the User to select based on use of the breaker status in the trip circuit. With 52a only in the trip circuit, the monitoring is only effective when the breaker is closed while if both 52a and 52b are used, the trip circuit will be monitored all time as long as the control power is on.

The trip circuit continuity is monitored through the digital inputs DI1 and DI2, and the breaker status 52a or 52b or both must be monitored through the other digital inputs. Note that the digital inputs used for this purpose must be configured properly based on the trip circuit control voltage and also that the de-bouncing times must be set to minimum. If the trip circuit is detected broken, an alarm will be issued with a specified delay, which must be greater than a period from the time when a trip contact is closed to the time when the breaker status is clearly recognized by the relay.

Slot 1 has two digital inputs, each of which has a separate root (contact separation) for the trip circuit supervision.

In this case, the trip circuit supply voltage serves also as supply voltage for the digital inputs and so the supply voltage failure of a trip circuit can be detected directly.

In order to identify a conductor failure in the trip circuit on the supply line or in the trip coil, the off-coil has to be looped-in to the supervision circuit.

The time delay is to be set in a way that switching actions cannot cause false trips in this module.

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One Breaker Application Examples

Trip Circuit Monitoring for one Breaker: Auxiliary Contacts (52a and 52b) in trip circuit.

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Breaker 1 (Bkr[1]) Control Voltage

12345678

PE

9101112

COM1

131415161718

V+

DI1COM2DI2

V-

X1TC

W1-52a

W1-52b

+DC

- DC

52a 52b

Trip

Relay Control Voltage

AND

t-TCM

0

tTCM.Pickup

56

X1

AND78

X1

OR

DI-Threshold

52a and 52b in Trip Circuit

DI-Threshold

V+V-

ETR-5000 IM02602013E

Trip Circuit Monitoring for One Breaker: Auxiliary Contacts (52a Only) in Trip Circuit.

Device Planning Parameters of the Trip Circuit Monitoring Module




Global Protection Parameters of the Trip Circuit Monitoring Module



TCM[1]: Bkr[1].StateTCM[2]: Bkr[2].State

TCM[1]: Bkr[1].StateTCM[2]: Bkr[2].State

[Protection Para/Global Prot Para/Supervision/TCM[1]]

Mode Select if trip circuit is going to be monitored when the breaker is closed or when the breaker is either open or close.

Closed, Either

Closed [Protection Para/Global Prot Para/Supervision/TCM[1]]

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Breaker 1 (Bkr[1]) Control Voltage

12345678

PE

9101112

COM1

131415161718

V+

DI1

V-

X1TC

W1-52a

W1-52b

+DC

- DC

52a 52b

Trip

Relay Control Voltage

AND

Bkr.Pos CLOSE

t-TCM

0

t TCM.Pickup56

X1

52a only in Trip Circuit

DI-Threshold

V+V-

IM02602013E ETR-5000


Input 1 Select the input configured to monitor the trip coil when the breaker is closed.


TCM[1]: DI-8P X1.DI 1TCM[2]: DI-8P X1.DI 2


Input 2 Select the input configured to monitor the trip coil when the breaker is open. Only available if Mode set to “Either”.

Only available if: Mode = Either


-.- [Protection Para/Global Prot Para/Supervision/TCM[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Supervision/TCM[1]]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Supervision/TCM[1]]

Setting Group Parameters of the Trip Circuit Monitoring Module



Inactive, Active

Inactive [Protection Para/<1..4>/Supervision/TCM[1]]


Inactive, Active

Inactive [Protection Para/<1..4>/Supervision/TCM[1]]

t-TCM Tripping delay time of the Trip Circuit Supervision

0.10 – 10.00 s 0.2 s [Protection Para/<1..4>/Supervision/TCM[1]]

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Trip Circuit Monitoring Module Input States


CinBkr-52a-I Module Input State: Feed-back signal of the Bkr (52a)


CinBkr-52b-I Module Input State: Feed-back signal of the Bkr. (52b)


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Supervision/TCM[1]]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Supervision/TCM[1]]

Trip Circuit Monitoring Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingPickup Signal: Pickup Trip Circuit SupervisionNot Possible Not possible because no state indicator assigned to the breaker.

Commissioning: Trip Circuit Monitoring for Breakers

For breakers that trip by means of little energy (e.g.: via an optocoupler), it has to be ensured that the current applied by the digital inputs will not cause false tripping of the breaker.

Object to Be Tested:• Test of the trip circuit monitoring (with 52a and 52b contact).

Procedure, Part 1:• Simulate failure of the control voltage in the power circuits.

Successful Test Result, Part 1:After expiration of »t-TCM« the trip circuit supervision, TCM of the device should signal an alarm.

Procedure, Part 2:• Simulate a broken cable in the breaker control circuit.

Successful Test Result, Part 2:After expiration of »t-TCM«, the trip circuit supervision TCM of the device should signal an alarm.

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LOP – Loss of PotentialAvailable elements:LOP

LOP function detects the loss of voltage in any of the voltage input measuring circuits and uses the following measured values and information to detect an LOP condition:

• Three-phase voltages;

• Ratio of negative-to-positive sequence voltages;

• Zero sequence voltage;

• Three-phase currents;

• Residual current (I0);

• Pickup flags from all overcurrent elements; and

• Breaker status

Once an LOP condition is detected and it lasts longer than an adjustable minimum pickup time, the LOP Pickup will be set. The LOP Block will only be set if the LOP-Block control setting is set to enabled (activated). The LOP Pickup and LOP Block signals can both be used as logical signal to block the protective functions which use the voltage information such as voltage restraint. The minimum pickup timer is used to prevent short time incorrect operation of the LOP function during breaker switching-on operation.

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Inac

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LOP

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IM02602013E ETR-5000

Device Planning Parameters of the LOP Module




Global Protection Parameters of the LOP Module



-.-, Bkr[1].State, Bkr[2].State

Bkr[1].State [Protection Para/Global Prot Para/Supervision/LOP]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Supervision/LOP]


1..n, Assignment List -.- [Protection Para/Global Prot Para/Supervision/LOP]

Setting Group Parameters of the LOP Module



Inactive, Active

Inactive [Protection Para/<1..4>/Supervision/LOP]


Inactive, Active


LOP Blo Enable

Activate (allow) or inactivate (disallow) blocking by the module LOP.

Inactive, Active


t-Pickup Pickup Delay 0 – 9999.0 s 0.1 s [Protection Para/<1..4>/Supervision/LOP]

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LOP Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Supervision/LOP]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Supervision/LOP]

LOP Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingPickup Signal: Pickup Loss of PotentialLOP Blo Signal: Loss of Potential blocks other elements

Commissioning: Loss of Potential


• Testing the LOP.

Necessary means:

• Three-phase current source and

• Three-phase voltage source.

Procedure part 1:

Examine if the output signals »LOP BLO « (200ms delay) and »LOP« only become true if:

• Any of the three-phase voltages becomes less 0.01*Vn Voltand

• The residual voltage is less than 0.01*Vn Volt or the %V2/V1 ratio is greater 40%and

• All three-phase currents are less than 2 * Ipu (rated current)and

• The residual current is less than 0.1 Ipu (rated current)and

• No pickup of an IOC element (No pickup of a 50P[x] element)and

• The breaker is closed (Information from the Breaker module).

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Successful test result part 1:

The output signals only become true if all the above mentioned conditions are fulfilled.

Procedure part 2:

• Assign the »LOP« or »LOP BLO« output signals to all protection element that should be blocked by LOP (e.g.: Undervoltage Protection, Voltage Restraint...).

• Test if those elements are blocked if the LOP modules issue a blocking signal.

Successful test result part 2:

All elements that should be blocked in case of LOP are blocked if the conditions (Procedure part 1) are fulfilled.

Self SupervisionThe System-OK contact (SC relay, life-contact) cannot be configured. The system contact is a Form “C” contact that picks up when the device is free from internal faults. While the device is booting up, the System OK relay (SC) remains dropped-off (unenergized). As soon as the system is properly started (and protection is active), the System Contact picks up and the System LED is activated accordingly.

The devices are continuously monitored and supervised by different methods during normal operation as well as during the start-up phase.

Results of this supervision may be:

• Messages appearing within the event recorder;• Indications within the display or PowerPort-E;• Corrective measures;• Restart of the device; or• Any combination of the above results.

In case of failures that cannot be corrected immediately, 3 restarts within 20 minutes are accepted before the device will be deactivated. In such a case, the device should be removed for service to ensure continuous correct operation. The Eaton Customer Service contact information and address can be found at the front of this manual.

In case of any failures, the recorders of the device should be left untouched to ensure an easy diagnosis and proper repair at the factory. Besides the records and visible indications to the customer, there is internal information about failures. These allow Eaton service personnel at the repair facility to make a detailed analysis of files with failure reports.

Self supervision is applied by different functions at different cyclic or non-cyclic timings to the following parts and functions of the device:

• Faultless cyclic execution of the software;• Functional capability of memory boards;• Consistency of data;• Functional capability of hardware sub-assemblies; and• Faultless operation of the measuring unit.

Faultless cyclic operation of the software is supervised by timing analysis and checking results of different functions. Errors of the software (watchdog function) lead to restarting the device and switching off the System-

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OK contact (life contact). In addition, the “System-OK” LED will blink red after 3 unsuccessful attempts to restart the device within a time period of 20 minutes.

The main processor cyclically monitors the operation of the signal processor and initiates corrective actions or restart of the device in case of faulty operation. Data and files are generally secured against unintended overwriting or faulty changes by check-sums.

The measuring unit continuously checks the measured data by comparing received data with data from a second channel sampled in parallel.

The auxiliary voltage is monitored continuously. If the voltage of one of the different supply circuits falls below a certain threshold, a restart of the device is initiated. If the voltage staggers around the threshold, the device also starts again after several seconds. Additionally the level of all internal supply voltage groups are continuously monitored.

Independent of these separate monitoring functions, the intermediate voltage circuit is buffered until all important and relevant operational and fault-data have been saved and the device initiates a restart.

Error Messages / Codes

After a reboot of the device, the reason for rebooting will be displayed under [Operation/Status Display/Sys/Reboot]. For more information about the reboot reason, please refer to the information in this section.

The reboot will also be logged within the event recorder. Rebooting causes an event named “Sys.Reboot”.

Numeric Reboot Codes

Error Messages/Codes

1. Reboot after clean switching off of the device - Normal reboot after clean shut-down of the device.

2. Reboot by User command - User-initiated reboot through panel command.

3. Super reset - Reset to factory settings.

4. Restart by debugger - Eaton internally for system-analysis purposes.

5. Restart because of configuration changes.

6. General failure - Reboot without definite reason.

7. Reboot by “SW-system abort” (HOST-side) - Summary of several reboot reasons detected by the software (i.e.: wrong pointer, corrupted files, etc.).

8. Reboot by watchdog timeout (HOST-side) - Signaling if the protection-class-task hangs.

9. Reboot by system abort (DSP-side) - Summary of several reboot reasons detected by software (i.e.: wrong pointer, DSP-side).

10. Reboot by watchdog timeout (DSP-side) - Appears when DSP sequence needs too long for one cycle.

11. Loss of auxiliary voltage or low voltage reboot after loss of auxiliary voltage or voltage dropping below reboot level but not becoming zero.

12. Faulty memory access - Message of MMU (memory mapping unit) that prohibited memory access has occurred.

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RTD Protection ModuleElements:RTD

General – Principle Use

The Resistance-based Temperature Detector (RTD) Protection Module uses temperature data that are provided by Eaton's Universal Resistance-based Temperature Detector (URTD) module (please refer to the URTD Module section) or Eaton's Universal Resistance-based Temperature Detector II (URTDII) module (please refer to the URTDII Module section).

If voting trip is required, please map the output used for tripping purposes: "RTD. Voting Trip Grp 1" or "RTD.Voting Trip Grp 2".

The protective device provides tripping and alarming functions based on the direct temperature measurements read from Eaton’s (URTD) device that has 11 temperature sensor channels or Eaton’s (URTDII) device that has 11 or 12 temperature sensor channels. Each channel will have one trip function without an intended delay and one alarm function with a delay.

• The “trip” function has only a threshold setting.

• Each individual »Alarm Function« will have a threshold setting range, and can be individually enabled or disabled. Since the temperature cannot change instantaneously (which is a way that temperature differs from current), the “delay” is essentially built in to the function due to the fact that the temperature will take some time to increase from room temperature to the “trip threshold” level.

• The dropout ratio for both trip and alarm is 0.99.

The temperature rise is limited by the RTD driver.

The entire function can be turned off or on, or individual channels can be turned off or on.

Voting

Additionally, RTD voting schemes are available and User programmable. The Voting feature must be activated and configured within the following menu, [Protection Para\Set[x]\Temp-Prot/ RTD\Vote[x]]. Here, the setting »Function« has to be set to »Active«.

Once activated, the number of channels that will be used by the voting feature is selected. This is set by way of the parameter »Voting[x]«. This parameter defines how many of the selected channels must be over its threshold level in order to get a voting trip. Each individual channel must be selected or deselected by setting to either »Yes« or »No«. When selecting »Yes«, the channel will be used in the voting process. Note that in order to be selected, each channel must also be active and the RTD module itself has to be active.

If for example, Vote[x] is set to »3«, and all channels are set to »Yes«, and if any three of the selected channels exceed their individual threshold settings, a Vote trip will occur. Please note that the voting trips are not included within the RTD trips. In order to have voting trips, the User has to assign them to a Trip Input of an External Trip module. The External Trip has to be assigned then within the trip manager to the Breaker.

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RTD

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IM02602013E ETR-5000

Device Planning Parameters of the RTD Temperature Protection Module




Global Protection Parameters of the RTD Temperature Protection Module



1..n, Assignment List -.- [Protection Para/Global Prot Para/Temp-Prot/RTD]





Setting Group Parameters of the RTD Temperature Protection Module



Inactive, Active

Inactive [Protection Para/<1..4>/Temp-Prot/RTD/General Settings]


Inactive, Active



Inactive, Active


ExBlo TripCmd Fc


Inactive, Active


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W1-A Alarm Function

Winding1 Phase A Alarm Function Inactive, Active

Active [Protection Para/<1..4>/Temp-Prot/RTD/W1-A]

W1-A Trip Function

Winding1 Phase A Trip Function Inactive, Active


W1-A Alarm Winding1 Phase A Threshold for Temperature Alarm

Only available if: Device Planning: Alarm Function = Use

0 - 200°C 105°C [Protection Para/<1..4>/Temp-Prot/RTD/W1-A]

W1-A t-Delay Winding1 Phase A If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/W1-A]

W1-A Trip Winding1 Phase A Threshold for Temperature Trip

Only available if: Device Planning: Trip Function = Use


W1-B Alarm Function

Winding1 Phase B Alarm Function Inactive, Active

Active [Protection Para/<1..4>/Temp-Prot/RTD/W1-B]

W1-B Trip Function

Winding1 Phase B Trip Function Inactive, Active


W1-B Alarm Winding1 Phase B Threshold for Temperature Alarm


0 - 200°C 105°C [Protection Para/<1..4>/Temp-Prot/RTD/W1-B]

W1-B t-Delay Winding1 Phase B If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/W1-B]

W1-B Trip Winding1 Phase B Threshold for Temperature Trip



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W1-C Alarm Function

Winding1 Phase C Alarm Function Inactive, Active

Active [Protection Para/<1..4>/Temp-Prot/RTD/W1-C]

W1-C Trip Function

Winding1 Phase C Trip Function Inactive, Active


W1-C Alarm Winding1 Phase C Threshold for Temperature Alarm


0 - 200°C 105°C [Protection Para/<1..4>/Temp-Prot/RTD/W1-C]

W1-C t-Delay Winding1 Phase C If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/W1-C]

W1-C Trip Winding1 Phase C Threshold for Temperature Trip



W2-A Alarm Function

Winding2 Phase A Alarm Function Inactive, Active


W2-A Trip Function

Winding2 Phase A Trip Function Inactive, Active


W2-A Alarm Winding2 Phase A Threshold for Temperature Alarm



W2-A t-Delay Winding2 Phase A If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/W2-A]

W2-A Trip Winding2 Phase A Threshold for Temperature Trip



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W2-B Alarm Function

Winding2 Phase B Alarm Function Inactive, Active


W2-B Trip Function

Winding2 Phase B Trip Function Inactive, Active


W2-B Alarm Winding2 Phase B Threshold for Temperature Alarm



W2-B t-Delay Winding2 Phase B If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/W2-B]

W2-B Trip Winding2 Phase B Threshold for Temperature Trip



W2-C Alarm Function

Winding2 Phase C Alarm Function Inactive, Active


W2-C Trip Function

Winding2 Phase C Trip Function Inactive, Active


W2-C Alarm Winding2 Phase C Threshold for Temperature Alarm



W2-C t-Delay Winding2 Phase C If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/W2-C]

W2-C Trip Winding2 Phase C Threshold for Temperature Trip



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Amb1 Alarm Function

Ambient Alarm Function Inactive, Active

Active [Protection Para/<1..4>/Temp-Prot/RTD/Amb 1]

Amb1 Trip Function

Ambient Trip Function Inactive, Active


Amb1 Alarm Ambient Threshold for Temperature Alarm


0 - 200°C 105°C [Protection Para/<1..4>/Temp-Prot/RTD/Amb 1]

Amb1 t-Delay Ambient If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/Amb 1]

Amb1 Trip Ambient Threshold for Temperature Trip



Amb2 Alarm Function



Amb2 Alarm Function



Amb2 Alarm Ambient Threshold for Temperature Alarm



Amb2 t-Delay Ambient If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/Amb 2]

Amb2 Trip Ambient Threshold for Temperature Trip



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Aux1Alarm Function

Auxiliary Alarm Function Inactive, Active

Active [Protection Para/<1..4>/Temp-Prot/RTD/Aux 1]

Aux1Trip Function

Auxiliary Trip Function Inactive, Active


Aux1 Alarm Auxiliary Threshold for Temperature Alarm


0 - 200°C 105°C [Protection Para/<1..4>/Temp-Prot/RTD/Aux 1]

Aux1 t-Delay Auxiliary If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/Aux 1]

Aux1 Trip Auxiliary Threshold for Temperature Trip



Aux2 Alarm Function



Aux2 Trip Function












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Aux3 Alarm Function



Aux3 Trip Function




Only available if: Device Planning: Alarm Function = Use Only available if: Device Planning: Alarm Function = Use






Only available if: Device Planning: Trip Function = Use Only available if: Device Planning: Trip Function = Use


Aux4 Alarm Function



Aux4 Trip Function



Aux4 Alarm Auxiliary Threshold for Temperature Alarm 0 - 200°C 105°C [Protection Para/<1..4>/Temp-Prot/RTD/Aux 4]



Aux4 Trip Auxiliary Threshold for Temperature Trip 0 - 200°C 110°C [Protection Para/<1..4>/Temp-Prot/RTD/Aux 4]

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WD W1 Alarm Function

Winding W1 Alarm Function Inactive, Active

Inactive [Protection Para/<1..4>/Temp-Prot/RTD/WD W1 Group]

WD W1 Trip Function

Winding W1 Trip Function Inactive, Active


WD W1 Alarm Winding W1 Threshold for Temperature Alarm


0 - 200°C 80°C [Protection Para/<1..4>/Temp-Prot/RTD/WD W1 Group]

WD W1 t-Delay Winding W1 If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/WD W1 Group]

WD W1 Trip Winding W1 Threshold for Temperature Trip



WD W2 Alarm Function

Winding W2 Alarm Function Inactive, Active


WD W2 Trip Function

Winding W2 Trip Function Inactive, Active


WD W2 Alarm Winding W2 Threshold for Temperature Alarm



WD W2 t-Delay Winding W2 If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/WD W2 Group]

WD W2 Trip Winding W2 Threshold for Temperature Trip



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Amb Alarm Function


Inactive [Protection Para/<1..4>/Temp-Prot/RTD/Amb Group]

Amb Trip Function


Inactive [Protection Para/<1..4>/Temp-Prot/RTD/Amb Group]

Amb Alarm Ambient Threshold for Temperature Alarm


0 - 200°C 80°C [Protection Para/<1..4>/Temp-Prot/RTD/Amb Group]

Amb t-Delay Ambient If this time is expired a Temperature Alarm will be generated.


0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/Amb Group]

Amb Trip Ambient Threshold for Temperature Trip

Only available if: Device Planning: Trip Function = Use Only available if: Device Planning: Aux = Use

0 - 200°C 100°C [Protection Para/<1..4>/Temp-Prot/RTD/Amb Group]

Aux Alarm Function


Inactive [Protection Para/<1..4>/Temp-Prot/RTD/Aux Group]

Aux Trip Function


Inactive [Protection Para/<1..4>/Temp-Prot/RTD/Aux Group]

Aux Alarm Auxiliary Threshold for Temperature Alarm 0 - 200°C 80°C [Protection Para/<1..4>/Temp-Prot/RTD/Aux Group]

Aux t-Delay Auxiliary If this time is expired a Temperature Alarm will be generated.

0 – 360 min 1 min [Protection Para/<1..4>/Temp-Prot/RTD/Aux Group]

Aux Trip Auxiliary Threshold for Temperature Trip 0 - 200°C 100°C [Protection Para/<1..4>/Temp-Prot/RTD/Aux Group]

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Inactive, Active

Inactive [Protection Para/<1..4>/Temp-Prot/RTD/Voting1]

Voting 1 Voting: This parameter defines how many of the selected channels must be over its threshold level for getting a voting trip

1 - 11 1 [Protection Para/<1..4>/Temp-Prot/RTD/Voting1]

W1-A Winding1 Phase A No, Yes

Yes [Protection Para/<1..4>/Temp-Prot/RTD/Voting1]

W1-B Winding1 Phase B No, Yes


W1-C Winding1 Phase C No, Yes








Amb 1 Ambient 1 No, Yes

No [Protection Para/<1..4>/Temp-Prot/RTD/Voting1]



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Aux 1 Auxiliary 1 No, Yes









Inactive, Active

Inactive [Protection Para/<1..4>/Temp-Prot/RTD/Voting2]

Voting 2 Voting: This parameter defines how many of the selected channels must be over its threshold level for getting a voting trip

1 - 11 1 [Protection Para/<1..4>/Temp-Prot/RTD/Voting2]









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RTD Temperature Protection Module Input States


ExBlo1-I Module Input State: External Blocking1 [Protection Para/Global Prot Para/Temp-Prot/RTD]

ExBlo2-I Module Input State: External Blocking2 [Protection Para/Global Prot Para/Temp-Prot/RTD]

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[Protection Para/Global Prot Para/Temp-Prot/RTD]

RTD Temperature Protection Module Signals (Output States)

Name Description

Active Signal: ActiveExBlo Signal: External BlockingBlo TripCmd Signal: Trip Command blockedExBlo TripCmd Signal: External Blocking of the Trip CommandAlarm Alarm RTD Temperature ProtectionTrip Signal: TripTripCmd Signal: Trip CommandW1-A Trip Winding1 Phase A Signal: TripW1-A Alarm Winding1 Phase A Alarm RTD Temperature ProtectionW1-A Timeout Alarm Winding1 Phase A Timeout AlarmW1-A Invalid Winding1 Phase A Signal: Invalid Temperature Measurement

Value (e.g caused by an defective or interrupted RTD Measurement)

W1-B Trip Winding1 Phase B Signal: TripW1-B Alarm Winding1 Phase B Alarm RTD Temperature ProtectionW1-B Timeout Alarm Winding1 Phase B Timeout AlarmW1-B Invalid Winding1 Phase B Signal: Invalid Temperature Measurement


W1-C Trip Winding1 Phase C Signal: TripW1-C Alarm Winding1 Phase C Alarm RTD Temperature ProtectionW1-C Timeout Alarm Winding1 Phase C Timeout AlarmW1-C Invalid Winding1 Phase C Signal: Invalid Temperature Measurement


W2-A Trip Winding2 Phase A Signal: TripW2-A Alarm Winding2 Phase A Alarm RTD Temperature ProtectionW2-A Timeout Alarm Winding2 Phase A Timeout AlarmW2-A Invalid Winding2 Phase A Signal: Invalid Temperature Measurement


W2-B Trip Winding2 Phase B Signal: TripW2-B Alarm Winding2 Phase B Alarm RTD Temperature ProtectionW2-B Timeout Alarm Winding2 Phase B Timeout Alarm

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Name Description

W2-B Invalid Winding2 Phase B Signal: Invalid Temperature Measurement Value (e.g caused by an defective or interrupted RTD Measurement)

W2-C Trip Winding2 Phase C Signal: TripW2-C Alarm Winding2 Phase C Alarm RTD Temperature ProtectionW2-C Timeout Alarm Winding2 Phase C Timeout AlarmW2-C Invalid Winding2 Phase C Signal: Invalid Temperature Measurement


Amb 1 Trip Ambient 1 Signal: TripAmb 1 Alarm Ambient 1 Alarm RTD Temperature ProtectionAmb 1 Timeout Alarm Ambient 1 Timeout AlarmAmb 1 Invalid Ambient 1 Signal: Invalid Temperature Measurement Value (e.g

caused by an defective or interrupted RTD Measurement)Amb 2 Trip Ambient 2 Signal: TripAmb 2 Alarm Ambient 2 Alarm RTD Temperature ProtectionAmb 2 Timeout Alarm Ambient 2 Timeout AlarmAmb 2 Invalid Ambient 2 Signal: Invalid Temperature Measurement Value (e.g

caused by an defective or interrupted RTD Measurement)Aux 1 Trip Auxiliary 1 Signal: TripAux 1 Alarm Auxiliary 1 Alarm RTD Temperature ProtectionAux 1 Timeout Alarm Auxiliary 1 Timeout AlarmAux 1 Invalid Auxiliary 1 Signal: Invalid Temperature Measurement Value (e.g



caused by an defective or interrupted RTD Measurement)Aux4 Trip Auxiliary 4 Signal: TripAux4 Alarm Auxiliary 4 Alarm RTD Temperature ProtectionAux4 Timeout Alarm Auxiliary 4 Timeout AlarmAux4 Invalid Auxiliary 4 Signal: Invalid Temperature Measurement Value (e.g

caused by an defective or interrupted RTD Measurement)Trip WD W1 Group Trip all Windings of group W1Alarm WD W1 Group Alarm all Windings of group W1TimeoutAlmWDW1Grp Timeout Alarm of group W1

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Name Description

WD W1 Group Invalid Winding W1 Group Signal: Invalid Temperature Measurement Value (e.g caused by an defective or interrupted RTD Measurement)

Trip WD W2 Group Trip all Windings of group W2Alarm WD W2 Group Alarm all Windings of group W2TimeoutAlmWDW2Grp Timeout Alarm of group W2WD W2 Group Invalid Winding W2 Group Signal: Invalid Temperature Measurement


Trip Amb Group Trip all Windings of group AmbientAlarm Amb Group Alarm all Windings of group AmbientTimeoutAlmAmbGrp Timeout Alarm of group AmbientAmb Group Invalid Ambient Group Signal: Invalid Temperature Measurement Value

(e.g caused by an defective or interrupted RTD Measurement)Trip Any Group Trip Any GroupAlarm Any Group Alarm Any GroupTimeoutAlmAnyGrp Timeout Alarm Any GroupVoting Trip Grp 1 Voting Trip Group 1Voting Trip Grp 2 Voting Trip Group 2Timeout Alarm Alarm timeout expiredTrip Aux Group Trip Auxiliary GroupAlarm Aux Group Alarm Auxiliary GroupTimeoutAlmAuxGrp Timeout Alarm Auxiliary GroupAuxGrpInvalid Invalid Auxiliary Group

RTD Temperature Protection Module Counter Values


Hottest WD W1 Hottest winding on side W1 0°C 0 - 200°C [Operation/Measured Values/URTD]

Hottest WD W2 Hottest winding on side W2 0°C 0 - 200°C [Operation/Measured Values/URTD]

Hottest Amb Hottest Ambient Temperature 0°C 0 - 200°C [Operation/Measured Values/URTD]

Hottest Aux Hottest Auxiliary temperature in degrees C. Resettable with "Sys Res OperationsCr" or "All".

0°C 0 - 200°C [Operation/Measured Values/URTD]

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URTDII Module InterfaceURTD

Principle – General UseThe optional Universal Resistance-based Temperature Detector II (URTDII) Module provides temperature data to the protective device from up to 12 RTDs embedded in the motor, generator, transformer, or cable connector and driven equipment (see Eaton I.L. IL02602013E). The temperature data will be shown as measured values and statistics in the Operating Data menu. In addition, each channel will be monitored. The measured data provided by the URTDII Module can also be used for temperature protection (please refer to the Temperature Protection section).

The URTDII conveys multiplexed temperature data back to the relay via a single optical fiber. The URTDII may be mounted remotely from the protective device. The fiber optic connector is located on the X102 terminal of the protective device.

Consider the benefit of mounting the URTDII module away from the protective device and as close to the protected equipment as possible. The big bundle of RTD wires to the protected equipment becomes much shorter. The URTDII may be placed up to 400 ft (121.9 m) from the protective device with the optical fiber connection. Note that the URTDII will require a power supply connection at its remote location.

Connect a suitable source to the power terminals J10A-1 and J10A-2 on the URTDII module. Connect any of the Shield terminals to a non-current-carrying safety ground. It is recommended to have a ground connection on both sides of the unit.

Style Power SupplyURTDII-01 48-240 VAC

48-250 VDCURTDII-02 24-48V DC

URTDII Module Fiber Optic Connection to the Protective Device

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The figure above shows the fiber optic connections between the URTDII Module and the protective device. The protective device supports the optical fiber connection. The following table lists the fiber optic order options.

Fiber Optic Order Options.

Cutler-Hammer Agilent Technologies

Length Catalog Number Number

3.3 ft (1 m) MPFO-1 HBFR-ELS001 or HBFRRLS00116.4 ft (5 m) MPFO-5 HBFR-ELS005 or HBFRRLS00532.8 ft (10 m) MPFO-10 HBFR-ELS010 or HBFRRLS01082.0 ft (25 m) MPFO-25 HBFR-ELS025164.0 ft (50 m) MPFO-50 HBFR-ELS050246.1 ft (75 m) MPFO-75 HBFR-ELS075249.3 ft (76 m) MPFO-76 HBFR-ELS076328.1 ft (100 m) MPFO-100 HBFR-ELS100393.7 ft (120 m) MPFO-120 HBFR-ELS120Uncut Fiber HBFR-EUS (Length)

The optical fiber is the only method of transmitting temperature data from the URTDII Module to the protective device.

Preassembled plastic optical fibers with connectors can be ordered from Eaton, or from any distributor of Agilent Technologies® optical fiber products. In addition, these same distributors offer long rolls of cable with connectors that can be installed in the field. Some distributors will make custom lengths to order.

Force is 11 pounds (50 Newtons).

Surplus length of a pre-cut fiber does not cause a problems. Simply coil and tie the excess fiber at a convenient point. Avoid high tie pressure. Bending radius of the fiber should be greater than 2 in. (50.8 mm).

The fiber termination at the URTDII simply snaps into or out of the connector. To connect the fiber termination at the protective device, push the plug of the fiber optic onto the device interface then turn it until it “snaps”.

The protective device as well as the URTDII have various power supply options. Make certain that the power supply is acceptable for both units before connecting the same power supply to both devices.

Wiring RTDs to the URTDII Module

RTD Control URTDII Connection Name

Terminals Transformer Temperature Monitoring Point

RTD1:Alarm FunctionalTrip FunctionalW1-A AlarmW1-A t-DelayW1-A Trip

MW1 J2-1, J2-2 W1-A – Transformer Winding 1,Phase A RTD Temperature.

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RTD2:Alarm FunctionalTrip FunctionalW1-B AlarmW1-B t-DelayW1-B Trip

MW2 J2-5, J2-6 W1-B - Transformer Winding 1,Phase B RTD Temperature.

RTD3:Alarm FunctionalTrip FunctionalW1-C AlarmW1-C t-DelayW1-C Trip

MW3 J2-8, J2-9 W1-C - Transformer Winding 1,Phase C RTD Temperature.

RTD4:Alarm FunctionalTrip FunctionalW2-A AlarmW2-A t-DelayW2-A Trip

MW4 J2-12, J2-13 W2-A - Transformer Winding 2,Phase A RTD Temperature.

RTD5:Alarm FunctionalTrip FunctionalW2-B AlarmW2-B t-DelayW2-B Trip

MW5 J2-15, J2-16 W2-B - Transformer Winding 2,Phase B RTD Temperature.

RTD6:Alarm FunctionalTrip FunctionalW2-C AlarmW2-C t-DelayW2-C Trip

MW6 J2-19, J2-20 W2-C - Transformer Winding 2,Phase C RTD Temperature.

RTD7:Alarm FunctionalTrip FunctionalAmb1 AlarmAmb1 t-DelayAmb1 Trip

MB1 J10B-19, J10B-20 AMB1 - Transformer Ambient RTD Temperature (1).

RTD8:Alarm FunctionalTrip FunctionalAmb2 AlarmAmb2 t-DelayAmb2 Trip

MB2 J10B-15, J10B-16 AMB2 - Transformer Ambient RTD Temperature (2).

RTD9:Alarm FunctionalTrip FunctionalAux1 AlarmAux1 t-DelayAux1 Trip

LB1 J10B-12, J10B-13 AUX1 – User Defined RTD Temperature.

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LB2 J10B-8, J10B-9 AUX2 – User Defined RTD Temperature.


AUX1 J10B-5, J10B-6 AUX3 – User Defined RTD Temperature.


AUX2 J10B-1, J10B-2 AUX4 – User Defined RTD Temperature.

Consult the URTDII Module Instruction Leaflet (I.L. IL02602013E) for complete instructions.

Three URTD terminals are provided for each RTD input.

The three terminals for any unused RTD input channel should be wired together. For example, if MW5 and MW6 are unused, MW5 terminals J2-15, J2-16, and J2-17 should be wired together and MW6 terminals J2-19, J2-20, J2- 21 should be separately wired together.

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1 -2 +3 C4 S5 -6 +7 C8 -9 +

10 C11 S12 -13 +14 C15 -16 +17 C18 S19 -20 +21 C

212019181716151413121110987654321

C+-SC+-C+-SC+-C+-SC+-

J10B J2

Auxiliary

LoadBearings

MotorBearings

MotorWindings

RTD

RTD

RTD

RTD

RTD

RTD

RTD

RTD

RTD

RTD

RTD

RTD

UniversalRTD Module II

WireShield/Drain

TerminalsMotor

USE TAPE TO INSULATEDO NOT CONNECT CABLE'S SHIELD WIRE AT THIS END!

TerminalsMotor

WireShield/Drain

WireShield/Drain

WireShield/Drain

WireShield/Drain

WireShield/Drain

ETR-5000 IM02602013E

See the figure above for wiring of RTDs to the URTD inputs. Use #18 AWG, three-conductor shielded cable. Note the connection rules in the figure. When making connections to a two-lead RTD, connect two of the cable conductors to one of the RTD leads as shown. Make this connection as close to the transformer as possible. Connect the third cable conductor to the remaining RTD lead.

Connect the shield / drain wire to the Shield terminal as shown in the figure. The RTD cable shield should be connected only at the URTD end, and insulated at the RTD end. The RTD's themselves must not be grounded at the object to be protected.

Remember to set the URTDII module DIP switches according to the types of RTDs in each of the channels (see I.L. IL02602013E).

Direct Commands of the URTD Module



Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/URTD]

Force W1-A Force Measured Value: Winding Temperature

0 - 392 0 [Service/Test Mode (Prot inhibit)/WARNING! Cont?/URTD]

Force W1-B Force Measured Value: Winding Temperature


Force W1-C Force Measured Value: Winding Temperature


Force W2-A Force Measured Value: Winding Temperature


Force W2-B Force Measured Value: Winding Temperature


Force W2-C Force Measured Value: Winding Temperature


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Force Amb1 Force Measured Value: Ambient Temperature


Force Amb2 Force Measured Value: Ambient Temperature


Force Aux1 Force Measured Value: Auxiliary Temperature








Global Protection Parameters of the URTD Module



Permanent, Timeout

Permanent [Service/Test Mode (Prot inhibit)/WARNING! Cont?/URTD]

t-Timeout Force



0.00 – 300.00 s 0.03 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/URTD]

Temperature Unit

Temperature Unit Celsius, Fahrenheit

Celsius [System Para/General Settings]

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URTD Signals (Output States)

Name Description

W1-A Superv Signal: Supervision Channel Winding1 Phase AW1-B Superv Signal: Supervision Channel Winding1 Phase BW1-C Superv Signal: Supervision Channel Winding1 Phase CW2-A Superv Signal: Supervision Channel Winding2 Phase AW2-B Superv Signal: Supervision Channel Winding2 Phase BW2-C Superv Signal: Supervision Channel Winding2 Phase CAmb1 Superv Signal: Supervision Channel Ambient1Amb2 Superv Signal: Supervision Channel Ambient2Aux1 Superv Signal: Supervision Channel Auxiliary1Aux2 Superv Signal: Supervision Channel Auxiliary2Aux3 Superv Signal: Supervision Channel Auxiliary3Aux4 Superv Signal: Supervision Channel Auxiliary4Superv Signal: URTD Supervision Channelactive Signal: URTD activeOuts forced Signal: The State of at least one Relay Output has been set by

force. That means that the state of at least one Relay is forced and hence does not show the state of the assigned signals.

URTD Module Statistics


W1-A max Measured Value: Winding Temperature Maximum Value

[Operation/Statistics/Max/URTD]

W1-B max Measured Value: Winding Temperature Maximum Value


W1-C max Measured Value: Winding Temperature Maximum Value


W2-A max Measured Value: Winding Temperature Maximum Value


W2-B max Measured Value: Winding Temperature Maximum Value


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W2-C max Measured Value: Winding Temperature Maximum Value


Amb1 max Measured Value: Ambient Temperature Maximum Value


Amb2 max Measured Value: Ambient Temperature Maximum Value


Aux1 max Measured Value: Auxiliary Temperature Maximum Value








URTD Measured Values


W1-A Measured Value: Winding Temperature [Operation/Measured Values/URTD]

W1-B Measured Value: Winding Temperature [Operation/Measured Values/URTD]

W1-C Measured Value: Winding Temperature [Operation/Measured Values/URTD]

W2-A Measured Value: Winding Temperature [Operation/Measured Values/URTD]

W2-B Measured Value: Winding Temperature [Operation/Measured Values/URTD]

W2-C Measured Value: Winding Temperature [Operation/Measured Values/URTD]

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ETR-5000 IM02602013E


Amb1 Measured Value: Ambient Temperature [Operation/Measured Values/URTD]

Amb2 Measured Value: Ambient Temperature [Operation/Measured Values/URTD]

Aux1 Measured Value: Auxiliary Temperature [Operation/Measured Values/URTD]




RTD Max Maximum temperature of all channels. [Operation/Measured Values/URTD]

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IM02602013E ETR-5000

Programmable LogicAvailable Elements (Equations):Logic

General DescriptionThe protective device includes programmable logic equations for programming inputs, outputs, blocking of protective functions, and custom logic functions in the relay.

The logic provides control of the relay output contacts based on the state of the inputs that can be chosen from the assignment list (protective function pickups, protective function states, breaker states, system alarms, and module inputs). The User can use the output signals of a logic equation as inputs in higher equations (e.g.: the output signal of logic equation 10 might be used as an input of logic equation 11).

Principle Overview.

If no signal is assigned to a logic gate (All inputs are "0"), then the output of the gate will be set as follows:

• "0" for an AND gate • "1" for a NAND gate• "0" for an OR gate• "1" for a NOR gate

If at least one input signal is assigned to a gate all not assigned inputs are set to:

• "1" for AND / NAND gates• "0" for an OR / NOR gates

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IN1

IN2

IN3

IN4

Reset Latched

Inverting settable

Inverting settable

Inverting settable

Inverting settable

AND

OR

NAND

NOR

Inverting settable

Inverting settable

t-On Delay

t-Off Delay

Gate Out

Timer Out

Out

Out inverted

Set

Reset

Type of logic gate selectable

Delay Timer

S

R

Q

Q

ETR-5000 IM02602013E

Detailed Overview – Overall Logic Diagram.

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φ

AN

DO

RN

AN

DN

OR

t-O

n D

elay

t-Off

Del

ay

Gat

e O

ut

Tim

er O

ut Out

Out

inve

rted

Del

ay T

imer

1..n

, Ass

ignm

ent L

ist

LE[x

].IN

1

Activ

e

Inac

tive

Inve

rting

1XO

R

1..n

, Ass

ignm

ent L

ist

LE[x

].IN

2

Activ

e

Inac

tive

Inve

rting

2XO

R

1..n

, Ass

ignm

ent L

ist

LE[x

].IN

3

Activ

e

Inac

tive

Inve

rting

3XO

R

1..n

, Ass

ignm

ent L

ist

LE[x

].IN

4

Activ

e

Inac

tive

Inve

rting

4XO

R

1..n

, Ass

ignm

ent L

ist

LE[x

].Res

et L

atch

ed

Activ

e

Inac

tive

Inve

rting

Res

etXO

R

Gat

e

AN

D

OR

NA

ND

NO

R

Activ

e

Inac

tive

Inve

rting

Set

XOR

S

Q

R

Q

LE[1

]...[n

]

IM02602013E ETR-5000

Available Gates (Operators)

Within the Logic Equation, the following Gates can be used.

Input Signals

The User can assign up to four Input signals (from the assignment list) to the inputs of the gate.

As an option, each of the four input signals can be inverted (negated).

Timer Gate (On Delay and Off Delay)

The output of the gate can be delayed. The User has the option to set an On and an Off delay.

Latching

The timer issues two signals: an unlatched and a latched signal. The latched output can optionally be inverted.

In order to reset the latched signal, the User has to assign a reset signal from the assignment list. Optionally, the reset signal can also be inverted.

If no »Reset Latched« signal is assigned, then the »LATCH OUT «signal will be identical with the »TIMER OUT « signal.

Cascading Logical Outputs

The device will evaluate output states of the logic equations starting from “Logic Equation 1” up to the logic equation with the highest number. This evaluation cycle will be continuously repeated.

Cascading Logic Equations in an ascending sequence.

Cascading in an ascending sequence means that the User utilizes the output signal of “Logic Equation n” as input of “Logic Equation n+1”. If the state of “Logic Equation n” changes, the state of the output of “Logic Equation n+1” will be updated within the same cycle.

Cascading Logic Equations in a descending sequence.

Cascading in a descending sequence means that the User utilizes the output signal of “Logic Equation n+1” as input of “Logic Equation n”. If the output of “Logic Equation n+1” changes, this change of the feed back signal at the input of “Logic Equation n” will be delayed for one cycle.

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AND ORAND OR

AND NAND OR NOR

Gate

ETR-5000 IM02602013E

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Logic Equation1

LE1.IN1

LE1.IN2

LE1.IN3

LE1.IN4

Output of Logic Equation 1

Logic Equation2

LE2.IN2

LE2.IN3

LE2.IN4


Update within the same evaluation cycle

Update within the next evaluation cycle (1 cycle delay )

Logic Equation2

LE2.IN1

LE2.IN2

LE2.IN3

LE2.IN4


Logic Equation1

LE1.IN2

LE1.IN3

LE1.IN4

Output of Logic Equation1

Update within the next evaluation cycle (1 cycle delay )

Logic Equation2

LE2.IN2

LE2.IN3

LE2.IN4


Logic Equation1

LE1.IN2

LE1.IN3

LE1.IN4


Logic Equation3

LE3.IN1

LE3.IN2

LE3.IN3

LE3.IN4

Logic Equation2


LE2.IN2

LE2.IN3

LE2.IN4


Logic Equation3

LE3.IN2

LE3.IN3

LE3.IN4


Logic Equation1

LE1.IN1

LE1.IN2

LE1.IN3

LE1.IN4



Update within the next but one evaluation cycle (2 cycles delay)



Cascading in Ascending Order

Cascading in Descending Order

IM02602013E ETR-5000

Programmable Logic at the Panel

WARNING improper use of logic equations might result in personal injury or damage the electrical equipment.

Do not use logic equations unless the User can ensure the safe functionality.

How to configure a logic equation?

• Within the Device Planning, set the number of required Logic Equations.

• Call up the [Logic] menu.

• Select a Logic Equation that is to be set.

• Set the Input Signals (where necessary, invert them).

• If required, configure the timer (»On delay« and »Off delay«).

• If the latched output signal is used, assign a reset signal to the reset input.

• Within the »status display«, the User can check the status of the logical inputs and outputs of the logic equation.

In case the logic equations should be cascaded, the User has to be aware of timing delays (cycles) in case of descending sequences (Please refer to the Cascading Logical Outputs section).

By means of the Status Display [Operation/Status Display], the logical states can be verified.

Programmable Logic Via PowerPort-E

WARNING improper use of logic equations might result in personal injury or damage the electrical equipment.

Do not use logic equations unless the User can ensure the safe functionality.

It is recommended to configure the logic via the PowerPort-E application.

How to configure a logic equation?

• Within the Device Planning, set the number of required Logic Equations.

• Call up the [Logic] menu.

• Set the Input Signals (where necessary, invert them).

• If required, configure the timer (»On delay« and »Off delay«).

• If the latched output signal is used, assign a reset signal to the reset input.

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ETR-5000 IM02602013E

• Within the »status display«, the User can check the status of the logical inputs and outputs of the logic equation.

In case the logic equations should be cascaded, the User has to be aware of timing delays (cycles) in case of descending sequences (Please refer to section: Cascading Logical Outputs).

By means of the Status Display [Operation/Status Display], the logical states can be verified.

Device Planning Parameters of the Programmable Logic


No of Equations: Number of required Logic Equations: 0, 5, 10, 20, 40, 80

20 [Device Planning]

Selection List for Logic Input Signals

Name Description

-.- No assignmentProt.Active Signal: ActiveProt.Available Signal: Protection is available.Prot.I dir fwd Signal: Phase current failure forward directionProt.I dir n poss Signal: Phase fault - missing reference voltageProt.I dir rev Signal: Phase current failure reverse directionProt.IR dir fwd Signal: IR Ground fault (calculated) forwardProt.IR dir n poss Signal: IR Ground fault (calculated) direction detection not possibleProt.IR dir rev Signal: IR Ground fault (calculated) reverse directionProt.IX dir fwd Signal: IX Ground fault (measured) forwardProt.IX dir n poss Signal: IX Ground fault (measured) direction detection not possibleProt.IX dir rev Signal: IX Ground fault (measured) reverse directionProt.Pickup Signal: General PickupProt.Trip Signal: General TripBkr[1].SI SingleContactInd Signal: The Position of the Switchgear is detected by one auxiliary

contact (pole) only. Thus indeterminate and disturbed Positions cannot be detected.

Bkr[1].Pos not CLOSE Signal: Pos not CLOSEBkr[1].Pos CLOSE Signal: Breaker is in CLOSE-PositionBkr[1].Pos OPEN Signal: Breaker is in OPEN-PositionBkr[1].Pos Indeterm Signal: Breaker is in Indeterminate PositionBkr[1].Pos Disturb Signal: Breaker Disturbed - Undefined Breaker Position. The feed-


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IM02602013E ETR-5000

Name Description

Bkr[1].Ready Signal: Breaker is ready for operation.Bkr[1].Interl CLOSE Signal: One or more IL_Close inputs are active.Bkr[1].Interl OPEN Signal: One or more IL_Open inputs are active.Bkr[1].CES succesf Command Execution Supervision: Switching command executed

successfully.Bkr[1].CES Disturbed Command Execution Supervision: Switching Command

unsuccessful. Switchgear in disturbed position.Bkr[1].CES Fail TripCmd Command Execution Supervision: Command execution failed

because trip command is pending.Bkr[1].CES SwitchgDir Command Execution Supervision respectivly Switching Direction


Bkr[1].CES CLOSE d OPEN Command Execution Supervision: CLOSE Command during a pending OPEN Command.

Bkr[1].CES SG not ready Command Execution Supervision: Switchgear not readyBkr[1].CES Field Interl Command Execution Supervision: Switching Command not

executed because of field interlocking.Bkr[1].CES SyncTimeout Command Execution Supervision: Switching Command not

excecuted. No Synchronization signal while t-sync was running.Bkr[1].TripCmd Signal: Trip CommandBkr[1].Ack TripCmd Signal: Acknowledge Trip CommandBkr[1].Bwear Slow Breaker Signal: Slow Breaker AlarmBkr[1].Res Bwear Sl Breaker Signal: Resetting the slow breaker alarmBkr[1].CLOSE Cmd Signal: CLOSE command issued to the switchgear. Depending on

the setting the signal may include the CLOSE command of the Prot module.

Bkr[1].OPEN Cmd Signal: OPEN command issued to the switchgear. Depending on the setting the signal may include the OPEN command of the Prot module.

Bkr[1].CLOSE Cmd manual Signal: CLOSE Cmd manualBkr[1].OPEN Cmd manual Signal: OPEN Cmd manualBkr[1].Sync CLOSE request Signal: Synchronous CLOSE requestBkr[2].SI SingleContactInd Signal: The Position of the Switchgear is detected by one auxiliary




Bkr[2].Ready Signal: Breaker is ready for operation.

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ETR-5000 IM02602013E

Name Description

Bkr[2].Interl CLOSE Signal: One or more IL_Close inputs are active.Bkr[2].Interl OPEN Signal: One or more IL_Open inputs are active.Bkr[2].CES succesf Command Execution Supervision: Switching command executed











Bkr[2].CLOSE Cmd manual Signal: CLOSE Cmd manualBkr[2].OPEN Cmd manual Signal: OPEN Cmd manualBkr[2].Sync CLOSE request Signal: Synchronous CLOSE request87.Pickup Signal: Pickup87.Trip Signal: Trip87.TripCmd Signal: Trip Command87H.Pickup Signal: Pickup87H.Trip Signal: Trip87H.TripCmd Signal: Trip Command87GD[1].Pickup Signal: Pickup87GD[1].Trip Signal: Trip87GD[1].TripCmd Signal: Trip Command87GDH[1].Pickup Signal: Pickup87GDH[1].Trip Signal: Trip

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IM02602013E ETR-5000

Name Description

87GDH[1].TripCmd Signal: Trip Command87GD[2].Pickup Signal: Pickup87GD[2].Trip Signal: Trip87GD[2].TripCmd Signal: Trip Command87GDH[2].Pickup Signal: Pickup87GDH[2].Trip Signal: Trip87GDH[2].TripCmd Signal: Trip Command50P[1].Pickup Signal: Pickup50P[1].Trip Signal: Trip50P[1].TripCmd Signal: Trip Command50P[2].Pickup Signal: Pickup50P[2].Trip Signal: Trip50P[2].TripCmd Signal: Trip Command50P[3].Pickup Signal: Pickup50P[3].Trip Signal: Trip50P[3].TripCmd Signal: Trip Command50P[4].Pickup Signal: Pickup50P[4].Trip Signal: Trip50P[4].TripCmd Signal: Trip Command51P[1].Pickup Signal: Pickup51P[1].Trip Signal: Trip51P[1].TripCmd Signal: Trip Command51P[2].Pickup Signal: Pickup51P[2].Trip Signal: Trip51P[2].TripCmd Signal: Trip Command51P[3].Pickup Signal: Pickup51P[3].Trip Signal: Trip51P[3].TripCmd Signal: Trip Command51P[4].Pickup Signal: Pickup51P[4].Trip Signal: Trip51P[4].TripCmd Signal: Trip Command50X[1].Pickup Signal: Pickup IX or IR50X[1].Trip Signal: Trip50X[1].TripCmd Signal: Trip Command50X[2].Pickup Signal: Pickup IX or IR50X[2].Trip Signal: Trip50X[2].TripCmd Signal: Trip Command51X[1].Pickup Signal: Pickup IX or IR51X[1].Trip Signal: Trip

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ETR-5000 IM02602013E

Name Description

51X[1].TripCmd Signal: Trip Command51X[2].Pickup Signal: Pickup IX or IR51X[2].Trip Signal: Trip51X[2].TripCmd Signal: Trip Command50R[1].Pickup Signal: Pickup IX or IR50R[1].Trip Signal: Trip50R[1].TripCmd Signal: Trip Command50R[2].Pickup Signal: Pickup IX or IR50R[2].Trip Signal: Trip50R[2].TripCmd Signal: Trip Command51R[1].Pickup Signal: Pickup IX or IR51R[1].Trip Signal: Trip51R[1].TripCmd Signal: Trip Command51R[2].Pickup Signal: Pickup IX or IR51R[2].Trip Signal: Trip51R[2].TripCmd Signal: Trip Command51Q[1].Pickup Signal: Pickup51Q[1].Trip Signal: Trip51Q[1].TripCmd Signal: Trip Command51Q[2].Pickup Signal: Pickup51Q[2].Trip Signal: Trip51Q[2].TripCmd Signal: Trip Command27M[1].Pickup Signal: Pickup Voltage Element27M[1].Trip Signal: Trip27M[1].TripCmd Signal: Trip Command27M[2].Pickup Signal: Pickup Voltage Element27M[2].Trip Signal: Trip27M[2].TripCmd Signal: Trip Command59M[1].Pickup Signal: Pickup Voltage Element59M[1].Trip Signal: Trip59M[1].TripCmd Signal: Trip Command59M[2].Pickup Signal: Pickup Voltage Element59M[2].Trip Signal: Trip59M[2].TripCmd Signal: Trip Command27A[1].Pickup Signal: Pickup Residual Voltage Supervision-Element27A[1].Trip Signal: Trip27A[1].TripCmd Signal: Trip Command27A[2].Pickup Signal: Pickup Residual Voltage Supervision-Element27A[2].Trip Signal: Trip

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IM02602013E ETR-5000

Name Description

27A[2].TripCmd Signal: Trip Command59A[1].Pickup Signal: Pickup Residual Voltage Supervision-Element59A[1].Trip Signal: Trip59A[1].TripCmd Signal: Trip Command59A[2].Pickup Signal: Pickup Residual Voltage Supervision-Element59A[2].Trip Signal: Trip59A[2].TripCmd Signal: Trip Command46[1].Pickup Signal: Pickup Negative Sequence46[1].Trip Signal: Trip46[1].TripCmd Signal: Trip Command46[2].Pickup Signal: Pickup Negative Sequence46[2].Trip Signal: Trip46[2].TripCmd Signal: Trip Command47[1].Pickup Signal: Pickup Voltage Asymmetry47[1].Trip Signal: Trip47[1].TripCmd Signal: Trip Command47[2].Pickup Signal: Pickup Voltage Asymmetry47[2].Trip Signal: Trip47[2].TripCmd Signal: Trip Command81[1].Pickup Signal: Pickup Frequency Protection (collective signal)81[1].Pickup 81 Signal: Pickup Frequency Protection81[1].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change 81[1].Pickup Vector Surge Signal: Pickup Vector Surge81[1].Trip Signal: Trip Frequency Protection (collective signal)81[1].TripCmd Signal: Trip Command81[1].Trip 81 Signal: Frequency has exceeded the limit.81[1].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[1].Trip Vector Surge Signal: Trip delta phi81[2].Pickup Signal: Pickup Frequency Protection (collective signal)81[2].Pickup 81 Signal: Pickup Frequency Protection81[2].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change 81[2].Pickup Vector Surge Signal: Pickup Vector Surge81[2].Trip Signal: Trip Frequency Protection (collective signal)81[2].TripCmd Signal: Trip Command81[2].Trip 81 Signal: Frequency has exceeded the limit.81[2].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[2].Trip Vector Surge Signal: Trip delta phi81[3].Pickup Signal: Pickup Frequency Protection (collective signal)

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ETR-5000 IM02602013E

Name Description

81[3].Pickup 81 Signal: Pickup Frequency Protection81[3].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-




change 81[6].Pickup Vector Surge Signal: Pickup Vector Surge81[6].Trip Signal: Trip Frequency Protection (collective signal)81[6].TripCmd Signal: Trip Command81[6].Trip 81 Signal: Frequency has exceeded the limit.81[6].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[6].Trip Vector Surge Signal: Trip delta phi32[1].Pickup Signal: Pickup Power Protection32[1].Trip Signal: Trip Power Protection

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IM02602013E ETR-5000

Name Description

32[1].TripCmd Signal: Trip Command32[2].Pickup Signal: Pickup Power Protection32[2].Trip Signal: Trip Power Protection32[2].TripCmd Signal: Trip Command32[3].Pickup Signal: Pickup Power Protection32[3].Trip Signal: Trip Power Protection32[3].TripCmd Signal: Trip Command32V[1].Pickup Signal: Pickup Power Protection32V[1].Trip Signal: Trip Power Protection32V[1].TripCmd Signal: Trip Command32V[2].Pickup Signal: Pickup Power Protection32V[2].Trip Signal: Trip Power Protection32V[2].TripCmd Signal: Trip Command32V[3].Pickup Signal: Pickup Power Protection32V[3].Trip Signal: Trip Power Protection32V[3].TripCmd Signal: Trip CommandZI[1].Ground OUT Signal: Zone Interlocking Ground OUTZI[1].Ground Pickup Signal: Zone Interlocking Ground PickupZI[1].Ground Trip Signal: Zone Interlocking Ground Trip ZI[1].IN Signal: Zone Interlocking INZI[1].OUT Signal: Zone Interlocking OUTZI[1].Phase OUT Signal: Zone Interlocking Phase OUTZI[1].Phase Pickup Signal: Zone Interlocking Phase PickupZI[1].Phase Trip Signal: Zone Interlocking Phase Trip ZI[1].Pickup Signal: Pickup Zone InterlockingZI[1].Trip Signal: Zone Interlocking TripZI[1].TripCmd Signal: Zone Interlocking Trip CommandZI[2].Ground OUT Signal: Zone Interlocking Ground OUTZI[2].Ground Pickup Signal: Zone Interlocking Ground PickupZI[2].Ground Trip Signal: Zone Interlocking Ground Trip ZI[2].IN Signal: Zone Interlocking INZI[2].OUT Signal: Zone Interlocking OUTZI[2].Phase OUT Signal: Zone Interlocking Phase OUTZI[2].Phase Pickup Signal: Zone Interlocking Phase PickupZI[2].Phase Trip Signal: Zone Interlocking Phase Trip ZI[2].Pickup Signal: Pickup Zone InterlockingZI[2].Trip Signal: Zone Interlocking TripZI[2].TripCmd Signal: Zone Interlocking Trip Command24[1].Pickup Signal: Pickup

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ETR-5000 IM02602013E

Name Description

24[1].Trip Signal: Trip24[1].TripCmd Signal: Trip Command24[2].Pickup Signal: Pickup24[2].Trip Signal: Trip24[2].TripCmd Signal: Trip CommandSOTF.Active Signal: ActiveSOTF.enabled Signal: Switch Onto Fault enabled. This Signal can be used to

modify Overcurrent Protection Settings.SOTF.I< Signal: No Load Current.CLPU.detected Signal: Cold Load detectedCLPU.enabled Signal: Cold Load enabledCLPU.ExBlo Signal: External BlockingCLPU.ExBlo1-I Module Input State: External BlockingCLPU.ExBlo2-I Module Input State: External BlockingCLPU.I< Signal: No Load Current.CLPU.Load Inrush Signal: Load InrushCLPU.Settle Time Signal: Settle TimeExP[1].Alarm Signal: AlarmExP[1].Trip Signal: TripExP[1].TripCmd Signal: Trip CommandExP[2].Alarm Signal: AlarmExP[2].Trip Signal: TripExP[2].TripCmd Signal: Trip CommandExP[3].Alarm Signal: AlarmExP[3].Trip Signal: TripExP[3].TripCmd Signal: Trip CommandExP[4].Alarm Signal: AlarmExP[4].Trip Signal: TripExP[4].TripCmd Signal: Trip CommandSudden Press.Alarm Signal: AlarmSudden Press.Trip Signal: TripSudden Press.TripCmd Signal: Trip CommandExt Oil Temp.Alarm Signal: AlarmExt Oil Temp.Trip Signal: TripExt Oil Temp.TripCmd Signal: Trip CommandExt Temp Superv[1].Alarm Signal: AlarmExt Temp Superv[1].Trip Signal: TripExt Temp Superv[1].TripCmd Signal: Trip CommandExt Temp Superv[2].Alarm Signal: AlarmExt Temp Superv[2].Trip Signal: Trip

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IM02602013E ETR-5000

Name Description

Ext Temp Superv[2].TripCmd Signal: Trip CommandExt Temp Superv[3].Alarm Signal: AlarmExt Temp Superv[3].Trip Signal: TripExt Temp Superv[3].TripCmd Signal: Trip CommandRTD.Alarm Alarm RTD Temperature ProtectionRTD.Trip Signal: TripRTD.TripCmd Signal: Trip CommandRTD.W1-A Trip Winding1 Phase A Signal: TripRTD.W1-A Alarm Winding1 Phase A Alarm RTD Temperature ProtectionRTD.W1-A Timeout Alarm Winding1 Phase A Timeout AlarmRTD.W1-B Trip Winding1 Phase B Signal: TripRTD.W1-B Alarm Winding1 Phase B Alarm RTD Temperature ProtectionRTD.W1-B Timeout Alarm Winding1 Phase B Timeout AlarmRTD.W1-C Trip Winding1 Phase C Signal: TripRTD.W1-C Alarm Winding1 Phase C Alarm RTD Temperature ProtectionRTD.W1-C Timeout Alarm Winding1 Phase C Timeout AlarmRTD.W2-A Trip Winding2 Phase A Signal: TripRTD.W2-A Alarm Winding2 Phase A Alarm RTD Temperature ProtectionRTD.W2-A Timeout Alarm Winding2 Phase A Timeout AlarmRTD.W2-B Trip Winding2 Phase B Signal: TripRTD.W2-B Alarm Winding2 Phase B Alarm RTD Temperature ProtectionRTD.W2-B Timeout Alarm Winding2 Phase B Timeout AlarmRTD.W2-C Trip Winding2 Phase C Signal: TripRTD.W2-C Alarm Winding2 Phase C Alarm RTD Temperature ProtectionRTD.W2-C Timeout Alarm Winding2 Phase C Timeout AlarmRTD.Amb 1 Trip Ambient 1 Signal: TripRTD.Amb 1 Alarm Ambient 1 Alarm RTD Temperature ProtectionRTD.Amb 1 Timeout Alarm Ambient 1 Timeout AlarmRTD.Amb 2 Trip Ambient 2 Signal: TripRTD.Amb 2 Alarm Ambient 2 Alarm RTD Temperature ProtectionRTD.Amb 2 Timeout Alarm Ambient 2 Timeout AlarmRTD.Aux 1 Trip Auxiliary 1 Signal: TripRTD.Aux 1 Alarm Auxiliary 1 Alarm RTD Temperature ProtectionRTD.Aux 1 Timeout Alarm Auxiliary 1 Timeout AlarmRTD.Aux 2 Trip Auxiliary 2 Signal: TripRTD.Aux 2 Alarm Auxiliary 2 Alarm RTD Temperature ProtectionRTD.Aux 2 Timeout Alarm Auxiliary 2 Timeout AlarmRTD.Aux 3 Trip Auxiliary 3 Signal: TripRTD.Aux 3 Alarm Auxiliary 3 Alarm RTD Temperature Protection

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ETR-5000 IM02602013E

Name Description

RTD.Aux 3 Timeout Alarm Auxiliary 3 Timeout AlarmRTD.Aux4 Trip Auxiliary 4 Signal: TripRTD.Aux4 Alarm Auxiliary 4 Alarm RTD Temperature ProtectionRTD.Aux4 Timeout Alarm Auxiliary 4 Timeout AlarmRTD.Trip WD W1 Group Trip all Windings of group W1RTD.Alarm WD W1 Group Alarm all Windings of group W1RTD.TimeoutAlmWDW1Grp Timeout Alarm of group W1RTD.Trip WD W2 Group Trip all Windings of group W2RTD.Alarm WD W2 Group Alarm all Windings of group W2RTD.TimeoutAlmWDW2Grp Timeout Alarm of group W2RTD.Trip Amb Group Trip all Windings of group AmbientRTD.Alarm Amb Group Alarm all Windings of group AmbientRTD.TimeoutAlmAmbGrp Timeout Alarm of group AmbientRTD.Trip Aux Group Trip Auxiliary GroupRTD.Alarm Aux Group Alarm Auxiliary GroupRTD.TimeoutAlmAuxGrp Timeout Alarm Auxiliary GroupRTD.Trip Any Group Trip Any GroupRTD.Alarm Any Group Alarm Any GroupRTD.TimeoutAlmAnyGrp Timeout Alarm Any GroupRTD.Timeout Alarm Alarm timeout expiredRTD.Voting Trip Grp 1 Voting Trip Group 1RTD.Voting Trip Grp 2 Voting Trip Group 2BF[1].Lockout Signal: LockoutBF[1].Pickup Signal: BF-Module Started (Pickup)BF[1].Trip Signal: Breaker Failure TripBF[2].Lockout Signal: LockoutBF[2].Pickup Signal: BF-Module Started (Pickup)BF[2].Trip Signal: Breaker Failure TripTCM[1].Not Possible Not possible because no state indicator assigned to the breaker.TCM[1].Pickup Signal: Pickup Trip Circuit SupervisionTCM[2].Not Possible Not possible because no state indicator assigned to the breaker.TCM[2].Pickup Signal: Pickup Trip Circuit SupervisionCTS[1].Pickup Signal: Pickup Current Transformer Measuring Circuit SupervisionCTS[2].Pickup Signal: Pickup Current Transformer Measuring Circuit SupervisionLOP.Pickup Signal: Pickup Loss of PotentialSysA.Alm Current Demd Signal: Alarm Current demand valueSysA.Alarm I THD Signal: Alarm Total Harmonic Distortion CurrentSysA.Alarm V THD Signal: Alarm Total Harmonic Distortion VoltageSysA.Alarm VA Demand Signal: Alarm VAs demand value

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IM02602013E ETR-5000

Name Description

SysA.Alarm VA Power Signal: Alarm VAs peakSysA.Alarm VAr Demand Signal: Alarm VARs demand valueSysA.Alarm VAr Power Signal: Alarm VArs peakSysA.Alarm Watt Demand Signal: Alarm WATTS demand valueSysA.Alarm Watt Power Signal: Alarm WATTS peakSysA.Trip Current Demand Signal: Trip Current demand valueSysA.Trip I THD Signal: Trip Total Harmonic Distortion CurrentSysA.Trip V THD Signal: Trip Total Harmonic Distortion VoltageSysA.Trip VA Demand Signal: Trip VAs demand valueSysA.Trip VA Power Signal: Trip VAs peakSysA.Trip VAr Demand Signal: Trip VARs demand valueSysA.Trip VAr Power Signal: Trip VArs peakSysA.Trip Watt Demand Signal: Trip WATTS demand valueSysA.Trip Watt Power Signal: Trip WATTS peakWired Inputs.52a M1-I State of the module input: Main 1 Breaker ClosedWired Inputs.52b M1-I State of the module input: Main 1 Breaker OpenWired Inputs.TOCa M1-I State of the module input: Main 1 Breaker Connected Wired Inputs.43/10 M1-I State of the module input: Main 1 Breaker Selected To Trip Wired Inputs.52a M2-I State of the module input: Main 2 Breaker ClosedWired Inputs.52b M2-I State of the module input: Main 2 Breaker OpenWired Inputs.TOCa M2-I State of the module input: Main 2 Breaker Connected Wired Inputs.43/10 M2-I State of the module input: Main 2 Breaker Selected To TripWired Inputs.52a T-I State of the module input: Tie Breaker ClosedWired Inputs.52b T-I State of the module input: Tie Breaker OpenWired Inputs.TOCa T-I State of the module input: Tie Breaker Connected Wired Inputs.43/10 T-I State of the module input: Tie Breaker Selected To TripWired Inputs.43 M-I State of the module input: System In ManualWired Inputs.43 A-I State of the module input: System in AutoWired Inputs.43 P1-I State of the module input: Preferred Source 1Wired Inputs.43 P2-I State of the module input: Preferred Source 2Wired Inputs.Bkr Trouble-I Breaker TroubleDI-8P X1.DI 1 Signal: Digital InputDI-8P X1.DI 2 Signal: Digital InputDI-8P X1.DI 3 Signal: Digital InputDI-8P X1.DI 4 Signal: Digital InputDI-8P X1.DI 5 Signal: Digital InputDI-8P X1.DI 6 Signal: Digital InputDI-8P X1.DI 7 Signal: Digital InputDI-8P X1.DI 8 Signal: Digital Input

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ETR-5000 IM02602013E

Name Description

RO-4Z X2.ZI OUT Signal: Zone Interlocking OUTRO-4Z X2.RO 1 Signal: Relay OutputRO-4Z X2.RO 2 Signal: Relay OutputRO-4Z X2.RO 3 Signal: Relay OutputRO-4Z X2.RO 4 Signal: Relay OutputRO-4Z X5.ZI OUT Signal: Zone Interlocking OUTRO-4Z X5.RO 1 Signal: Relay OutputRO-4Z X5.RO 2 Signal: Relay OutputRO-4Z X5.RO 3 Signal: Relay OutputRO-4Z X5.RO 4 Signal: Relay OutputRO-4 X5.RO 1 Signal: Relay OutputRO-4 X5.RO 2 Signal: Relay OutputRO-4 X5.RO 3 Signal: Relay OutputRO-4 X5.RO 4 Signal: Relay OutputPres[1].Pickup Signal: PickupPres[1].Trip Signal: TripPres[1].TripCmd Signal: Trip CommandPres[2].Pickup Signal: PickupPres[2].Alarm AlarmTmp1[1].Pickup Signal: PickupTmp1[1].Trip Signal: TripTmp1[1].TripCmd Signal: Trip CommandTmp1[2].Pickup Signal: PickupTmp1[2].Alarm AlarmTmp2[1].Pickup Signal: PickupTmp2[1].Trip Signal: TripTmp2[1].TripCmd Signal: Trip CommandTmp2[2].Pickup Signal: PickupTmp2[2].Alarm AlarmVibr[1].Pickup Signal: PickupVibr[1].Trip Signal: TripVibr[1].TripCmd Signal: Trip CommandVibr[2].Pickup Signal: PickupVibr[2].Alarm AlarmVBat[1].Pickup Signal: PickupVBat[1].Trip Signal: TripVBat[1].TripCmd Signal: Trip CommandVBat[2].Pickup Signal: PickupVBat[2].Alarm Alarm

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IM02602013E ETR-5000

Name Description

TapV[1].Pickup Signal: PickupTapV[1].Trip Signal: TripTapV[1].TripCmd Signal: Trip CommandTapV[2].Pickup Signal: PickupTapV[2].Alarm AlarmAnaP[1].Pickup Signal: PickupAnaP[1].Trip Signal: TripAnaP[1].TripCmd Signal: Trip CommandAnaP[2].Pickup Signal: PickupAnaP[2].Alarm AlarmIEC61850.VirtOut1-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut2-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut3-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut4-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut5-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut6-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut7-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut8-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut9-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut10-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut11-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut12-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut13-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut14-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut15-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut16-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtInp1 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp2 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp3 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp4 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp5 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp6 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp7 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp8 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp9 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp10 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp11 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp12 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp13 Signal: Virtual Input (IEC61850 GGIO Ind)

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ETR-5000 IM02602013E

Name Description

IEC61850.VirtInp14 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp15 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp16 Signal: Virtual Input (IEC61850 GGIO Ind)Logic.LE1.Gate Out Signal: Output of the logic gateLogic.LE1.Timer Out Signal: Timer OutputLogic.LE1.Out Signal: Latched Output (Q)Logic.LE1.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE2.Gate Out Signal: Output of the logic gateLogic.LE2.Timer Out Signal: Timer OutputLogic.LE2.Out Signal: Latched Output (Q)Logic.LE2.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE3.Gate Out Signal: Output of the logic gateLogic.LE3.Timer Out Signal: Timer OutputLogic.LE3.Out Signal: Latched Output (Q)Logic.LE3.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE4.Gate Out Signal: Output of the logic gateLogic.LE4.Timer Out Signal: Timer OutputLogic.LE4.Out Signal: Latched Output (Q)Logic.LE4.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE5.Gate Out Signal: Output of the logic gateLogic.LE5.Timer Out Signal: Timer OutputLogic.LE5.Out Signal: Latched Output (Q)Logic.LE5.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE6.Gate Out Signal: Output of the logic gateLogic.LE6.Timer Out Signal: Timer OutputLogic.LE6.Out Signal: Latched Output (Q)Logic.LE6.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE7.Gate Out Signal: Output of the logic gateLogic.LE7.Timer Out Signal: Timer OutputLogic.LE7.Out Signal: Latched Output (Q)Logic.LE7.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE8.Gate Out Signal: Output of the logic gateLogic.LE8.Timer Out Signal: Timer OutputLogic.LE8.Out Signal: Latched Output (Q)Logic.LE8.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE9.Gate Out Signal: Output of the logic gateLogic.LE9.Timer Out Signal: Timer OutputLogic.LE9.Out Signal: Latched Output (Q)Logic.LE9.Out inverted Signal: Negated Latched Output (Q NOT)

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Name Description

Logic.LE78.Timer Out Signal: Timer OutputLogic.LE78.Out Signal: Latched Output (Q)Logic.LE78.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE79.Gate Out Signal: Output of the logic gateLogic.LE79.Timer Out Signal: Timer OutputLogic.LE79.Out Signal: Latched Output (Q)Logic.LE79.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE80.Gate Out Signal: Output of the logic gateLogic.LE80.Timer Out Signal: Timer OutputLogic.LE80.Out Signal: Latched Output (Q)Logic.LE80.Out inverted Signal: Negated Latched Output (Q NOT)Sys.Maint Mode Active Signal: Arc Flash Reduction Maintenance ActiveSys.Maint Mode Comm Signal: Arc Flash Reduction Maintenance Comm ModeSys.Maint Mode DI Signal: Arc Flash Reduction Maintenance Digital Input ModeSys.Maint Mode Inactive Signal: Arc Flash Reduction Maintenance InactiveSys.MaintMode Manually Signal: Arc Flash Reduction Maintenance Manual ModeSys.Maint Mode-I Module Input State: Arc Flash Reduction Maintenance SwitchSys.Min. 1 param changed Signal: At least one parameter has been changedSys.PS 1 Signal: Parameter Set 1Sys.PS 2 Signal: Parameter Set 2Sys.PS 3 Signal: Parameter Set 3Sys.PS 4 Signal: Parameter Set 4Sys.PS1-I State of the module input, respectively of the signal, that should

activate this Parameter Setting Group.Sys.PS2-I State of the module input, respectively of the signal, that should



activate this Parameter Setting Group.Sys.PSS manual Signal: Manual switch over of a Parameter SetSys.PSS via Comm Signal: Parameter Set Switch via CommunicationSys.PSS via Inp fct Signal: Parameter Set Switch via Input FunctionSys.Res AlarmCr Signal: Res AlarmCrSys.Res OperationsCr Signal: Res OperationsCrSys.Res TotalCr Signal: Res TotalCrSys.Res TripCmdCr Signal: Res TripCmdCr

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IM02602013E ETR-5000

Global Protection Parameter of the Programmable Logic


LE1.Gate Logic gate AND, OR, NAND, NOR

AND [Logic/LE 1]

LE1.IN1 Assignment of the Input Signal 1..n, LogicList -.- [Logic/LE 1]

LE1.Inverting1 Inverting the input signals.

Only available if an input signal has been assigned.

Inactive, Active

Inactive [Logic/LE 1]




Inactive, Active





Inactive, Active





Inactive, Active


LE1.t-On Delay Switch On Delay 0.00 – 36000.00 s 0.00 s [Logic/LE 1]

LE1.t-Off Delay Switch Off Delay 0.00 – 36000.00 s 0.00 s [Logic/LE 1]

LE1.Reset Latched

Reset Signal for the Latching 1..n, LogicList -.- [Logic/LE 1]

LE1.Inverting Reset

Inverting Reset Signal for the Latching Inactive, Active


LE1.Inverting Set

Inverting the Setting Signal for the Latching Inactive, Active


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Programmable Logic Inputs


LE1.Gate In1-I State of the module input: Assignment of the Input Signal

[Logic/LE 1]


[Logic/LE 1]


[Logic/LE 1]


[Logic/LE 1]

LE1.Reset Latch-I State of the module input: Reset Signal for the Latching

[Logic/LE 1]

Programmable Logic Outputs

Name Description

LE1.Gate Out Signal: Output of the logic gateLE1.Timer Out Signal: Timer OutputLE1.Out Signal: Latched Output (Q)LE1.Out inverted Signal: Negated Latched Output (Q NOT)

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IM02602013E ETR-5000

CommissioningBefore starting work on an open switchboard, it is required that the switchboard is de-energized and the following five safety regulations have been met.

Safety precautions:• Disconnect the power supply;• Secure against reconnection;• Verify that the equipment is de-energized;• Connect to ground and short-circuit all phases; and• Cover or safeguard all live adjacent parts.

The secondary circuit of a current transformer must never be opened during operation. The prevailing high voltages can cause severe injury or death.

Even when the auxiliary voltage is switched off, it is likely that there are still hazardous voltages at the component connections.

All locally applicable national and international installation and safety regulations for working at electrical power installations MUST always to be followed.

Prior to the initial voltage connection, the following must be guaranteed:

• Correct grounding of the device;• That all signal circuits are tested;• That all control circuits are tested;• Transformer wiring is checked;• Correct rating of the CTs;• Correct burden of the CTs;• That the operational conditions are in line with the Technical Data;• Correct rating of the transformer protection;• Function of the transformer fuses;• Correct wiring of all digital inputs;• Polarity and capacity of the supply voltage; and• Correct wiring of the analog inputs and outputs.

The permissible deviations of measuring values and device adjustment are dependent on the Technical Data/Tolerances.

Commissioning/Protection Test

Commissioning/protection test must be carried out by authorized and qualified personnel. Before the device is put into operation, the related documentation MUST be read and understood.

With any test of the protection functions, the following has to be checked:

• Is activation/tripping saved in the event recorder?• Is tripping saved in the fault recorder?• Is tripping saved in the waveform recorder?• Are all signals/messages correctly generated?• Do all generally configured blocking functions work properly?

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ETR-5000 IM02602013E

• Do all temporarily configured (via DI) blocking functions work properly?• To enable checks on all LEDs and relay functions, these have to be

provided with the relevant pickup (alarm) and tripping functions of the respective protection functions/elements. This MUST be tested in practical operation.

Check of all temporary blockings (via digital inputs).

• In order to avoid malfunctions, all blockings related to tripping/non-tripping of protection function MUST be tested. The test can be very complex and should therefore be performed by the same personnel who set up the protection concept.

Check all general trip blockings. All general trip blockings MUST be tested.

Prior to the initial operation of the protection device, all tripping times and values shown in the adjustment list MUST be confirmed by a secondary test.

Any description of functions, parameters, inputs, or outputs that does not match the device in hand can be ignored.

Decommissioning – Removing the Plug from the Relay

Dismounting the relay will lead to a loss of the protection functionality. Ensure that there is a back-up protection. If you are not aware of the consequences of decommissioning the device – STOP! DO NOT start.

Inform SCADA before you start.

Switch-off the power supply.

Ensure that the cabinet is de-energized and that there are no voltages that could lead to injury of personnel.

Disconnect the terminals at the rear-side of the device. DO NOT pull any cable – pull on the plug! If it is stuck, use a screw driver.

Fasten the cables and terminals in the cabinet by means of cable clips to ensure that no accidental electrical connections are caused.

Hold the device at the front-side while removing the mounting nuts.

Remove the device carefully from the cabinet.

In case no other device is to be mounted or replaced, cover/close the cut-out in the front-door.

Close the cabinet.

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IM02602013E ETR-5000

Service and Commissioning SupportWithin the service menu, various functions support maintenance and commissioning of the device.

General

Within the [Service/General] menu, the User can initiate a reboot of the device.

Maintenance Mode

Principle – General UseThe Maintenance Mode can be used to reduce arc flash levels. Refer to Std. NFPA70E.

DO NOT attempt to install or perform maintenance on equipment while it is energized. Severe personal injury or death can result from contact with energized equipment. Verify that no voltage is present before opening doors of the switchboard.

If maintenance will be performed on a device, special protective clothing and equipment MUST BE USED and all industry standard procedures MUST BE FOLLOWED. Failure to do so can result in severe personal injury or death.

The Maintenance Mode can improve safety by providing a simple and reliable method to reduce fault clearing time and lower incident energy levels at energized panels. The Maintenance Mode allows the User to switch to more sensitive settings via the HMI/panel, Communication, or via a Digital Input while maintenance work is being performed at an energized panel or device. The more sensitive settings provide greater security for maintenance personnel and helps reduce the possibility of injury.

The status of the Maintenance Mode (active/inactive) is stored power fail-safe.

Manual activation is only possible via the HMI/panel (not via PowerPort-E).

The Maintenance Mode can be activated:

• Manually (only at the HMI/panel);• Via communication; or• Via a digital input.

Changing to another mode is only possible if there is no active Activation Signal (e.g.: if the device is in the “Via Digital Input Mode” and while the assigned Digital Input is “true”, the User cannot switch to the “Manual Mode”).

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Before Use

The sensitivity settings for the Maintenance Mode have to be calculated and programmed into the device (according to Std. NFPA70E). They are not part of the device by default.

When the Maintenance Mode is enabled and fault current causes its operation, the fault clearing time of the associated breaker has to be very fast. Calculate the sensitivity setting on the basis of Std. NFPA70E.

Program those sensitivity settings either into a setting group or into Adaptive Parameters.

How to Use the Maintenance ModeCalculate the sensitivity setting on the basis of Std. NFPA70E. Program those sensitivity settings either into a setting group or into Adaptive Parameters.

The Maintenance Mode offers two output signals: “Maint Mode activated” and “Maint Mode not activated”.

The »Maint Mode.ACTIVATED« signal should be used to:

• Switch to another setting group (in case the sensitivity settings are saved within this setting group);• Activate “Adaptive Parameters” (in case the sensitivity settings are saved within these adaptive

parameters); and/or• Block or activate dedicated functions.

Please see the Adaptive Parameters section for more details.

The »Maint Mode.NOT ACTIVATED« signal should be used to:

• Switch back to the standard setting group when Maintenance Mode should not be used.

For fast access, the Maintenance Mode can be accessed by means of the »Softkey« Maint on the start screen (root) of the device.

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IM02602013E ETR-5000

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ETR-5000 IM02602013E

Forcing the Relay Output Contacts

The parameters, their defaults, and setting ranges have to be taken from Relay Output Contacts section.


The User MUST ENSURE that the relay output contacts operate normally after maintenance is completed. If the relay output contacts do not operate normally, the protective device WILL NOT provide protection.

For commissioning purposes or for maintenance, relay output contacts can be set by force.

Within this mode [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Force RO], relay output contacts can be set by force:

• Permanent; or• Via timeout.

If they are set with a timeout, they will keep their “Force Position” only as long as this timer runs. If the timer expires, the relay will operate normally. If they are set as Permanent, they will keep the “Force Position” continuously.

There are two options available:

• Forcing a single relay »Force Rox«; and• Forcing an entire group of relay output contacts »Force all Outs«.

Forcing an entire group takes precedence over forcing a single relay output contact!

A relay output contact WILL NOT follow a force command as long as it is disarmed at the same time.

A relay output contact WILL follow a force command:

• If it is not disarmed; and • If the Direct Command is applied to the relay(s).

Keep in mind, that forcing all relay output contacts (of the same assembly group) takes precedence over the force command of a single relay output contact.

Disarming the Relay Output Contacts

The parameters, their defaults, and setting ranges have to be taken from the Relay Output Contacts section.

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IM02602013E ETR-5000


Within this mode [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED], entire groups of relay output contacts can be disabled. By means of this test mode, contact outputs switching actions of the relay output contacts are prevented. If the relay output contacts are disarmed, maintenance actions can be carried out without the risk of taking entire processes off-line.

The User MUST ENSURE that the relay output contacts are ARMED AGAIN after maintenance is complete. If they are not armed, the protective device WILL NOT provide protection.

Zone Interlocking Output and the Supervision Contact cannot be disarmed.

Within this mode [Service/Test Mode (Prot inhibit)/WARNING! Cont?/DISARMED] entire groups of relay output contacts can be disarmed:


If they are set with a timeout, they will keep their “Disarm Position” only as long as this timer runs. If the timer expires, the relay output contacts will operate normally. If they are set Permanent, they will keep the “Disarm State” continuously.

A relay output contact WILL NOT be disarmed as long as:

• A relay output contact WILL NOT be disarmed if it is latched (and not yet reset).

• A relay output contact WILL NOT be disarmed as long as a running t-OFF-delay timer is not yet expired (hold time of a relay output contact).

• If the Disarm Control is not set to active.

• If the Direct Command is not applied.

A relay output contact WILL be disarmed if it is not latched and:

• If there is no running t-OFF-delay timer (hold time of a relay output contact); and

• If the DISARM Control is set to active; and

• If the Direct Command Disarm is applied.

Forcing RTDs** = Availability depends on ordered device.

The parameters, their defaults, and setting ranges have to be taken from RTD/UTRD section.

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ETR-5000 IM02602013E


The User MUST ENSURE that the RTDs operate normally after maintenance is completed. If the RTDs do not operate normally, the protective device WILL NOT provide protection.

For commissioning purposes or for maintenance, RTD temperatures can be set by force.

Within this mode [Service/Test Mode (Prot inhibit)/WARNING! Cont?/URTD], RTD temperatures can be set by force:


If they are set with a timeout, they will keep their “Forced Temperature” only as long as this timer runs. If the timer expires, the RTD will operate normally. If they are set as »Permanent«, they will keep the “Forced Temperature” continuously. This menu will show the measured values of the RTDs until the User activates the force mode by calling up the »Function«. As soon as the force mode is activated, the shown values will be frozen as long as this mode is active. Now the User can force RTD values. As soon as the force mode is deactivated, measured values will again be shown.

Forcing Analog Outputs*• = Availability depends on ordered device.

The parameters, their defaults, and setting ranges have to be taken from Analog Output section.


The User MUST ENSURE that the Analog Outputs operate normally after maintenance is completed. Do not use this mode if forced Analog Outputs cause issues in external processes.

For commissioning purposes or for maintenance, Analog Outputs can be set by force.

Within this mode [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Outputs], Analog Outputs can be set by force:


If they are set with a timeout, they will keep their “Forced Value” only as long as this timer runs. If the timer expires, the Analog Output will operate normally. If they are set as »Permanent«, they will keep the “Forced Value” continuously. This menu will show the current value that is assigned to the Analog Output until the User activates the force mode by calling up the »Function«. As soon as the force mode is activated, the shown values will be frozen as long as this mode is active. Now the User can force Analog Output values. As soon as the force mode is deactivated, measured values will again be shown.

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Forcing Analog Inputs*• = Availability depends on ordered device.

The parameters, their defaults, and setting ranges have to be taken from Analog Inputs section.


The User MUST ENSURE that the Analog Inputs operate normally after maintenance is completed.

For commissioning purposes or for maintenance, Analog Inputs can be set by force.

Within this mode [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Analog Inputs], Analog Inputs can be set by force:


If they are set with a timeout, they will keep their “Forced Value” only as long as this timer runs. If the timer expires, the Analog Input will operate normally. If they are set as »Permanent«, they will keep the “Forced Value” continuously. This menu will show the current value that is fed to the Analog Input until the User activates the force mode by calling up the »Function«. As soon as the force mode is activated, the shown value will be frozen as long as this mode is active. Now the User can force the Analog Input value. As soon as the force mode is deactivated, measured value will be shown again.

Failure Simulator (Sequencer)*Available Elements:Sgen

* = Availability depends on ordered device. This applies especially to the availability of voltage and current. Voltage simulation is only avail-able in voltage relays, current simulation is only available in current relays.

For commissioning support and in order to analyze failures, the protective device offers the option to simulate measuring quantities. The simulation menu can be found within the [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sine wave gen] menu. The simulation cycle consists of three states:

• Pre-failure;• Failure; and• Post-failure State (Phase).

Within the [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sine wave gen/Configuration] sub-menu, the duration of each phase can be set. In addition; the measuring quantities to be simulated can be determined (e.g.: voltages, currents, and the corresponding angles) for each phase (and ground). The simulation will be terminated, if a phase current exceeds 0.1 times In. A simulation can be restarted, five seconds after the current has fallen below 0.1 times In.

Setting the device into the simulation mode means taking the protective device out of operation for the duration of the simulation. Do not use this feature during operation of the device if the User cannot guarantee that there is a running and properly working backup protection.

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The energy counters will be stopped while the failure simulator is running.

The simulation voltages are always phase to neutral voltages, irrespectively of the mains voltage transformers' connection method (Phase-to-phase/Wey/Open Delta).

Application Options of the Fault Simulator**:

Stop Options Cold Simulation (Option 1) Hot Simulation (Option 2)Do not stop

Run complete: Pre Failure, Failure, Post Failure.

How To?: Call up [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sine wave gen/Process] Ex Force Post = no assignment and

Press/Call up Start Simulation.

Simulation without tripping the breaker:Blocking protective Trips to the Breaker. That means verifying if the protective device generates a trip without energizing the trip coil of the breaker (similar to disarm the relay output contact).

How To?: Call up [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sine wave gen/Process]

Trip Cmd Mode = No Trip

Simulation is authorized to trip the breaker:How To?: Call up [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sine wave gen/Process]

Trip Cmd Mode = Trip

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pre postFailure Simulation

PreFault FaultSimulation PostFault

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IM02602013E ETR-5000

Stop Options Cold Simulation (Option 1) Hot Simulation (Option 2)Stop by external signal

Force Post: As soon as this signal becomes true, the Fault Simulation will be forced to switch into the Post Failure mode. How To?: Call up [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sine wave gen/Process]

Ex Force Post = Assigned SignalManual stop

As soon as this signal becomes true, the Fault Simulation will be terminated and the device changes back to normal operation. How To?: Call up [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sine wave gen/Process]

Press/Call up Stop Simulation.

**Please note: Due to internal dependencies, the frequency of the simulation module is 0.16% greater than the rated one.

Device Planning Parameters of the Failure Simulator




Global Protection Parameter of the Failure Simulator


PreFault Pre Fault Duration 0.00 – 300.00 s 0.0 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/Times]

FaultSimulation Duration of Fault Simulation 0.00 – 10800.00 s 0.0 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/Times]

PostFault PostFault 0.00 – 300.00 s 0.0 s [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/Times]

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TripCmd Mode Trip Command Mode No TripCmd, With TripCmd

No TripCmd [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Process]

Ex Start Simulation

External Start of Fault Simulation (Using the test parameters)

1..n, Assignment List -.- [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Process]

ExBlo External blocking of the module, if blocking is activated (allowed) within a parameter set and if the state of the assigned signal is true.

1..n, Assignment List Bkr[1].Pos CLOSE

[Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Process]

Ex ForcePost Force Post state. Abort simulation. 1..n, Assignment List -.- [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Process]

Voltage Parameter of the Failure Simulator


VA Fund. Voltage Fundamental Magnitude in Pre State: Phase A

0.00 – 2.00 Vn 1.0 Vn [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/PreFault/VT]

VB Fund. Voltage Fundamental Magnitude in Pre State: Phase B


VC Fund. Voltage Fundamental Magnitude in Pre State: Phase C


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VX Fund. Voltage Fundamental Magnitude in Pre State: VX


Angle VA Fund. Start Position respectively Start Angle of the Voltage Phasor during Pre Phase:Phase A

-360 - 360° 0° [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/PreFault/VT]

Angle VB Fund. Start Position respectively Start Angle of the Voltage Phasor during Pre Phase:Phase B


Angle VC Fund.

Start Position respectively Start Angle of the Voltage Phasor during Pre Phase:Phase C


Angle VX meas Fund.

Start Position respectively Start Angle of the Voltage Phasor during Pre Phase: VX


VA Fund. Voltage Fundamental Magnitude in Fault State: Phase A

0.00 – 2.00 Vn 0.5 Vn [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/FaultSimulation/VT]

VB Fund. Voltage Fundamental Magnitude in Fault State: Phase B


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VC Fund. Voltage Fundamental Magnitude in Fault State: Phase C


VX Fund. Voltage Fundamental Magnitude in Fault State: Phase VX


Angle VA Fund. Start Position respectively Start Angle of the Voltage Phasor during Fault Phase:Phase A

-360 - 360° 0° [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/FaultSimulation/VT]

Angle VB Fund. Start Position respectively Start Angle of the Voltage Phasor during Fault Phase:Phase B


Angle VC Fund.

Start Position respectively Start Angle of the Voltage Phasor during Fault Phase:Phase C


Angle VX meas Fund.

Start Position respectively Start Angle of the Voltage Phasor during Fault Phase: VX


VA Fund. Voltage Fundamental Magnitude during Post phase: Phase A

0.00 – 2.00 Vn 1.0 Vn [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/PostFault/VT]

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VB Fund. Voltage Fundamental Magnitude during Post phase: Phase B


VC Fund. Voltage Fundamental Magnitude during Post phase: Phase C


VX Fund. Voltage Fundamental Magnitude during Post phase: Phase VX


Angle VA Fund. Start Position respectively Start Angle of the Voltage Phasor during Post phase: Phase A

-360 - 360° 0° [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/PostFault/VT]

Angle VB Fund. Start Position respectively Start Angle of the Voltage Phasor during Post phase: Phase B


Angle VC Fund.

Start Position respectively Start Angle of the Voltage Phasor during Post phase: Phase C


Angle VX meas Fund.

Start Position respectively Start Angle of the Voltage Phasor during Post phase: Phase VX


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Current Parameter of the Failure Simulator


CT W1.IA Fund.

Current Fundamental Magnitude in Pre State: Phase A

0.00 – 40.00 In 0.0 In [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/PreFault/CT W1]

CT W1.IB Fund.

Current Fundamental Magnitude in Pre State: Phase B


CT W1.IC Fund.

Current Fundamental Magnitude in Pre State: Phase C


CT W1.IX meas Fund.

Current Fundamental Magnitude in Pre State: IX


CT W1.Angle IA Fund.

Start Position respectively Start Angle of the Current Phasor during Pre Phase:Phase A

-360 - 360° 0° [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/PreFault/CT W1]

CT W1.Angle IB Fund.

Start Position respectively Start Angle of the Current Phasor during Pre Phase:Phase B


CT W1.Angle IC Fund.

Start Position respectively Start Angle of the Current Phasor during Pre Phase:Phase C


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CT W1.Angle IX meas Fund.

Start Position respectively Start Angle of the Current Phasor during Pre Phase: IX


CT W1.IA Fund.

Current Fundamental Magnitude in Fault State: Phase A

0.00 – 40.00 In 0.0 In [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/FaultSimulation/CT W1]

CT W1.IB Fund.

Current Fundamental Magnitude in Fault State: Phase B


CT W1.IC Fund.

Current Fundamental Magnitude in Fault State: Phase C


CT W1.IX meas Fund.

Current Fundamental Magnitude in Fault State: IX



Start Position respectively Start Angle of the Current Phasor during Fault Phase:Phase A

-360 - 360° 0° [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/FaultSimulation/CT W1]


Start Position respectively Start Angle of the Current Phasor during Fault Phase:Phase B


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Start Position respectively Start Angle of the Current Phasor during Fault Phase:Phase C



Start Position respectively Start Angle of the Current Phasor during Fault Phase: IX


CT W1.IA Fund.

Current Fundamental Magnitude during Post phase: Phase A

0.00 – 40.00 In 0.0 In [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/PostFault/CT W1]

CT W1.IB Fund.

Current Fundamental Magnitude during Post phase: Phase B


CT W1.IC Fund.

Current Fundamental Magnitude during Post phase: Phase C


CT W1.IX meas Fund.

Current Fundamental Magnitude during Post phase: IX



Start Position respectively Start Angle of the Current Phasor during Post phase: Phase A

-360 - 360° 0° [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Configuration/PostFault/CT W1]

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Start Position respectively Start Angle of the Current Phasor during Post phase: Phase B



Start Position respectively Start Angle of the Current Phasor during Post phase: Phase C



Start Position respectively Start Angle of the Current Phasor during Post phase: IX


CT W2.IA Fund.

Current Fundamental Magnitude in Pre State: Phase A


CT W2.IB Fund.

Current Fundamental Magnitude in Pre State: Phase B


CT W2.IC Fund.

Current Fundamental Magnitude in Pre State: Phase C


CT W2.IX meas Fund.

Current Fundamental Magnitude in Pre State: IX


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Start Position respectively Start Angle of the Current Phasor during Pre Phase:Phase A



Start Position respectively Start Angle of the Current Phasor during Pre Phase:Phase B



Start Position respectively Start Angle of the Current Phasor during Pre Phase:Phase C



Start Position respectively Start Angle of the Current Phasor during Pre Phase: IX


CT W2.IA Fund.

Current Fundamental Magnitude in Fault State: Phase A


CT W2.IB Fund.

Current Fundamental Magnitude in Fault State: Phase B


CT W2.IC Fund.

Current Fundamental Magnitude in Fault State: Phase C


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CT W2.IX meas Fund.

Current Fundamental Magnitude in Fault State: IX



Start Position respectively Start Angle of the Current Phasor during Fault Phase:Phase A



Start Position respectively Start Angle of the Current Phasor during Fault Phase:Phase B



Start Position respectively Start Angle of the Current Phasor during Fault Phase:Phase C



Start Position respectively Start Angle of the Current Phasor during Fault Phase: IX


CT W2.IA Fund.

Current Fundamental Magnitude during Post phase: Phase A


CT W2.IB Fund.

Current Fundamental Magnitude during Post phase: Phase B


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CT W2.IC Fund.

Current Fundamental Magnitude during Post phase: Phase C


CT W2.IX meas Fund.

Current Fundamental Magnitude during Post phase: IX



Start Position respectively Start Angle of the Current Phasor during Post phase: Phase A



Start Position respectively Start Angle of the Current Phasor during Post phase: Phase B



Start Position respectively Start Angle of the Current Phasor during Post phase: Phase C



Start Position respectively Start Angle of the Current Phasor during Post phase: IX


States of the Inputs of the Failure Simulator


Ex Start Simulation-I State of the module input:External Start of Fault Simulation (Using the test parameters)


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ExBlo Module Input State: External Blocking [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Process]

Ex ForcePost-I State of the module input:Force Post state. Abort simulation.


Signals of the Failure Simulator (States of the Outputs)

Name Description

Running Signal: Measuring value simulation is running

Direct Commands of the Failure Simulator


Start Simulation

Start Fault Simulation (Using the test parameters)

Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Process]

Stop Simulation Stop Fault Simulation (Using the test parameters)

Inactive, Active

Inactive [Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/Process]

Failure Simulator Values


State Wave generation states: 0=Off, 1=PreFault, 2=Fault, 3=PostFault, 4=InitReset

Off Off, PreFault, FaultSimulation, PostFault, Init Res

[Service/Test Mode (Prot inhibit)/WARNING! Cont?/Sgen/State]

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Technical DataUse Copper conductors only, 75°C (167°F).Conductor size AWG 14 [2.5 mm].

Climatic Environmental ConditionsStorage Temperature: -30°C to +70°C (-22°F to 158°F)Operating Temperature: -20°C to +60°C (-4°F to 140°F)Permissible Humidity at Ann. Average: <75% rel. (on 56d up to 95% rel.)Permissible Installation Altitude: <2,000 m (6,561.67 ft) above sea level

If 4,000 m (13,123.35 ft) altitude applies, a changed classification of the operating and test voltages may be necessary.

Degree of Protection EN 60529

HMI Front Panel with Seal: IP54Rear Side Terminals: IP20

Routine TestInsulation Test Acc. to IEC60255-5: All tests to be carried out against ground and other input and output circuits.Aux. Voltage Supply, Digital Inputs, Current Measuring Inputs, Signal Relay Output Contacts:

2.5 kV (eff.) / 50 Hz

Voltage Measuring Inputs: 3.0 kV (eff.) / 50 HzAll Wire-Bound Communication Interfaces: 1.5 kV DC

HousingHousing B2: Height / Width 183 mm (7.205 in.)/ 212.7 mm (8.374 in.)Housing Depth (Incl. Terminals): 208 mm (8.189 in.)Material, Housing: Aluminum extruded sectionMaterial, Front Panel: Aluminum/Foil frontMounting Position: Horizontal (±45° around the X-axis must be permitted)

Weight: Approx. 4.2 kg (9.259 lb)

Current and Ground Current Measurement

Plug-in Connector with Integrated Short-Circuiter (Conventional Current Inputs)

Phase and Ground Current Inputs:

Nominal Currents: 1 A / 5 AMax. Measuring Range: Up to 40 x In (phase currents)

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Phase and Ground Current Inputs:

Up to 25 x In (ground current standard)Capacity:Overcurrent Proof:

4 x In/continuously30 x In / 10 s100 x In / 1 s250 x In / 10 ms (1 half-wave)

Power Consumption: Phase current inputs At In = 1 A S = 25 mVAAt In = 5 A S = 120 mVA

Ground current inputAt In = 1 A S = 25 mVA At In = 5 A S = 120 mVA

Sensitive Ground Current Inputs:

Nominal Currents: 1 A / 5 A with 50:0.025 core balance CTMax. Measuring Range: Up to 2.5 x InCapacity:Overcurrent Proof:

2 x In/continuously10 x In / 10 s25 x In / 1 s100 x In / 10 ms (1 half-wave)

Power Consumption: At In = 1 A S = 170 mVA At In = 0.1 A S = 1,7 mVA At In = 5 A S = 540 mVAAt In = 0.5 A S = 5,4 mVA

Frequency Range: 50 Hz / 60 Hz ±10%Terminals:

Screws

Screw-type terminals with integrated short-circuiters (contacts)

M4, captive type acc. to VDEW

Connection Cross Sections: 1 x or 2 x 2.5 mm² (2 x AWG 14) with wire end ferrule1 x or 2 x 4.0 mm² (2 x AWG 12) with ring cable sleeve or cable sleeve1 x or 2 x 6 mm² (2 x AWG 10) with ring cable sleeve or cable sleeve

The current measuring board´s terminal blocks may be used as with 2 (double) conductors AWG 10,12,14 otherwise with single conductors only.

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Voltage and Residual Voltage MeasurementNominal Voltages: 60 - 520 V (can be configured)

Max. Measuring Range: 2 x nominal voltage or 800 V

Continuous Loading Capacity: 800 Vac

Power Consumption: at Vn = 100 V S = 22 mVAat Vn = 110 V S = 25 mVAat Vn = 230 V S = 110 mVAat Vn = 400 V S = 330 mVA

Frequency Range: 50 Hz or 60 Hz ±10%

Terminals: Screw-type terminals

Frequency MeasurementNominal Frequencies: 50 Hz / 60 Hz

Voltage SupplyAux. Voltage:

24 - 270 Vdc / 48 - 230 Vac (-20/+10%) ≂Buffer Time in Case of Supply Failure: >= 50 ms at minimal aux. voltage

Interrupted communication is permitted.Max. Permissible Making Current: 18 A peak value for <0.25 ms

12 A peak value for <1 ms

The voltage supply must be protected by a fuse of:• 2,5 A time-lag miniature fuse 5 x 20 mm (approx. 0.2 x 0.8 in.) according to IEC 60127• 3,5 A time-lag miniature fuse 6,3 x 32 mm (approx. 0.25 x 1.25 in.) according to UL 248-14

Power ConsumptionPower Supply Range: Power consumption

in Idle ModeMax. Power Consumption

24 - 270 Vdc: Approx. 8 W Approx.13 W48 - 230 Vac(For Frequencies of 50-60 Hz):

Approx. 8 W / 16 VA Approx.13 W / 21 VA

DisplayDisplay Type: LCD with LED background illuminationResolution - Graphics Display: 128 x 128 pixel

LED - Type: Two colored: red / greenNumber of LEDs, Housing B2: 15

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Front Interface RS232Baud Rates: 115,200 BaudHandshake: RTS and CTSConnection: 9-pole D-Sub plug

Analog OutputsThe following technical data only apply to devices, which are equipped with analog outputs. Please refer to the order code of your device.

The mode of each output can be individually selected between current or voltage output. Shielded cable for the analog outputs is recommended. The terminals of the HF shield should be used, when connecting the shield to ground on both sides of the cable is not possible. On one side of the cable the shield has to be directly connec-ted to ground. In case of the use of unshielded twisted pair cables, the length must not exceed 10 m. All analog outputs have a common potential. Each output has an own common terminal.

Current modeRange:Max. load resistance:

0-20 mA1 kΩ

Voltage modeRange: 0-10 V maximum output current 20 mA

Accuracy 0.5% of the nominal value 20 mA resp. 10 V

Influence of temperature to accuracy <1% (within the range of 0°C to +60°C (+32°F to +140°F)

Test voltage of outputs (one group) against other electrical groups

Test voltage of outputs (one group) against ground

2.5 kV

1.0 kV

Analog InputsThe following technical data only apply to devices, which are equipped with analog inputs. Please refer to the order code of your device.

The mode of each input can be individually selected between current or voltage input. Shielded cable for the analog inputs is recommended. The terminals of the HF shield should be used, when connecting the shield to ground on both sides of the cable is not possible. On one side of the cable the shield has to be directly connec-ted to ground. In case of the use of unshielded twisted pair cables, the length must not exceed 10 m. All analog inputs have a common potential. Each input has an own common terminal.

Current modeRange:Input resistance:

0-20 mA500 Ω

Voltage modeRange:Input resistance:

0-10 V100 kΩ

Accuracy 0.5% of the nominal value 20 mA resp. 10 V

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Current modeRange:Input resistance:

0-20 mA500 Ω

Influence of temperature to accuracy <1% (within the range of 0°C to +60°C (+32°F to +140°F)

Test voltage of inputs (one group) against other electrical groups

Test voltage of inputs (one group) against ground

2.5 kV

1.0 kV

Real Time ClockRunning Reserve of the Real Time Clock:

1 year min.

Digital InputsMax. Input Voltage: 300 Vdc / 259 Vac

Input Current: DC <4 mAAC <16 mA

Reaction Time: <20 ms

drop-out Time:Shorted inputsOpen inputs

<30 ms<90 ms

(Safe State of the Digital Inputs)

Switching Thresholds: Un = 24 Vdc, 48 Vdc, 60 Vdc,110 Vac / dc, 230 Vac / dc

Un = 24 VdcSwitching Threshold 1 ON:Switching Threshold 1 OFF:

Min. 19.2 VdcMax. 9.6 Vdc

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COMDI8DI2DI1 COMDI8DI2DI1

L+L-

L+L-

Open inputs Shorted inputs

IM02602013E ETR-5000

Un = 48 V / 60VdcSwitching Threshold 2 ON:Switching Threshold 2 OFF:

Min. 42.6 VdcMax. 21.3 Vdc

Un = 110 / 120 Vac / dcSwitching Threshold 3 ON:Switching Threshold 3 OFF:

Min. 88.0 Vdc / 88.0 VacMax. 44.0 Vdc / 44.0 Vac

Un = 230 / 240 Vac / dcSwitching Threshold 4 ON:Switching Threshold 4 OFF:

Min. 184 Vdc / 184 VacMax. 92 Vdc / 92 Vac

Terminals: Screw-type terminal

Relay Output ContactsContinuous Current: 5 A ac / dcMax. Make Current: 25 A ac / 25 A dc for 4 s

30 A / 230Vac according to ANSI IEEE Std C37.90-200530 A / 250Vdc according to ANSI IEEE Std C37.90-2005

Max. Breaking Current: 5 A ac up to 240 Vac5 A dc up to 30 V (resistive)0.3 A dc at 250 V (resistive)

Max. Switching Voltage: 250 V ac / 250 VdcSwitching Capacity: 1,250 VAContact Type: Form C or normally open contactTerminals: Screw-type terminals

Supervision Contact (SC)Continuous Current: 5 A ac / dcMax. Switch-on Current: 15 A ac / 15 A dc for 4 s Max. Breaking Current: 5 A ac up to 250 Vac

5 A dc up to 30 Vdc (resistive)0,25 A at 250 Vdc (resistive)

Max. Switching Voltage: 250 V ac / 250 VdcSwitching Capacity: 1,250 VAContact Type: Form CTerminals: Screw-type terminals

Time Synchronization IRIG-B00XNominal input voltage: 5 VConnection: Screw-type terminals (twisted pair)

Zone InterlockingOnly for Zone Interlock Tripping Outputs (Zone Interlock, semiconductor output): 5 Vdc, <2mA for connection to electronic inputs only.

Zone Out:Output voltage (High) 4.75 to 5.25 VdcOutput voltage (Low) 0.0 to +0.5 Vdc

Zone In:Nominal input voltage +5 Vdc

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Zone Out:Max. input voltage +5.5 VdcSwitching threshold ON min. 4.0 VdcSwitching threshold OFF max. 1.5 Vdc

Galvanic isolation 2.5 kV ac (to ground and other IO)Connection: Screw-type terminals (twisted pair)

RS485*Master/Slave: SlaveConnection: 6 screw-clamping terminals RM 3.5 mm (138 MIL)

(terminating resistors internal)

The RS485 interface is realized via terminals. The communication cable has to be shielded. The shielding has to be fixed at the screw that is marked with the ground symbol (rear side of the device).

Fiber Optic*Master/Slave: SlaveConnection: ST-Plug

URTD-Interface*Connection: Versatile Link

*availability depends on device

Boot PhaseAfter switching on the power supply, the protection will be available in approximately 15 seconds. After approximately 190 seconds (depending on the configuration), the boot phase is completed (HMI and Communication initialized).

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StandardsApprovals

• UL-listed file: E217753

Design StandardsGeneric Standard EN 61000-6-2

EN 61000-6-3Product Standard IEC 60255-6

EN 50178 UL 508 (Industrial Control Equipment)CSA C22.2 No. 14-95 (Industrial Control Equipment)ANSI C37.90

High Voltage Tests (IEC 60255-6)High Frequency Interference TestIEC 60255-22-1Class 3

Within one circuit

Circuit to ground

Circuit to circuit

1 kV/2 s

2.5 kV/2 s

2.5 kV/2 s

Insulation Voltage TestIEC 60255-5EN 50178

All circuits to other circuits and exposed conductive parts

Except interfaces

Voltage measuring input

2.5 kV (eff.)/50Hz, 1 min.

1.5 kV DC, 1 min.

3 kV (eff.)/50 Hz, 1 min.

Impulse Voltage TestIEC 60255-5 5 kV/0.5J, 1.2/50 µs

EMC Immunity Tests

Fast Transient Disturbance Immunity Test (Burst)IEC 60255-22-4IEC 61000-4-4Class 4ANSI C37.90.1

Power supply, mains inputs

Other in- and outputs

±4 kV, 2.5 kHz

±2 kV, 5 kHz (coupling network)±4 kV, 2.5 kHz (coupling clamp)

Surge Immunity TestIEC 61000-4-5Class 4

Within one circuit

Circuit to ground

2 kV

4 kV

Class 3 Communication cables to ground 2 kV

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Electrical Discharge Immunity TestIEC 60255-22-2IEC 61000-4-2Class 3

Air discharge

Contact discharge

8 kV

6 kV

Radiated Radio Frequency Electromagnetic Field Immunity TestIEC 61000-4-3ANSI C37.90.2

26 MHz – 80 MHz80 MHz – 1 GHz1 GHz – 3 GHz

10 V/m35 V/m10 V/m

Immunity to Conducted Disturbances Induced by Radio Frequency FieldsIEC 61000-4-6Class 3

10 V

Power Frequency Magnetic Field Immunity TestIEC 61000-4-8Class 4

Continuous

3 sec

30 A/m

300 A/m

EMC Emission Tests

Radio Interference Suppression TestIEC/CISPR11 Limit value class B

Radio Interference Radiation TestIEC/CISPR11 Limit value class B

Environmental TestsClassification:IEC 60068-1 Climatic

Classification

20/060/56

IEC 60721-3-1 Classification of ambient conditions (Storage)

1K5/1B1/1C1L/1S1/1M2but min. -30°C (-22°F)

IEC 60721-3-2 Classification of ambient conditions (Transportation)

2K4/2B1/2C1/2S1/2M2but min. -30°C (-22°F)

IEC 60721-3-3 Classification of ambient conditions (Stationary use at weather protected locations)

3K6/3B1/3C1/3S1/3M2 but min. -20°C (-4°F) /max 60°C (140°F)

Test Ad: ColdIEC 60068-2-1 Temperature

Test duration-20°C (-4°F)16 h

Test Bd: Dry HeatIEC 60068-2-2 Temperature

Relative humidityTest duration

60°C (140°F)<50%72 h

Test Cab: Damp Heat (Steady State)IEC 60068-2-78 Temperature 40°C (104°F)

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Relative humidityTest duration

93%12 h

Test Db: Damp Heat (Cyclic)IEC 60068-2-30 Temperature

Relative humidityCycles (12 + 12-hour)

60°C (140°F)95%2

Mechanical TestsTest Fc: Vibration Response TestIEC 60068-2-6IEC 60255-21-1Class 1

(10 Hz – 59 Hz)Displacement

(59Hz – 150Hz)Acceleration

Number of cycles in each axis

0.0014 in. (0.035 mm)

0.5 gn

1

Test Fc: Vibration Endurance TestIEC 60068-2-6IEC 60255-21-1Class 1

(10 Hz – 150 Hz)Acceleration

Number of cycles in each axis

1.0 gn

20

Test Ea: Shock TestIEC 60068-2-27IEC 60255-21-2Class 1

Shock response test 5 gn, 11 ms, 3 impulses in each direction

Shock resistance test 15 gn, 11 ms, 3 impulses in each direction

Test Eb: Shock Endurance TestIEC 60068-2-29IEC 60255-21-2Class 1

Shock endurance test 10 gn, 16 ms, 1,000 impulses in each direction

Test Fe: Earthquake TestIEC 60068-3-3KTA 3503IEC 60255-21-3

Single axis earthquake vibration test 3 – 7 Hz: Horizontal 0.394 in. (10 mm), 1 cycle each axis

Class 2 7 – 35 Hz Horizontal: 2 gn, 1 cycle each axis

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Specifications

Specifications of the Real Time Clock

Resolution: 1 msTolerance: <1 minute / month (+20°C [68°F])

<±1ms if synchronized via IRIG-B

Time Synchronization TolerancesThe different protocols for time synchronization vary in their accuracy:

Used Protocol Time drift over one month Deviation to time generatorWithout time synchronization <1 min (+20°C) Time driftsIRIG-B Dependent on the time drift of

the time generator<±1 ms

SNTP Dependent on the time drift of the time generator

<±1 ms

Modbus TCP Dependent on the time drift of the time generator

Dependent on the network load

Modbus RTU Dependent on the time drift of the time generator

<±1 ms

Specifications of the Measured Value Acquisition

Phase and Ground Current Measuring

Frequency Range: 50 Hz / 60 Hz ± 10% Accuracy: Class 0.5Amplitude Error if I < In: ±0.5% of the rated current *3)

Amplitude Error if I > In: ±0.5% of the measured current *3)

Amplitude Error if I > 2 In: ±1.0% of the measured current *3)

Harmonics: Up to 20% 3rd harmonic ±2%Up to 20% 5th harmonic ±2%

Frequency Influence: <±2% / Hz in the range of ±5 Hz of the configured nominal frequencyTemperature Influence: <±1% within the range of 0°C to +60°C (+32°F to +140°F)

*3) For earth current sensitive the precision does not depend on the nominal value but is referenced to 100 mA (with In =1 A) respectively. 500 mA (with In = 5 A)

Phase-to-ground and Residual Voltage Measurement

Frequency Range: 50 Hz / 60 Hz ± 10%

Accuracy for measured values: Class 0.5Amplitude error for V<Vn: ±0.5% of rated voltage or ±0.5 V Amplitude error for V>Vn: ±0.5% of measured voltage or ±0.5 V

Accuracy for calculated values: Class 1.0Amplitude error for V<Vn: ±1.0% of rated voltage or ±1 V Amplitude error for V>Vn: ±1.0% of calculated voltage or ±1 V

Harmonics: Up to 20% 3rd harmonic ±1%Up to 20% 5th harmonic ±1%

Frequency influence: <±2% / Hz in the range of ±5 Hz of the configured nominal frequencyTemperature influence: <±1% within the range of 0°C up to +60°C

IM02602013E ETR-5000

Frequency measurement

Nominal frequency: 50 Hz / 60 HzPrecision: ±0.05% of fn within the range of 40-70 Hz at voltages >50 VVoltage dependency: frequency acquisition from 0.15 x Vn

Energy measurement*

Energy counter error 3% of measured energy or 3% Sn*1h

Power Measurement*

VA, W, VAr: <±3% of the measured value or 0.1% Sn

Power Factor Measurement*

PF: ±0.01 of measured power factor or 1°I > 30% In and S >2% Sn

*)Tolerance at 0.8 … 1.2 x Vn (with Vn=100V) , |PF|>0.5, symmetrically feeded Sn=1.73 * VT rating * CT rating

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Protection Elements AccuracyThe tripping delay relates to the time between alarm and trip. The accuracy of the operating time relates to the time between fault entry and the time when the protection element is picked-up.

Reference conditions for all Protection Elements: sine wave, at rated frequency, total harmonic distortion < 1%

Overcurrent Protection Elements:50P[x] / 67P[x]

Accuracy *2)

Pickup ±1.5% of the setting value or 1% In.Dropout Ratio 97% or 0.5% Int DEFT

±1% or ±10 msOperating TimeAt testing current >= 2 times pickup value

<35 ms

Disengaging Time <45 ms

Overcurrent Protection Elements:51P[x] / 67P[x]

Accuracy *2)

Pickup ±1.5% of the setting value or 1% In.Dropout Ratio 97% or 0.5% x InOperating TimeAt testing current >= 2 times pickup value

<35 ms

Disengaging Time <45 mst-Multiplier ±5% (according to selected curve)Reset Mode ±5% (according to selected curve)t-reset (Reset Mode = t-delay) ±1% or ±10 ms

*2) For directional elements, accuracy of MTA: ±3° at I >20% In.

Ground Current Elements:50X[x] / 50R[x] / 67X[x] / 67R[x]

Accuracy *2) *3)

Pickup (measured ground current)

Pickup (calculated ground current)

±1.5% of the setting value or 1% In

±2.0% of the setting value or 1.5% InDropout Ratio 97% or 0.5% Int DEFT

±1% or ±10 msOperating Time

Starting from IE higher than 1.1 x IE>

<35 ms

Disengaging Time <45 mst-reset (Reset Mode = t-delay) ±1% or ±10 ms

Ground Current Elements:51X[x] / 51R[x] / 67X[x] / 67R[x]

Accuracy *2) *3)

Pickup (measured ground current)Pickup (calculated ground current)

±1.5% of the setting value or 1% In±2.0% of the setting value or 1.5% In

Dropout Ratio 97% or 0.5% InOperating TimeStarting from IE higher than 1.1 x IE>

<35 ms

Disengaging Time <45 mst-Multiplier ±5% (according to selected curve)Reset Mode ±5% (according to selected curve)t-reset (Reset Mode = t-delay) ±1% or ±10 ms

*2) For directional elements, accuracy of MTA: ±3° at I >20% In.*3) For earth current sensitive the precision does not depend on the nominal value but is referenced to 100 mA (with In =1 A) respectively 500 mA (with In = 5 A)

Directional Sensitivity:67P[x]

Value Release Level Blocking Level

I V (3-phases) IV

10 mA0.35 V

5 mA0.25 V

IM02602013E ETR-5000

Directional Sensitivity:67X[x], 67R[x]

Value Release Level Blocking Level

IX 3V0 IXIX (sensitive)3V0

10 mA 1 mA0.35 V

5 mA0.5 mA0.25 V

IR 3V0 IR3V0

18 mA1 V

11 mA0.8 V

IR IPol IRIXIX (sensitive)

18 mA10 mA 1 mA

11 mA 5 mA0.5 mA

IX Neg, IR Neg I2V2

10 mA0.35 V

5 mA0.25 V

Phase Differential Protection: 87

Accuracy

Id > ±3% of the setting value or 2% In.Operating timeId > 2 x pickup (step from zero to 200% pickup of 87-Char)

<40 ms

Typically trip time 30 msShortest trip time 18 ms

Unrestrained Phase Differential Protection:87H

Accuracy

Id >> ±3% of the setting value or 2% In.Operating timeId > 1.1 x pickup: <30 msTypically trip time 19 msShortest trip time 13 ms

Ground Differential Protection:87G

Accuracy

IdG > ±3% of the setting value or 2% In.Operating timeIdG > 2 x pickup (step from zero to 200% pickup of 87G-Char)

<40 ms

Typically trip time 30 msShortest trip time 18 ms

Unrestrained Ground Differential Protection: 87GH

Accuracy

IdG >> ±3% of the setting value or 2% In.Operating timeIdG > 1.1 x pickup: <30 msTypically trip time 19 msShortest trip time 13 ms

Temperature Protection Elements: 49/38 [x]RTD Trip w /URTD

Accuracy

Trip Threshold ±1°C (1.8°F)Alarm Threshold ±1°C (1.8°F)t-delay Alarm DEFT

±1% or ±10 msReset Hysteresis -2°C (-3.6°F) of threshold

±1°C (1.8°F)

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ETR-5000 IM02602013E

Thermal Replica: ThR

Accuracy

Ib ±2% of the setting value or 1% InPickup ThR ±1.5 % of the setting value

Inrush Supervision:IH2

Accuracy

IH2/IH1 ±1% InDropout Ratio 5% IH2 or 1% InOperating Time <30 ms *1)

*1) Inrush supervision is possible, if the fundamental Harmonic (IH1) > 0.1 In and 2nd Harmonic (IH2) > 0.01 In.

Current unbalance: 46[x]

Accuracy *1)

Threshold ±2% of the setting value or 1% In%(I2/I1) ±1%t DEFT

±1% or ±10 msOperating Time <60 msDisengaging Time <40 ms

*1) Negative-sequence current I2 must be ≥ 0.01 x In, I1 must be ≥ 0.1 x In.

Undervoltage and Overvoltage(Phase and Auxiliary)27M[x] / 59M[x] / 27A[x] / 59A[x]

Accuracy

Pickup ±1.5% of the setting value or 1% VnDropout Ratio 97% or 0.5% Vn for 59[x]

103% or 0.5% Vn for 27[x]t DEFT

±1% or ±10 msOperating Time

Starting from V higher than 1.1 x pickup value for 59[x] or V lower than 0.9 x pickup value for 27[x]

<35 ms


Volts per Hertz:24[x]

Accuracy

Pickup ±1% *1)

(fn ±10% / 0.1-1.5 Vn (with Vn=120V) / 100-150%)t DEFT

±1% or ±10 mst-Multiplier ±5% ±10 ms

( Volts/Hertz (%) higher than 1.1 x Pickup)INV AINV BINV C

t-reset ±1% or ±10 msINV AINV BINV C

Operating TimeStarting from Volts/Hertz (%) higher than 1.1 x Pickup

<60 ms (at fn) or < 4 cycles

Disengaging Time <85 ms (at fn) or < 5 cycles

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*1) The V/Hz function provides reliable measurements of V/Hz for a frequency range of fn ±10%, if voltage (rms) is greater than 15% Vn and < 800V. U/f < 48 V/Hz.

Voltage unbalance:47[x]

Accuracy *1)

Threshold ±2% of the setting value or 1% Vn%(V2/V1) ±1%t DEFT

±1% or ±10 msOperating Time <60 msDisengaging Time <40 ms

*1) Negative-sequence voltage V2 must be ≥ 0.01 x Vn, V1 must be ≥ 0.1 x Vn.

Over Frequency Protection:81O[x]

Accuracy

Threshold ±10 mHz at fnDropout ratio 99.95% or 0.05% fnt ±1% or ±10 msOperating time

Starting from f higher than f> + 0.02 Hz

40-50Hz <60 ms50-70Hz <50 ms

Disengaging time 40-50Hz <85 ms50-70Hz <75 ms

Under Frequency Protection:81U[x]

Accuracy

Threshold ±10 mHz at fnDropout ratio 100.05% or 0.05% fnt ±1% or ±10 msOperating time

Starting from f lower than f< - 0.02 Hz

40-50Hz <60 ms50-70Hz <50 ms

Disengaging time 40-50Hz <85 ms50-70Hz <75 ms

V Block f ±1.5% of the setting value or 1% VnDropout ratio 103% or 0.5% Vn

Rate of Change of Frequency:df/dt

Accuracy

Threshold ±100 mHz per Secondt ±1% or ±10 msOperating time <40 ms Disengaging time <40 ms

Rate of Change of Frequency:DF/DT

Accuracy

DF ±20 mHz at fnDT ±1% or ±10 msOperating time <40 ms Disengaging time <40 ms

Vector surge:78V

Accuracy

Threshold ±0.5° [1-30°] at Vn and fnOperating time <40 ms

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ETR-5000 IM02602013E

Power Factor:PF-55D/PF-55A

Accuracy

Trigger-PF ± 0.01 (absolute) or ±1°Reset-PF ± 0.01 (absolute) or ±1°t-trip ±1% or ±10 msT-Pickup Comp ±1% or ±10 msT-Reset Comp ±1% or ±10 msOperating time *1)

55D <130 ms 55A <200 ms

*1) The calculation of the Power Factor will be available 300 ms after the required measuring values (I > 2.5% In and V > 20% Vn) have energized the measuring inputs.

PQ-protection:32[x]/32V[x]

Accuracy

Threshold ±3% or ±1.5% Van at |PF|>0.5 and Vn=100V, symmetrically fed

Dropout Ratio 97% or 0.7 VA for Over-protection103% or 0.7 VA for Under-protection

t ±1% or ±10 msOperating time 75 msDisengaging time 75 ms

Switch onto Fault:SOTF

Accuracy

Operating time <35 msI< ±1.5% of the setting value or1% Int-enable ±1% or ±10 ms

Cold Load Pickup:CLPU

Accuracy

Threshold ±1.5% of the setting value or1% InOperating time <35 msI< ±1.5% of the setting value or1% Int-Load OFF ±1% or ±10 mst-Max Block ±1% or ±10 msSettle Time ±1% or ±10 ms

Breaker Failure Protection:50BF

Accuracy

I-BF> ±1.5% of the setting value or1% Int-BF ±1% or ±10 msOperating TimeStarting from I Higher than 1.3 x I-BF>

<40 ms


Trip Circuit Monitoring:TCM

Accuracy

t-TCM ±1% or ±10 ms

Current Transformer Supervision:CTS

Accuracy

ΔI ±2% of the setting value or 1.5% InDropout Ratio 94%Pickup delay ±1% or ± 10 ms

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IM02602013E ETR-5000

Loss of Potential:LOP

Accuracy

t-Pickup ±1% or ±10 ms

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ETR-5000 IM02602013E

AppendixThe following terms, abbreviations, and acronyms are used in this manual. Please refer to this section for their meanings / definitions.

A Ampere(s), Amp(s)AC Alternating currentA/D Analog to digitalAck. AcknowledgeAMP Ampere(s), Amp(s)AND Logical gate (The output becomes true if all Input signals are true.)ANG AngleANSI American National Standards InstituteAR Automatic reclosureAUX AuxiliaryAVG, avg AverageAWG American wire gaugeBF Breaker failureBFI Breaker failure initiateBKR, bkr BreakerBlo Blocking(s)°C Degrees Celsiuscalc CalculatedBkr. BreakerCD Compact diskChar Curve shapeCHK CheckCHNL ChannelCmd. CommandCMND CommandCMN Common inputCOM Common inputComm CommunicationCOMP Compensated, comparisonCONN ConnectionCONT Continuous, contactCPU Central processing unitCr. Counter(s)CRT, CRNT CurrentCSA Canadian Standards AssociationCT Control transformerCtrl. ControlCTS Current transformer supervisiond DayD/A Digital to analogD-Sub-Plug Communication interfaceDC, dc Direct currentDEFT Definite time characteristic (Tripping time does not depend on the height of the current.)DFLT DefaultDGNST DiagnosticsDI Digital InputDiagn. DiagnosisDiagn Cr Diagnosis counter(s)

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IM02602013E ETR-5000

DIFF DifferentialDIN Deutsche Industrie NormDIR, dir DirectionalDMD DemandDPO DropoutDSP Digital signal processordt Rate of changeEINV Extremely inverse tripping characteristicEMC Electromagnetic compatibilityEN Europäische Normerr. / Err. ErrorEVTcon Parameter determines if the residual voltage is measured or calculated.Ex ExternalExBlo External blocking(s)ExP External protectionEXT Extension, external°F Degrees FahrenheitF FieldFc Function (Enable or disable functionality = allow or disallow.)FIFO First in first outFIFO Principal First in first outFLA Full load currentFO Fiber opticFTP File transfer protocolfund Fundamental (ground wave)FWD ForwardG, g Generatorgn Acceleration of the earth in vertical direction (9.81 m/s2)GND GroundGPS Global positioning systemh HourHARM Harmonic / harmonicsHMI Human machine interface (Front of the protective relay)HTL Manufacturer internal product designationHTTP Hyper text transfer protocolHz HertzI Fault currentI CurrentI0 Zero current (symmetrical components), Zero sequence currentI1 Positive sequence current (symmetrical components)I2 Negative sequence current (symmetrical components)IA Phase A currentIAB Phase A minus B currentIB Phase B currentIBC Phase B minus C currentI-BF Tripping thresholdIC Phase C currentIC's Manufacturer internal product designationICA Phase C minus A currentID IdentificationIEC International Electrotechnical CommissionIED Intelligent electronic deviceIEEE Institute of Electrical and Electronics Engineers

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ETR-5000 IM02602013E

IG Ground current (not residual)IG Fault currentIgd Differential ground currentIGnom Nominal ground currentIH1 Fundamental harmonic (fundamental harmonic)IH2 2nd harmonicIINV Inversein. Inchincl. Include, includingInfo. InformationInterl. InterlockingINV Inverse characteristic (The tripping time will be calculated depending on the height of the

current)I/O Input / outputIOC Instantaneous overcurrentIOV Instantaneous overvoltageIR Calculated ground currentIRIG Input for time synchronization (Clock), Inter-range instrumentation groupISO International Standards OrganizationIT Thermal CharacteristicI2T Thermal CharacteristicI4T Thermal CharacteristicIUV Instantaneous undervoltageIX 4th measuring input of the current measuring assembly group (either ground or neutral current)J JoulekA Kiloamperekg KilogramkHz KilohertzkV Kilovolt(s)kVdc or kVDC Kilovolt(s) direct currentL1 Phase AL2 Phase BL3 Phase Cl/ln Ratio of current to nominal current.LED Light emitting diodelb-in Pound-inchLINV Long time inverse tripping characteristicLV Low voltagem MeterM MachinemA Milliampere(s), Milliamp(s)MAG MagnitudeMAN, man. Manual / manuallyMAX, max. Maximummeas MeasuredMIN, min. Minimummin. MinuteMINV Moderately Inverse Tripping CharacteristicMK Manufacturer Internal Product Designation Codemm MillimeterMMU Memory mapping unitMRT Minimum response timems Milli-second(s)

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IM02602013E ETR-5000

MTA Maximum torque angleMTR MotorMV Medium voltagemVA Milli volt amperes (Power)MVA Mega volt-ampere (total 3-phase)MVA A Mega volt-ampere (phase A)MVA B Mega volt-ampere (phase B)MVA C Mega volt-ampere (phase C)MVAR Mega Var (total 3-phase)MVAR A Mega Var (phase A)MVAR B Mega Var (phase B)MVAR C Mega Var (phase C)MVARH Mega Var-HourMW Megawatt(s) (total 3-phase)MW A Megawatt(s) (phase A)MW B Megawatt(s) (phase B)MW C Megawatt(s) (phase C)MWH Megawatt-Hour(s)N NeutralN/A, n/a Not applicableN.C. Not connectedNEG NegativeNINV Normal inverse tripping characteristicNm Newton-meterNo NumberN.O. Normal open (Contact)NOM, Nom. NominalNT Manufacturer internal product designation codeO OverOC, O/C OvercurrentO/P, Op, OUT OutputOV OvervoltageOVERFREQ over-frequencyOVLD OverloadP PhasePara. ParameterPC Personal computerPCB Printed circuit boardPE Protected EarthPF Power factor (total 3-phase)PF A Power factor (phase A)PF B Power factor (phase B)PF C Power factor (phase C)Ph PhasePOS PositivePRESS PressurePRI, pri PrimaryPROT, Prot Protection Module (Master Module), protectionPS1 Parameter set 1PS2 Parameter set 2PS3 Parameter set 3PS4 Parameter set 4PSet Parameter set

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PSS Parameter set switch (Switching from one parameter set to another)pu Per unitPWM Pulse width modulatedPWR PowerR Resetrec. RecordREF Referencerel RelativeREM Remoteres ResetResetFct Reset functionREV ReverseRevData Review dataRMS Root mean squareRO Relay OutputRO1 1st Relay OutputRO2 2nd Relay OutputRO3 3rd Relay OutputRst ResetRTD Resistance-temperature detectorRX (Rx) Receive, receivers SecondS SensitiveSAT CT saturationSC Supervision contactSca SCADASCADA Communication module, supervisory control and data acquistionsec Second(s)SEC, sec SecondarySENS SensitiveSEQ SequenceSig. SignalSNTP Simple network time protocolSRC SourceStartFct Start functionSTATS StatisticsSum SummationSUPERV SupervisionSW SoftwareSYNC Sync-check, Sync-checkSYNCHCHK Sync-check, Sync-checkSys. Systemt or t. Timet Tripping delayT Time, transformerTcmd Trip commandTCP Transmission control protocolTCP/IP Communication protocolTEMP, temp TemperatureTHD Total harmonic distortionTI Manufacturer internal product designation codeTOC Time overcurrentTOV Time overvoltage

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IM02602013E ETR-5000

TRANS TransientTripCmd Trip commandTX (Tx) Transmit, transmittertxt TextUC UndercurrentUL Underwriters LaboratoriesUMZ DEFT (definite time tripping characteristic)URTD Universal resistance-temperature detectorUSB Universal serial busV VoltsV0 Zero sequence voltageV1 Positive sequence voltageV2 Negative sequence voltageVA Phase A voltageVAB Phase A to B voltageVac / V ac Volts alternating currentVAG Phase A to ground voltageVARH Var-hour voltageVB Phase B voltageVBA Phase B to A voltageVBG Phase B to ground voltageVC Phase C voltageVCA Phase C to A voltageVCG Phase C to ground voltageVdc / V dc Volts direct currentVDE Verband Deutscher ElektrotechnikVDEW Verband der ElektrizitätswirtschaftVE Residual voltageV/Hz Volts per HertzVINV Very inverse tripping characteristicVT Voltage transformerVTS Voltage transformer supervisionW Watt(s)WDC Watch dog contact (supervision contact)WDG WindingWH Watthourwww World wide webX ReactanceXCT 4th current measuring input (ground or neutral current)XInv Inverse characteristicZ Impedance, zone

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ETR-5000 IM02602013E

Instantaneous Current Curves (Phase)Explanation:

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t = Tripping delay

I = Fault current


t [s]

PickupI

1 100.01

0.1

1

10

100

1 100.01

0.1

1

10

100

tt

4040

300 s300 s

0.0 s0.0 s

0.010.01PickupI

DEFT

IM02602013E ETR-5000

Time Current Curves (PHASE)The following characteristics are available:


Explanation:

698 www.eaton.com

t = Tripping delay

t-multiplier = Time multiplier/tripping characteristic factor. The setting range depends on the selected tripping curve.I = Fault current

Pickup = If the pickup value is exceeded, the module/element starts to time out to trip.

ETR-5000 IM02602013E

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t-multiplier

x * Pickup (Multiples of Pickup)

TripReset

t = 0.14 *t-multiplier [s]

Pickup -1I( )2 t = 0.14 *t-multiplier [s]

Pickup -1I( )0.02

t [s]

Notice!Various Reset Modes are available. Resetting via characteristic, delayed, and instantaneous.

IEC NINV

IM02602013E ETR-5000

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t [s]t-multiplier


Pickup -1I( )t = 13.5 *t-multiplier [s]

Pickup -1I( )2

TripReset



IEC VINV

ETR-5000 IM02602013E

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t [s] t-multiplier

t = 120 *t-multiplier [s]

Pickup -1I( )2


Pickup -1I( )

TripReset



IEC LINV

IM02602013E ETR-5000

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t [s] t-multiplier


Pickup -1I( )2t = 80 *t-multiplier [s]

Pickup -1I( )2

TripReset



IEC EINV

ETR-5000 IM02602013E

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t [s] t-multiplier


Pickup -1I( )2 t = 0.0515 *t-multiplier [s]

Pickup -1I( )0.02 + 0.1140( )

TripReset



ANSI MINV

IM02602013E ETR-5000

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t [s] t-multiplier

TripReset



Pickup -1I( )2 + 0.491( )t = 21.6 *t-multiplier [s]

Pickup -1I( )2


ANSI VINV

ETR-5000 IM02602013E

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t [s] t-multiplier


Pickup -1I( )2

TripReset



Pickup -1I( )2 + 0.1217( )


ANSI EINV

IM02602013E ETR-5000

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t [s] t-multiplier

x * In (Multiples of the Nominal Current)

TripReset

t = 5*3 *t-multiplier [s]2

InI( )

0t = 5*1 *t-multiplier [s]

InI( )

0

2

Notice!Various Reset Modes are available . Resetting via characteristic, delayed, and instantaneous .

Therm Flat

t = 45*t-multiplier [s]

0.01 0.1 1 10 1000.01

0.1

1

10

100

1 103×

1 104×

TM[s]=

10

5

2

1.0

0.5

0.05

ETR-5000 IM02602013E

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t [s] t-multiplier


TripReset


InI( )

0


IT


InI( )

1

0.01 0.1 1 10 1000.01

0.1

1

10

100

1 103×

1 104×

TM[s]=

10

5

2

1.0

0.5

0.05

IM02602013E ETR-5000

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0.01 0.1 1 10 1000.01

0.1

1

10

100

1 103×

1 104×

TM[s]=

10

5

2

1.0

0.50.05

t [s] t-multiplier


TripReset


InI( )

0


I2T

t = 5*3 *t-multiplier [s]

InI( )

2

2

ETR-5000 IM02602013E

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t [s] t-multiplier


TripReset


InI( )

0


I4T


InI( )

4

4

0.01 0.1 1 10 1000.01

0.1

1

10

100

1 103×

1 104×

TM[s]=

10

52

1.00.5

0.05

IM02602013E ETR-5000

Instantaneous Current Curves (Ground Current Calculated)The following characteristics is available:


Explanation:

The ground current can be measured either directly via a zero sequence transformer or detected by a residual connection. The ground current can alternatively be calculated from the phase currents; but this is only possible if the current transformers are Wye-connected.

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t = Tripping delay

IG = Fault current


t [s]

1 100.01

0.1

1

10

100

1 100.01

0.1

1

10

100

I/I>

tt

4020

300 s300 s

0.0 s0.0 s

0.010.01

PickupIR calc

PickupIR calc

DEFT

ETR-5000 IM02602013E

Instantaneous Current Curves (Ground Current Measured)The following characteristics is available:


Explanation:


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t = Tripping delay

IX = Fault current


t [s]

1 100.01

0.1

1

10

100

1 100.01

0.1

1

10

100

I/I>

tt

4020

300 s300 s

0.0 s0.0 s

0.010.01

PickupIX

PickupIX

DEFT

IM02602013E ETR-5000

Time Current Curves (Ground Current)The following characteristics are available:


Explanation:


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t = Tripping delay

t-multiplier = Time multiplier/tripping characteristic factor. The setting range depends on the selected tripping curve.IG = Fault current

Pickup = If the pickup value is exceeded, the module/element starts to time out to trip.

ETR-5000 IM02602013E

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t-multiplier


Pickup -1IG( )0.02

TripReset


Pickup -1IG( )2


t [s]


IEC NINV

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t [s]t-multiplier

TripReset



Pickup -1IG( )2


Pickup -1IG( )


IEC VINV

ETR-5000 IM02602013E

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t [s] t-multiplier


TripReset


Pickup -1IG( )t = 120 *t-multiplier [s]

-1IG( )2

Pickup


IEC LINV

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t [s] t-multiplier


TripReset


Pickup -1IG( )2 t = 80 *t-multiplier [s]

Pickup -1IG( )2


IEC EINV

ETR-5000 IM02602013E

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t [s] t-multiplier



Pickup -1IG( )0.02 + 0.1140( )t = 4.85 *t-multiplier [s]

-1IG( )2

Pickup

TripReset


ANSI MINV

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t [s] t-multiplier


TripReset

t = 21.6 *t-multiplier [s]-1IG( )

2

Pickup


Pickup -1IG( )2 + 0.491( )


ANSI VINV

ETR-5000 IM02602013E

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t [s] t-multiplier


TripReset


Pickup -1IG( )2 + 0.1217( )t = 29.1 *t-multiplier [s]

-1IG( )2

Pickup


ANSI EINV

IM02602013E ETR-5000

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t [s] t-multiplier

TripReset


IG( )0

IGnom



Therm Flat


IGnomIG( )

0


0.01 0.1 1 10 1000.01

0.1

1

10

100

1 103×

1 104×

TM[s]=

10

5

2

1.0

0.5

0.05

ETR-5000 IM02602013E

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t [s] t-multiplier

TripReset



IG( )0

IGnom


IT


IGnomIG( )

1

1

0.01 0.1 1 10 1000.01

0.1

1

10

100

1 103×

1 10×

TM[s]=

510

5 2

2

1.0

0.5

0.05

4

IM02602013E ETR-5000

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t [s] t-multiplier

TripReset



IG( )0

IGnom


I2T


IGnomIG( )

2

2

0.01 0.1 1 10 1000.01

0.1

1

10

100

1 103×

1 104×

TM[s]=

10

5

2

1.00.50.05

ETR-5000 IM02602013E

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t [s] t-multiplier

TripReset


t =


I4T


IGnomIG( )

4

45*1 *t-multiplier [s]2

IGnomIG( )

0

0.01 0.1 1 10 1000.01

0.1

1

10

100

1 103×

1 104×

TM[s]=

10

5

2

1.0

0.50.05

IM02602013E ETR-5000

Assignment ListThe »ASSIGNMENT LIST« below summarizes all module outputs (signals) and inputs (e.g.: states of the assignments).

Name Description

-.- No assignmentProt.Available Signal: Protection is available.Prot.Active Signal: ActiveProt.ExBlo Signal: External BlockingProt.Pickup Phase A Signal: General Pickup Phase AProt.Pickup Phase B Signal: General Pickup Phase BProt.Pickup Phase C Signal: General Pickup Phase CProt.Pickup IX or IR Signal: General Pickup - Ground FaultProt.Pickup Signal: General PickupProt.Trip Phase A Signal: General Trip Phase AProt.Trip Phase B Signal: General Trip Phase BProt.Trip Phase C Signal: General Trip Phase CProt.Trip IX or IR Signal: General Trip Ground FaultProt.Trip Signal: General TripProt.Res Fault a Mains No Signal: Resetting of fault number and number of grid faults.Prot.I dir fwd Signal: Phase current failure forward directionProt.I dir rev Signal: Phase current failure reverse directionProt.I dir n poss Signal: Phase fault - missing reference voltageProt.IR dir fwd Signal: IR Ground fault (calculated) forwardProt.IR dir rev Signal: IR Ground fault (calculated) reverse directionProt.IR dir n poss Signal: IR Ground fault (calculated) direction detection not possibleProt.IX dir fwd Signal: IX Ground fault (measured) forwardProt.IX dir rev Signal: IX Ground fault (measured) reverse directionProt.IX dir n poss Signal: IX Ground fault (measured) direction detection not possibleProt.ExBlo1-I Module Input State: External Blocking1Prot.ExBlo2-I Module Input State: External Blocking2Ctrl.Local Switching Authority: LocalCtrl.Remote Switching Authority: RemoteBkr[1].SI SingleContactInd Signal: The Position of the Switchgear is detected by one auxiliary


Bkr[1].Pos not CLOSE Signal: Pos not CLOSEBkr[1].Pos CLOSE Signal: Breaker is in CLOSE-PositionBkr[1].Pos OPEN Signal: Breaker is in OPEN-PositionBkr[1].Pos Indeterm Signal: Breaker is in Indeterminate Position

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Name Description

Bkr[1].Pos Disturb Signal: Breaker Disturbed - Undefined Breaker Position. The feed-back signals (Position Indicators) contradict themselves. After expiring of a supervision timer this signal becomes true.












Bkr[1].CLOSE Cmd manual Signal: CLOSE Cmd manualBkr[1].OPEN Cmd manual Signal: OPEN Cmd manualBkr[1].Sync CLOSE request Signal: Synchronous CLOSE requestBkr[1].CinBkr-52a-I Module Input State: Feed-back signal of the Bkr (52a)Bkr[1].CinBkr-52b-I Module Input State: Feed-back signal of the Bkr. (52b)Bkr[1].Ready-I Module Input State: Breaker ReadyBkr[1].Sys-in-Sync-I State of the module input: This signals has to become true within

the synchronization time. If not, switching is unsuccessful.Bkr[1].Ack TripCmd-I State of the module input: Acknowledgment Signal (only for

automatic acknowledgment). Module input signalBkr[1].Interl CLOSE1-I State of the module input: Interlocking of the CLOSE command

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Name Description

Bkr[1].Interl CLOSE2-I State of the module input: Interlocking of the CLOSE commandBkr[1].Interl CLOSE3-I State of the module input: Interlocking of the CLOSE commandBkr[1].Interl OPEN1-I State of the module input: Interlocking of the OPEN commandBkr[1].Interl OPEN2-I State of the module input: Interlocking of the OPEN commandBkr[1].Interl OPEN3-I State of the module input: Interlocking of the OPEN commandBkr[1].SC CLOSE-I State of the module input: Switching CLOSE Command, e.g. the

state of the logic or the state of the digital inputBkr[1].SC OPEN-I State of the module input: Switching OPEN Command, e.g. the

state of the logic or the state of the digital inputBkr[1].Operations Alarm Signal: Service Alarm, too many OperationsBkr[1].Isum Intr trip: IA Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: IABkr[1].Isum Intr trip: IB Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: IBBkr[1].Isum Intr trip: IC Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: ICBkr[1].Isum Intr trip Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded in at least one phase.Bkr[1].Res TripCmdCr Signal: Resetting of the Counter: total number of trip commandsBkr[1].Res Isum trip Signal: Reset summation of the tripping currentsBkr[1].WearLevel Alarm Signal: Breaker Wear curve AlarmBkr[1].WearLevel Lockout Signal: Breaker Wear Curve Lockout LevelBkr[1].Res Bwear Curve Signal: Reset of the Breaker Wear maintenance curve.Bkr[1].Isum Intr ph Alm Signal: Alarm, the per hour Sum (Limit) of interrupting currents has

been exceeded.Bkr[1].Res Isum Intr ph Alm Signal: Reset of the Alarm, "the per hour Sum (Limit) of

interrupting currents has been exceeded".Bkr[2].SI SingleContactInd Signal: The Position of the Switchgear is detected by one auxiliary






unsuccessful. Switchgear in disturbed position.

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Name Description

Bkr[2].CES Fail TripCmd Command Execution Supervision: Command execution failed because trip command is pending.

Bkr[2].CES SwitchgDir Command Execution Supervision respectivly Switching Direction Control: This signal becomes true, if a switch command is issued even though the switchgear is already in the requested position. Example: A switchgear that is already OPEN should be switched OPEN again (doubly). The same applies to CLOSE commands.







Bkr[2].CLOSE Cmd manual Signal: CLOSE Cmd manualBkr[2].OPEN Cmd manual Signal: OPEN Cmd manualBkr[2].Sync CLOSE request Signal: Synchronous CLOSE requestBkr[2].CinBkr-52a-I Module Input State: Feed-back signal of the Bkr (52a)Bkr[2].CinBkr-52b-I Module Input State: Feed-back signal of the Bkr. (52b)Bkr[2].Ready-I Module Input State: Breaker ReadyBkr[2].Sys-in-Sync-I State of the module input: This signals has to become true within

the synchronization time. If not, switching is unsuccessful.Bkr[2].Ack TripCmd-I State of the module input: Acknowledgment Signal (only for

automatic acknowledgment). Module input signalBkr[2].Interl CLOSE1-I State of the module input: Interlocking of the CLOSE commandBkr[2].Interl CLOSE2-I State of the module input: Interlocking of the CLOSE commandBkr[2].Interl CLOSE3-I State of the module input: Interlocking of the CLOSE commandBkr[2].Interl OPEN1-I State of the module input: Interlocking of the OPEN commandBkr[2].Interl OPEN2-I State of the module input: Interlocking of the OPEN commandBkr[2].Interl OPEN3-I State of the module input: Interlocking of the OPEN commandBkr[2].SC CLOSE-I State of the module input: Switching CLOSE Command, e.g. the

state of the logic or the state of the digital inputBkr[2].SC OPEN-I State of the module input: Switching OPEN Command, e.g. the

state of the logic or the state of the digital input

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Name Description

Bkr[2].Operations Alarm Signal: Service Alarm, too many OperationsBkr[2].Isum Intr trip: IA Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: IABkr[2].Isum Intr trip: IB Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: IBBkr[2].Isum Intr trip: IC Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded: ICBkr[2].Isum Intr trip Signal: Maximum permissible Summation of the interrupting

(tripping) currents exceeded in at least one phase.Bkr[2].Res TripCmdCr Signal: Resetting of the Counter: total number of trip commandsBkr[2].Res Isum trip Signal: Reset summation of the tripping currentsBkr[2].WearLevel Alarm Signal: Breaker Wear curve AlarmBkr[2].WearLevel Lockout Signal: Breaker Wear Curve Lockout LevelBkr[2].Res Bwear Curve Signal: Reset of the Breaker Wear maintenance curve.Bkr[2].Isum Intr ph Alm Signal: Alarm, the per hour Sum (Limit) of interrupting currents has

been exceeded.Bkr[2].Res Isum Intr ph Alm Signal: Reset of the Alarm, "the per hour Sum (Limit) of

interrupting currents has been exceeded".87.Active Signal: Active87.ExBlo Signal: External Blocking87.Blo TripCmd Signal: Trip Command blocked87.ExBlo TripCmd Signal: External Blocking of the Trip Command87.Alarm A Signal: Pickup System Phase A87.Alarm B Signal: Pickup System Phase B87.Alarm C Signal: Pickup System C87.Pickup Signal: Pickup87.Trip A Signal: Trip System Phase A87.Trip B Signal: Trip System Phase B87.Trip C Signal: Trip System Phase C87.Trip Signal: Trip87.TripCmd Signal: Trip Command87.Blo H2 Signal: Blocked by Harmonic:287.Blo H4 Signal: Blocked by Harmonic:487.Blo H5 Signal: Blocked by Harmonic:587.H2,H4,H5 Blo Signal: Blocked by Harmonics (Inhibit)87.Slope Blo Signal: Differential protection was blocked by current transformer

saturation. The tripping characteristic was lifted because of current transformer saturation.

87.Transient Signal: Temporary restraining of the differential protection afterwards the transformer is being engergized.

87.Restraining Signal: Restraining of the differential protection by means of rising the tripping curve.

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Name Description

87.Slope Blo: A Slope Blo: A87.Slope Blo: B Slope Blo: B87.Slope Blo: C Slope Blo: C87.Restraining: A Restraining: A87.Restraining: B Restraining: B87.Restraining: C Restraining: C87.ExBlo1-I Module Input State: External Blocking187.ExBlo2-I Module Input State: External Blocking287.ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command87H.Active Signal: Active87H.ExBlo Signal: External Blocking87H.Blo TripCmd Signal: Trip Command blocked87H.ExBlo TripCmd Signal: External Blocking of the Trip Command87H.Alarm A Signal: Pickup System Phase A87H.Alarm B Signal: Pickup System Phase B87H.Alarm C Signal: Pickup System C87H.Pickup Signal: Pickup87H.Trip A Signal: Trip System Phase A87H.Trip B Signal: Trip System Phase B87H.Trip C Signal: Trip System Phase C87H.Trip Signal: Trip87H.TripCmd Signal: Trip Command87H.ExBlo1-I Module Input State: External Blocking187H.ExBlo2-I Module Input State: External Blocking287H.ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command87GD[1].Active Signal: Active87GD[1].ExBlo Signal: External Blocking87GD[1].Blo TripCmd Signal: Trip Command blocked87GD[1].ExBlo TripCmd Signal: External Blocking of the Trip Command87GD[1].Pickup Signal: Pickup87GD[1].Trip Signal: Trip87GD[1].TripCmd Signal: Trip Command87GD[1].ExBlo1-I Module Input State: External Blocking187GD[1].ExBlo2-I Module Input State: External Blocking287GD[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command87GDH[1].Active Signal: Active87GDH[1].ExBlo Signal: External Blocking87GDH[1].Blo TripCmd Signal: Trip Command blocked87GDH[1].ExBlo TripCmd Signal: External Blocking of the Trip Command

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87GDH[1].Pickup Signal: Pickup87GDH[1].Trip Signal: Trip87GDH[1].TripCmd Signal: Trip Command87GDH[1].ExBlo1-I Module Input State: External Blocking187GDH[1].ExBlo2-I Module Input State: External Blocking287GDH[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command87GD[2].Active Signal: Active87GD[2].ExBlo Signal: External Blocking87GD[2].Blo TripCmd Signal: Trip Command blocked87GD[2].ExBlo TripCmd Signal: External Blocking of the Trip Command87GD[2].Pickup Signal: Pickup87GD[2].Trip Signal: Trip87GD[2].TripCmd Signal: Trip Command87GD[2].ExBlo1-I Module Input State: External Blocking187GD[2].ExBlo2-I Module Input State: External Blocking287GD[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command87GDH[2].Active Signal: Active87GDH[2].ExBlo Signal: External Blocking87GDH[2].Blo TripCmd Signal: Trip Command blocked87GDH[2].ExBlo TripCmd Signal: External Blocking of the Trip Command87GDH[2].Pickup Signal: Pickup87GDH[2].Trip Signal: Trip87GDH[2].TripCmd Signal: Trip Command87GDH[2].ExBlo1-I Module Input State: External Blocking187GDH[2].ExBlo2-I Module Input State: External Blocking287GDH[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50P[1].Active Signal: Active50P[1].ExBlo Signal: External Blocking50P[1].Rvs Blo Signal: Reverse Blocking50P[1].Blo TripCmd Signal: Trip Command blocked50P[1].ExBlo TripCmd Signal: External Blocking of the Trip Command50P[1].IH2 Blo Signal: Blocking the trip command by IH250P[1].Pickup IA Signal: Pickup IA50P[1].Pickup IB Signal: Pickup IB50P[1].Pickup IC Signal: Pickup IC50P[1].Pickup Signal: Pickup50P[1].Trip Phase A Signal: General Trip Phase A50P[1].Trip Phase B Signal: General Trip Phase B50P[1].Trip Phase C Signal: General Trip Phase C

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Name Description

50P[1].Trip Signal: Trip50P[1].TripCmd Signal: Trip Command50P[1].DefaultSet Signal: Default Parameter Set50P[1].AdaptSet 1 Signal: Adaptive Parameter 150P[1].AdaptSet 2 Signal: Adaptive Parameter 250P[1].AdaptSet 3 Signal: Adaptive Parameter 350P[1].AdaptSet 4 Signal: Adaptive Parameter 450P[1].ExBlo1-I Module Input State: External Blocking150P[1].ExBlo2-I Module Input State: External Blocking250P[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50P[1].Rvs Blo-I Module Input State: Reverse Blocking50P[1].AdaptSet1-I Module Input State: Adaptive Parameter150P[1].AdaptSet2-I Module Input State: Adaptive Parameter250P[1].AdaptSet3-I Module Input State: Adaptive Parameter350P[1].AdaptSet4-I Module Input State: Adaptive Parameter450P[2].Active Signal: Active50P[2].ExBlo Signal: External Blocking50P[2].Rvs Blo Signal: Reverse Blocking50P[2].Blo TripCmd Signal: Trip Command blocked50P[2].ExBlo TripCmd Signal: External Blocking of the Trip Command50P[2].IH2 Blo Signal: Blocking the trip command by IH250P[2].Pickup IA Signal: Pickup IA50P[2].Pickup IB Signal: Pickup IB50P[2].Pickup IC Signal: Pickup IC50P[2].Pickup Signal: Pickup50P[2].Trip Phase A Signal: General Trip Phase A50P[2].Trip Phase B Signal: General Trip Phase B50P[2].Trip Phase C Signal: General Trip Phase C50P[2].Trip Signal: Trip50P[2].TripCmd Signal: Trip Command50P[2].DefaultSet Signal: Default Parameter Set50P[2].AdaptSet 1 Signal: Adaptive Parameter 150P[2].AdaptSet 2 Signal: Adaptive Parameter 250P[2].AdaptSet 3 Signal: Adaptive Parameter 350P[2].AdaptSet 4 Signal: Adaptive Parameter 450P[2].ExBlo1-I Module Input State: External Blocking150P[2].ExBlo2-I Module Input State: External Blocking250P[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50P[2].Rvs Blo-I Module Input State: Reverse Blocking

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50P[2].AdaptSet1-I Module Input State: Adaptive Parameter150P[2].AdaptSet2-I Module Input State: Adaptive Parameter250P[2].AdaptSet3-I Module Input State: Adaptive Parameter350P[2].AdaptSet4-I Module Input State: Adaptive Parameter450P[3].Active Signal: Active50P[3].ExBlo Signal: External Blocking50P[3].Rvs Blo Signal: Reverse Blocking50P[3].Blo TripCmd Signal: Trip Command blocked50P[3].ExBlo TripCmd Signal: External Blocking of the Trip Command50P[3].IH2 Blo Signal: Blocking the trip command by IH250P[3].Pickup IA Signal: Pickup IA50P[3].Pickup IB Signal: Pickup IB50P[3].Pickup IC Signal: Pickup IC50P[3].Pickup Signal: Pickup50P[3].Trip Phase A Signal: General Trip Phase A50P[3].Trip Phase B Signal: General Trip Phase B50P[3].Trip Phase C Signal: General Trip Phase C50P[3].Trip Signal: Trip50P[3].TripCmd Signal: Trip Command50P[3].DefaultSet Signal: Default Parameter Set50P[3].AdaptSet 1 Signal: Adaptive Parameter 150P[3].AdaptSet 2 Signal: Adaptive Parameter 250P[3].AdaptSet 3 Signal: Adaptive Parameter 350P[3].AdaptSet 4 Signal: Adaptive Parameter 450P[3].ExBlo1-I Module Input State: External Blocking150P[3].ExBlo2-I Module Input State: External Blocking250P[3].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50P[3].Rvs Blo-I Module Input State: Reverse Blocking50P[3].AdaptSet1-I Module Input State: Adaptive Parameter150P[3].AdaptSet2-I Module Input State: Adaptive Parameter250P[3].AdaptSet3-I Module Input State: Adaptive Parameter350P[3].AdaptSet4-I Module Input State: Adaptive Parameter450P[4].Active Signal: Active50P[4].ExBlo Signal: External Blocking50P[4].Rvs Blo Signal: Reverse Blocking50P[4].Blo TripCmd Signal: Trip Command blocked50P[4].ExBlo TripCmd Signal: External Blocking of the Trip Command50P[4].IH2 Blo Signal: Blocking the trip command by IH250P[4].Pickup IA Signal: Pickup IA

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50P[4].Pickup IB Signal: Pickup IB50P[4].Pickup IC Signal: Pickup IC50P[4].Pickup Signal: Pickup50P[4].Trip Phase A Signal: General Trip Phase A50P[4].Trip Phase B Signal: General Trip Phase B50P[4].Trip Phase C Signal: General Trip Phase C50P[4].Trip Signal: Trip50P[4].TripCmd Signal: Trip Command50P[4].DefaultSet Signal: Default Parameter Set50P[4].AdaptSet 1 Signal: Adaptive Parameter 150P[4].AdaptSet 2 Signal: Adaptive Parameter 250P[4].AdaptSet 3 Signal: Adaptive Parameter 350P[4].AdaptSet 4 Signal: Adaptive Parameter 450P[4].ExBlo1-I Module Input State: External Blocking150P[4].ExBlo2-I Module Input State: External Blocking250P[4].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50P[4].Rvs Blo-I Module Input State: Reverse Blocking50P[4].AdaptSet1-I Module Input State: Adaptive Parameter150P[4].AdaptSet2-I Module Input State: Adaptive Parameter250P[4].AdaptSet3-I Module Input State: Adaptive Parameter350P[4].AdaptSet4-I Module Input State: Adaptive Parameter451P[1].Active Signal: Active51P[1].ExBlo Signal: External Blocking51P[1].Rvs Blo Signal: Reverse Blocking51P[1].Blo TripCmd Signal: Trip Command blocked51P[1].ExBlo TripCmd Signal: External Blocking of the Trip Command51P[1].IH2 Blo Signal: Blocking the trip command by IH251P[1].Pickup IA Signal: Pickup IA51P[1].Pickup IB Signal: Pickup IB51P[1].Pickup IC Signal: Pickup IC51P[1].Pickup Signal: Pickup51P[1].Trip Phase A Signal: General Trip Phase A51P[1].Trip Phase B Signal: General Trip Phase B51P[1].Trip Phase C Signal: General Trip Phase C51P[1].Trip Signal: Trip51P[1].TripCmd Signal: Trip Command51P[1].DefaultSet Signal: Default Parameter Set51P[1].AdaptSet 1 Signal: Adaptive Parameter 151P[1].AdaptSet 2 Signal: Adaptive Parameter 2

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51P[1].AdaptSet 3 Signal: Adaptive Parameter 351P[1].AdaptSet 4 Signal: Adaptive Parameter 451P[1].ExBlo1-I Module Input State: External Blocking151P[1].ExBlo2-I Module Input State: External Blocking251P[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51P[1].Rvs Blo-I Module Input State: Reverse Blocking51P[1].AdaptSet1-I Module Input State: Adaptive Parameter151P[1].AdaptSet2-I Module Input State: Adaptive Parameter251P[1].AdaptSet3-I Module Input State: Adaptive Parameter351P[1].AdaptSet4-I Module Input State: Adaptive Parameter451P[2].Active Signal: Active51P[2].ExBlo Signal: External Blocking51P[2].Rvs Blo Signal: Reverse Blocking51P[2].Blo TripCmd Signal: Trip Command blocked51P[2].ExBlo TripCmd Signal: External Blocking of the Trip Command51P[2].IH2 Blo Signal: Blocking the trip command by IH251P[2].Pickup IA Signal: Pickup IA51P[2].Pickup IB Signal: Pickup IB51P[2].Pickup IC Signal: Pickup IC51P[2].Pickup Signal: Pickup51P[2].Trip Phase A Signal: General Trip Phase A51P[2].Trip Phase B Signal: General Trip Phase B51P[2].Trip Phase C Signal: General Trip Phase C51P[2].Trip Signal: Trip51P[2].TripCmd Signal: Trip Command51P[2].DefaultSet Signal: Default Parameter Set51P[2].AdaptSet 1 Signal: Adaptive Parameter 151P[2].AdaptSet 2 Signal: Adaptive Parameter 251P[2].AdaptSet 3 Signal: Adaptive Parameter 351P[2].AdaptSet 4 Signal: Adaptive Parameter 451P[2].ExBlo1-I Module Input State: External Blocking151P[2].ExBlo2-I Module Input State: External Blocking251P[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51P[2].Rvs Blo-I Module Input State: Reverse Blocking51P[2].AdaptSet1-I Module Input State: Adaptive Parameter151P[2].AdaptSet2-I Module Input State: Adaptive Parameter251P[2].AdaptSet3-I Module Input State: Adaptive Parameter351P[2].AdaptSet4-I Module Input State: Adaptive Parameter451P[3].Active Signal: Active

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51P[3].ExBlo Signal: External Blocking51P[3].Rvs Blo Signal: Reverse Blocking51P[3].Blo TripCmd Signal: Trip Command blocked51P[3].ExBlo TripCmd Signal: External Blocking of the Trip Command51P[3].IH2 Blo Signal: Blocking the trip command by IH251P[3].Pickup IA Signal: Pickup IA51P[3].Pickup IB Signal: Pickup IB51P[3].Pickup IC Signal: Pickup IC51P[3].Pickup Signal: Pickup51P[3].Trip Phase A Signal: General Trip Phase A51P[3].Trip Phase B Signal: General Trip Phase B51P[3].Trip Phase C Signal: General Trip Phase C51P[3].Trip Signal: Trip51P[3].TripCmd Signal: Trip Command51P[3].DefaultSet Signal: Default Parameter Set51P[3].AdaptSet 1 Signal: Adaptive Parameter 151P[3].AdaptSet 2 Signal: Adaptive Parameter 251P[3].AdaptSet 3 Signal: Adaptive Parameter 351P[3].AdaptSet 4 Signal: Adaptive Parameter 451P[3].ExBlo1-I Module Input State: External Blocking151P[3].ExBlo2-I Module Input State: External Blocking251P[3].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51P[3].Rvs Blo-I Module Input State: Reverse Blocking51P[3].AdaptSet1-I Module Input State: Adaptive Parameter151P[3].AdaptSet2-I Module Input State: Adaptive Parameter251P[3].AdaptSet3-I Module Input State: Adaptive Parameter351P[3].AdaptSet4-I Module Input State: Adaptive Parameter451P[4].Active Signal: Active51P[4].ExBlo Signal: External Blocking51P[4].Rvs Blo Signal: Reverse Blocking51P[4].Blo TripCmd Signal: Trip Command blocked51P[4].ExBlo TripCmd Signal: External Blocking of the Trip Command51P[4].IH2 Blo Signal: Blocking the trip command by IH251P[4].Pickup IA Signal: Pickup IA51P[4].Pickup IB Signal: Pickup IB51P[4].Pickup IC Signal: Pickup IC51P[4].Pickup Signal: Pickup51P[4].Trip Phase A Signal: General Trip Phase A51P[4].Trip Phase B Signal: General Trip Phase B

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51P[4].Trip Phase C Signal: General Trip Phase C51P[4].Trip Signal: Trip51P[4].TripCmd Signal: Trip Command51P[4].DefaultSet Signal: Default Parameter Set51P[4].AdaptSet 1 Signal: Adaptive Parameter 151P[4].AdaptSet 2 Signal: Adaptive Parameter 251P[4].AdaptSet 3 Signal: Adaptive Parameter 351P[4].AdaptSet 4 Signal: Adaptive Parameter 451P[4].ExBlo1-I Module Input State: External Blocking151P[4].ExBlo2-I Module Input State: External Blocking251P[4].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51P[4].Rvs Blo-I Module Input State: Reverse Blocking51P[4].AdaptSet1-I Module Input State: Adaptive Parameter151P[4].AdaptSet2-I Module Input State: Adaptive Parameter251P[4].AdaptSet3-I Module Input State: Adaptive Parameter351P[4].AdaptSet4-I Module Input State: Adaptive Parameter450X[1].Active Signal: Active50X[1].ExBlo Signal: External Blocking50X[1].Rvs Blo Signal: Reverse Blocking50X[1].Blo TripCmd Signal: Trip Command blocked50X[1].ExBlo TripCmd Signal: External Blocking of the Trip Command50X[1].Pickup Signal: Pickup IX or IR50X[1].Trip Signal: Trip50X[1].TripCmd Signal: Trip Command50X[1].IGH2 Blo Signal: Blocked by IH250X[1].DefaultSet Signal: Default Parameter Set50X[1].AdaptSet 1 Signal: Adaptive Parameter 150X[1].AdaptSet 2 Signal: Adaptive Parameter 250X[1].AdaptSet 3 Signal: Adaptive Parameter 350X[1].AdaptSet 4 Signal: Adaptive Parameter 450X[1].ExBlo1-I Module Input State: External Blocking150X[1].ExBlo2-I Module Input State: External Blocking250X[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50X[1].Rvs Blo-I Module Input State: Reverse Blocking50X[1].AdaptSet1-I Module Input State: Adaptive Parameter150X[1].AdaptSet2-I Module Input State: Adaptive Parameter250X[1].AdaptSet3-I Module Input State: Adaptive Parameter350X[1].AdaptSet4-I Module Input State: Adaptive Parameter450X[2].Active Signal: Active

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50X[2].ExBlo Signal: External Blocking50X[2].Rvs Blo Signal: Reverse Blocking50X[2].Blo TripCmd Signal: Trip Command blocked50X[2].ExBlo TripCmd Signal: External Blocking of the Trip Command50X[2].Pickup Signal: Pickup IX or IR50X[2].Trip Signal: Trip50X[2].TripCmd Signal: Trip Command50X[2].IGH2 Blo Signal: Blocked by IH250X[2].DefaultSet Signal: Default Parameter Set50X[2].AdaptSet 1 Signal: Adaptive Parameter 150X[2].AdaptSet 2 Signal: Adaptive Parameter 250X[2].AdaptSet 3 Signal: Adaptive Parameter 350X[2].AdaptSet 4 Signal: Adaptive Parameter 450X[2].ExBlo1-I Module Input State: External Blocking150X[2].ExBlo2-I Module Input State: External Blocking250X[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50X[2].Rvs Blo-I Module Input State: Reverse Blocking50X[2].AdaptSet1-I Module Input State: Adaptive Parameter150X[2].AdaptSet2-I Module Input State: Adaptive Parameter250X[2].AdaptSet3-I Module Input State: Adaptive Parameter350X[2].AdaptSet4-I Module Input State: Adaptive Parameter451X[1].Active Signal: Active51X[1].ExBlo Signal: External Blocking51X[1].Rvs Blo Signal: Reverse Blocking51X[1].Blo TripCmd Signal: Trip Command blocked51X[1].ExBlo TripCmd Signal: External Blocking of the Trip Command51X[1].Pickup Signal: Pickup IX or IR51X[1].Trip Signal: Trip51X[1].TripCmd Signal: Trip Command51X[1].IGH2 Blo Signal: Blocked by IH251X[1].DefaultSet Signal: Default Parameter Set51X[1].AdaptSet 1 Signal: Adaptive Parameter 151X[1].AdaptSet 2 Signal: Adaptive Parameter 251X[1].AdaptSet 3 Signal: Adaptive Parameter 351X[1].AdaptSet 4 Signal: Adaptive Parameter 451X[1].ExBlo1-I Module Input State: External Blocking151X[1].ExBlo2-I Module Input State: External Blocking251X[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51X[1].Rvs Blo-I Module Input State: Reverse Blocking

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IM02602013E ETR-5000

Name Description

51X[1].AdaptSet1-I Module Input State: Adaptive Parameter151X[1].AdaptSet2-I Module Input State: Adaptive Parameter251X[1].AdaptSet3-I Module Input State: Adaptive Parameter351X[1].AdaptSet4-I Module Input State: Adaptive Parameter451X[2].Active Signal: Active51X[2].ExBlo Signal: External Blocking51X[2].Rvs Blo Signal: Reverse Blocking51X[2].Blo TripCmd Signal: Trip Command blocked51X[2].ExBlo TripCmd Signal: External Blocking of the Trip Command51X[2].Pickup Signal: Pickup IX or IR51X[2].Trip Signal: Trip51X[2].TripCmd Signal: Trip Command51X[2].IGH2 Blo Signal: Blocked by IH251X[2].DefaultSet Signal: Default Parameter Set51X[2].AdaptSet 1 Signal: Adaptive Parameter 151X[2].AdaptSet 2 Signal: Adaptive Parameter 251X[2].AdaptSet 3 Signal: Adaptive Parameter 351X[2].AdaptSet 4 Signal: Adaptive Parameter 451X[2].ExBlo1-I Module Input State: External Blocking151X[2].ExBlo2-I Module Input State: External Blocking251X[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51X[2].Rvs Blo-I Module Input State: Reverse Blocking51X[2].AdaptSet1-I Module Input State: Adaptive Parameter151X[2].AdaptSet2-I Module Input State: Adaptive Parameter251X[2].AdaptSet3-I Module Input State: Adaptive Parameter351X[2].AdaptSet4-I Module Input State: Adaptive Parameter450R[1].Active Signal: Active50R[1].ExBlo Signal: External Blocking50R[1].Rvs Blo Signal: Reverse Blocking50R[1].Blo TripCmd Signal: Trip Command blocked50R[1].ExBlo TripCmd Signal: External Blocking of the Trip Command50R[1].Pickup Signal: Pickup IX or IR50R[1].Trip Signal: Trip50R[1].TripCmd Signal: Trip Command50R[1].IGH2 Blo Signal: Blocked by IH250R[1].DefaultSet Signal: Default Parameter Set50R[1].AdaptSet 1 Signal: Adaptive Parameter 150R[1].AdaptSet 2 Signal: Adaptive Parameter 250R[1].AdaptSet 3 Signal: Adaptive Parameter 3

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ETR-5000 IM02602013E

Name Description

50R[1].AdaptSet 4 Signal: Adaptive Parameter 450R[1].ExBlo1-I Module Input State: External Blocking150R[1].ExBlo2-I Module Input State: External Blocking250R[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50R[1].Rvs Blo-I Module Input State: Reverse Blocking50R[1].AdaptSet1-I Module Input State: Adaptive Parameter150R[1].AdaptSet2-I Module Input State: Adaptive Parameter250R[1].AdaptSet3-I Module Input State: Adaptive Parameter350R[1].AdaptSet4-I Module Input State: Adaptive Parameter450R[2].Active Signal: Active50R[2].ExBlo Signal: External Blocking50R[2].Rvs Blo Signal: Reverse Blocking50R[2].Blo TripCmd Signal: Trip Command blocked50R[2].ExBlo TripCmd Signal: External Blocking of the Trip Command50R[2].Pickup Signal: Pickup IX or IR50R[2].Trip Signal: Trip50R[2].TripCmd Signal: Trip Command50R[2].IGH2 Blo Signal: Blocked by IH250R[2].DefaultSet Signal: Default Parameter Set50R[2].AdaptSet 1 Signal: Adaptive Parameter 150R[2].AdaptSet 2 Signal: Adaptive Parameter 250R[2].AdaptSet 3 Signal: Adaptive Parameter 350R[2].AdaptSet 4 Signal: Adaptive Parameter 450R[2].ExBlo1-I Module Input State: External Blocking150R[2].ExBlo2-I Module Input State: External Blocking250R[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command50R[2].Rvs Blo-I Module Input State: Reverse Blocking50R[2].AdaptSet1-I Module Input State: Adaptive Parameter150R[2].AdaptSet2-I Module Input State: Adaptive Parameter250R[2].AdaptSet3-I Module Input State: Adaptive Parameter350R[2].AdaptSet4-I Module Input State: Adaptive Parameter451R[1].Active Signal: Active51R[1].ExBlo Signal: External Blocking51R[1].Rvs Blo Signal: Reverse Blocking51R[1].Blo TripCmd Signal: Trip Command blocked51R[1].ExBlo TripCmd Signal: External Blocking of the Trip Command51R[1].Pickup Signal: Pickup IX or IR51R[1].Trip Signal: Trip51R[1].TripCmd Signal: Trip Command

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IM02602013E ETR-5000

Name Description

51R[1].IGH2 Blo Signal: Blocked by IH251R[1].DefaultSet Signal: Default Parameter Set51R[1].AdaptSet 1 Signal: Adaptive Parameter 151R[1].AdaptSet 2 Signal: Adaptive Parameter 251R[1].AdaptSet 3 Signal: Adaptive Parameter 351R[1].AdaptSet 4 Signal: Adaptive Parameter 451R[1].ExBlo1-I Module Input State: External Blocking151R[1].ExBlo2-I Module Input State: External Blocking251R[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51R[1].Rvs Blo-I Module Input State: Reverse Blocking51R[1].AdaptSet1-I Module Input State: Adaptive Parameter151R[1].AdaptSet2-I Module Input State: Adaptive Parameter251R[1].AdaptSet3-I Module Input State: Adaptive Parameter351R[1].AdaptSet4-I Module Input State: Adaptive Parameter451R[2].Active Signal: Active51R[2].ExBlo Signal: External Blocking51R[2].Rvs Blo Signal: Reverse Blocking51R[2].Blo TripCmd Signal: Trip Command blocked51R[2].ExBlo TripCmd Signal: External Blocking of the Trip Command51R[2].Pickup Signal: Pickup IX or IR51R[2].Trip Signal: Trip51R[2].TripCmd Signal: Trip Command51R[2].IGH2 Blo Signal: Blocked by IH251R[2].DefaultSet Signal: Default Parameter Set51R[2].AdaptSet 1 Signal: Adaptive Parameter 151R[2].AdaptSet 2 Signal: Adaptive Parameter 251R[2].AdaptSet 3 Signal: Adaptive Parameter 351R[2].AdaptSet 4 Signal: Adaptive Parameter 451R[2].ExBlo1-I Module Input State: External Blocking151R[2].ExBlo2-I Module Input State: External Blocking251R[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51R[2].Rvs Blo-I Module Input State: Reverse Blocking51R[2].AdaptSet1-I Module Input State: Adaptive Parameter151R[2].AdaptSet2-I Module Input State: Adaptive Parameter251R[2].AdaptSet3-I Module Input State: Adaptive Parameter351R[2].AdaptSet4-I Module Input State: Adaptive Parameter449.Active Signal: Active49.ExBlo Signal: External Blocking49.Blo TripCmd Signal: Trip Command blocked

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ETR-5000 IM02602013E

Name Description

49.ExBlo TripCmd Signal: External Blocking of the Trip Command49.Alarm Signal: Alarm Thermal Overload49.Trip Signal: Trip49.TripCmd Signal: Trip Command49.Res Thermal Cap Signal: Resetting Thermal Replica49.ExBlo1-I Module Input State: External Blocking149.ExBlo2-I Module Input State: External Blocking249.ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51Q[1].Active Signal: Active51Q[1].ExBlo Signal: External Blocking51Q[1].Rvs Blo Signal: Reverse Blocking51Q[1].Blo TripCmd Signal: Trip Command blocked51Q[1].ExBlo TripCmd Signal: External Blocking of the Trip Command51Q[1].IH2 Blo Signal: Blocking the trip command by IH251Q[1].Pickup Signal: Pickup51Q[1].Trip Signal: Trip51Q[1].TripCmd Signal: Trip Command51Q[1].DefaultSet Signal: Default Parameter Set51Q[1].AdaptSet 1 Signal: Adaptive Parameter 151Q[1].AdaptSet 2 Signal: Adaptive Parameter 251Q[1].AdaptSet 3 Signal: Adaptive Parameter 351Q[1].AdaptSet 4 Signal: Adaptive Parameter 451Q[1].ExBlo1-I Module Input State: External Blocking151Q[1].ExBlo2-I Module Input State: External Blocking251Q[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51Q[1].Rvs Blo-I Module Input State: Reverse Blocking51Q[1].AdaptSet1-I Module Input State: Adaptive Parameter151Q[1].AdaptSet2-I Module Input State: Adaptive Parameter251Q[1].AdaptSet3-I Module Input State: Adaptive Parameter351Q[1].AdaptSet4-I Module Input State: Adaptive Parameter451Q[2].Active Signal: Active51Q[2].ExBlo Signal: External Blocking51Q[2].Rvs Blo Signal: Reverse Blocking51Q[2].Blo TripCmd Signal: Trip Command blocked51Q[2].ExBlo TripCmd Signal: External Blocking of the Trip Command51Q[2].IH2 Blo Signal: Blocking the trip command by IH251Q[2].Pickup Signal: Pickup51Q[2].Trip Signal: Trip51Q[2].TripCmd Signal: Trip Command

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IM02602013E ETR-5000

Name Description

51Q[2].DefaultSet Signal: Default Parameter Set51Q[2].AdaptSet 1 Signal: Adaptive Parameter 151Q[2].AdaptSet 2 Signal: Adaptive Parameter 251Q[2].AdaptSet 3 Signal: Adaptive Parameter 351Q[2].AdaptSet 4 Signal: Adaptive Parameter 451Q[2].ExBlo1-I Module Input State: External Blocking151Q[2].ExBlo2-I Module Input State: External Blocking251Q[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command51Q[2].Rvs Blo-I Module Input State: Reverse Blocking51Q[2].AdaptSet1-I Module Input State: Adaptive Parameter151Q[2].AdaptSet2-I Module Input State: Adaptive Parameter251Q[2].AdaptSet3-I Module Input State: Adaptive Parameter351Q[2].AdaptSet4-I Module Input State: Adaptive Parameter4IH2[1].Active Signal: ActiveIH2[1].ExBlo Signal: External BlockingIH2[1].Blo Phase A Signal: Blocked Phase AIH2[1].Blo Phase B Signal: Blocked Phase BIH2[1].Blo Phase C Signal: Blocked Phase CIH2[1].Blo IG meas Signal: Blocking of the ground protection module (measured


ground current)IH2[1].3-ph Blo Signal: Inrush was detected in at least one phase - trip command

blocked.IH2[1].ExBlo1-I Module Input State: External Blocking1IH2[1].ExBlo2-I Module Input State: External Blocking2IH2[2].Active Signal: ActiveIH2[2].ExBlo Signal: External BlockingIH2[2].Blo Phase A Signal: Blocked Phase AIH2[2].Blo Phase B Signal: Blocked Phase BIH2[2].Blo Phase C Signal: Blocked Phase CIH2[2].Blo IG meas Signal: Blocking of the ground protection module (measured


ground current)IH2[2].3-ph Blo Signal: Inrush was detected in at least one phase - trip command

blocked.IH2[2].ExBlo1-I Module Input State: External Blocking1IH2[2].ExBlo2-I Module Input State: External Blocking227M[1].Active Signal: Active27M[1].ExBlo Signal: External Blocking

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ETR-5000 IM02602013E

Name Description

27M[1].Blo TripCmd Signal: Trip Command blocked27M[1].ExBlo TripCmd Signal: External Blocking of the Trip Command27M[1].Pickup Phase A Signal: Pickup Phase A27M[1].Pickup Phase B Signal: Pickup Phase B27M[1].Pickup Phase C Signal: Pickup Phase C27M[1].Pickup Signal: Pickup Voltage Element27M[1].Trip Phase A Signal: General Trip Phase A27M[1].Trip Phase B Signal: General Trip Phase B27M[1].Trip Phase C Signal: General Trip Phase C27M[1].Trip Signal: Trip27M[1].TripCmd Signal: Trip Command27M[1].ExBlo1-I Module Input State: External Blocking127M[1].ExBlo2-I Module Input State: External Blocking227M[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command27M[2].Active Signal: Active27M[2].ExBlo Signal: External Blocking27M[2].Blo TripCmd Signal: Trip Command blocked27M[2].ExBlo TripCmd Signal: External Blocking of the Trip Command27M[2].Pickup Phase A Signal: Pickup Phase A27M[2].Pickup Phase B Signal: Pickup Phase B27M[2].Pickup Phase C Signal: Pickup Phase C27M[2].Pickup Signal: Pickup Voltage Element27M[2].Trip Phase A Signal: General Trip Phase A27M[2].Trip Phase B Signal: General Trip Phase B27M[2].Trip Phase C Signal: General Trip Phase C27M[2].Trip Signal: Trip27M[2].TripCmd Signal: Trip Command27M[2].ExBlo1-I Module Input State: External Blocking127M[2].ExBlo2-I Module Input State: External Blocking227M[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command59M[1].Active Signal: Active59M[1].ExBlo Signal: External Blocking59M[1].Blo TripCmd Signal: Trip Command blocked59M[1].ExBlo TripCmd Signal: External Blocking of the Trip Command59M[1].Pickup Phase A Signal: Pickup Phase A59M[1].Pickup Phase B Signal: Pickup Phase B59M[1].Pickup Phase C Signal: Pickup Phase C59M[1].Pickup Signal: Pickup Voltage Element59M[1].Trip Phase A Signal: General Trip Phase A

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IM02602013E ETR-5000

Name Description

59M[1].Trip Phase B Signal: General Trip Phase B59M[1].Trip Phase C Signal: General Trip Phase C59M[1].Trip Signal: Trip59M[1].TripCmd Signal: Trip Command59M[1].ExBlo1-I Module Input State: External Blocking159M[1].ExBlo2-I Module Input State: External Blocking259M[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command59M[2].Active Signal: Active59M[2].ExBlo Signal: External Blocking59M[2].Blo TripCmd Signal: Trip Command blocked59M[2].ExBlo TripCmd Signal: External Blocking of the Trip Command59M[2].Pickup Phase A Signal: Pickup Phase A59M[2].Pickup Phase B Signal: Pickup Phase B59M[2].Pickup Phase C Signal: Pickup Phase C59M[2].Pickup Signal: Pickup Voltage Element59M[2].Trip Phase A Signal: General Trip Phase A59M[2].Trip Phase B Signal: General Trip Phase B59M[2].Trip Phase C Signal: General Trip Phase C59M[2].Trip Signal: Trip59M[2].TripCmd Signal: Trip Command59M[2].ExBlo1-I Module Input State: External Blocking159M[2].ExBlo2-I Module Input State: External Blocking259M[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command27A[1].Active Signal: Active27A[1].ExBlo Signal: External Blocking27A[1].Blo TripCmd Signal: Trip Command blocked27A[1].ExBlo TripCmd Signal: External Blocking of the Trip Command27A[1].Pickup Signal: Pickup Residual Voltage Supervision-Element27A[1].Trip Signal: Trip27A[1].TripCmd Signal: Trip Command27A[1].ExBlo1-I Module Input State: External Blocking127A[1].ExBlo2-I Module Input State: External Blocking227A[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command27A[2].Active Signal: Active27A[2].ExBlo Signal: External Blocking27A[2].Blo TripCmd Signal: Trip Command blocked27A[2].ExBlo TripCmd Signal: External Blocking of the Trip Command27A[2].Pickup Signal: Pickup Residual Voltage Supervision-Element27A[2].Trip Signal: Trip

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ETR-5000 IM02602013E

Name Description

27A[2].TripCmd Signal: Trip Command27A[2].ExBlo1-I Module Input State: External Blocking127A[2].ExBlo2-I Module Input State: External Blocking227A[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command59A[1].Active Signal: Active59A[1].ExBlo Signal: External Blocking59A[1].Blo TripCmd Signal: Trip Command blocked59A[1].ExBlo TripCmd Signal: External Blocking of the Trip Command59A[1].Pickup Signal: Pickup Residual Voltage Supervision-Element59A[1].Trip Signal: Trip59A[1].TripCmd Signal: Trip Command59A[1].ExBlo1-I Module Input State: External Blocking159A[1].ExBlo2-I Module Input State: External Blocking259A[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command59A[2].Active Signal: Active59A[2].ExBlo Signal: External Blocking59A[2].Blo TripCmd Signal: Trip Command blocked59A[2].ExBlo TripCmd Signal: External Blocking of the Trip Command59A[2].Pickup Signal: Pickup Residual Voltage Supervision-Element59A[2].Trip Signal: Trip59A[2].TripCmd Signal: Trip Command59A[2].ExBlo1-I Module Input State: External Blocking159A[2].ExBlo2-I Module Input State: External Blocking259A[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command46[1].Active Signal: Active46[1].ExBlo Signal: External Blocking46[1].Blo TripCmd Signal: Trip Command blocked46[1].ExBlo TripCmd Signal: External Blocking of the Trip Command46[1].Pickup Signal: Pickup Negative Sequence46[1].Trip Signal: Trip46[1].TripCmd Signal: Trip Command46[1].ExBlo1-I Module Input State: External Blocking146[1].ExBlo2-I Module Input State: External Blocking246[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command46[2].Active Signal: Active46[2].ExBlo Signal: External Blocking46[2].Blo TripCmd Signal: Trip Command blocked46[2].ExBlo TripCmd Signal: External Blocking of the Trip Command46[2].Pickup Signal: Pickup Negative Sequence

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IM02602013E ETR-5000

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46[2].Trip Signal: Trip46[2].TripCmd Signal: Trip Command46[2].ExBlo1-I Module Input State: External Blocking146[2].ExBlo2-I Module Input State: External Blocking246[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command47[1].Active Signal: Active47[1].ExBlo Signal: External Blocking47[1].Blo TripCmd Signal: Trip Command blocked47[1].ExBlo TripCmd Signal: External Blocking of the Trip Command47[1].Pickup Signal: Pickup Voltage Asymmetry47[1].Trip Signal: Trip47[1].TripCmd Signal: Trip Command47[1].ExBlo1-I Module Input State: External Blocking147[1].ExBlo2-I Module Input State: External Blocking247[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command47[2].Active Signal: Active47[2].ExBlo Signal: External Blocking47[2].Blo TripCmd Signal: Trip Command blocked47[2].ExBlo TripCmd Signal: External Blocking of the Trip Command47[2].Pickup Signal: Pickup Voltage Asymmetry47[2].Trip Signal: Trip47[2].TripCmd Signal: Trip Command47[2].ExBlo1-I Module Input State: External Blocking147[2].ExBlo2-I Module Input State: External Blocking247[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command81[1].Active Signal: Active81[1].ExBlo Signal: External Blocking81[1].Blo by V< Signal: Module is blocked by undervoltage.81[1].Blo TripCmd Signal: Trip Command blocked81[1].ExBlo TripCmd Signal: External Blocking of the Trip Command81[1].Pickup 81 Signal: Pickup Frequency Protection81[1].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change 81[1].Pickup Vector Surge Signal: Pickup Vector Surge81[1].Pickup Signal: Pickup Frequency Protection (collective signal)81[1].Trip 81 Signal: Frequency has exceeded the limit.81[1].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[1].Trip Vector Surge Signal: Trip delta phi81[1].Trip Signal: Trip Frequency Protection (collective signal)81[1].TripCmd Signal: Trip Command

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ETR-5000 IM02602013E

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81[1].ExBlo1-I Module Input State: External Blocking181[1].ExBlo2-I Module Input State: External Blocking281[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command81[2].Active Signal: Active81[2].ExBlo Signal: External Blocking81[2].Blo by V< Signal: Module is blocked by undervoltage.81[2].Blo TripCmd Signal: Trip Command blocked81[2].ExBlo TripCmd Signal: External Blocking of the Trip Command81[2].Pickup 81 Signal: Pickup Frequency Protection81[2].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change 81[2].Pickup Vector Surge Signal: Pickup Vector Surge81[2].Pickup Signal: Pickup Frequency Protection (collective signal)81[2].Trip 81 Signal: Frequency has exceeded the limit.81[2].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[2].Trip Vector Surge Signal: Trip delta phi81[2].Trip Signal: Trip Frequency Protection (collective signal)81[2].TripCmd Signal: Trip Command81[2].ExBlo1-I Module Input State: External Blocking181[2].ExBlo2-I Module Input State: External Blocking281[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command81[3].Active Signal: Active81[3].ExBlo Signal: External Blocking81[3].Blo by V< Signal: Module is blocked by undervoltage.81[3].Blo TripCmd Signal: Trip Command blocked81[3].ExBlo TripCmd Signal: External Blocking of the Trip Command81[3].Pickup 81 Signal: Pickup Frequency Protection81[3].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change 81[3].Pickup Vector Surge Signal: Pickup Vector Surge81[3].Pickup Signal: Pickup Frequency Protection (collective signal)81[3].Trip 81 Signal: Frequency has exceeded the limit.81[3].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[3].Trip Vector Surge Signal: Trip delta phi81[3].Trip Signal: Trip Frequency Protection (collective signal)81[3].TripCmd Signal: Trip Command81[3].ExBlo1-I Module Input State: External Blocking181[3].ExBlo2-I Module Input State: External Blocking281[3].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command81[4].Active Signal: Active

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IM02602013E ETR-5000

Name Description

81[4].ExBlo Signal: External Blocking81[4].Blo by V< Signal: Module is blocked by undervoltage.81[4].Blo TripCmd Signal: Trip Command blocked81[4].ExBlo TripCmd Signal: External Blocking of the Trip Command81[4].Pickup 81 Signal: Pickup Frequency Protection81[4].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change 81[4].Pickup Vector Surge Signal: Pickup Vector Surge81[4].Pickup Signal: Pickup Frequency Protection (collective signal)81[4].Trip 81 Signal: Frequency has exceeded the limit.81[4].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[4].Trip Vector Surge Signal: Trip delta phi81[4].Trip Signal: Trip Frequency Protection (collective signal)81[4].TripCmd Signal: Trip Command81[4].ExBlo1-I Module Input State: External Blocking181[4].ExBlo2-I Module Input State: External Blocking281[4].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command81[5].Active Signal: Active81[5].ExBlo Signal: External Blocking81[5].Blo by V< Signal: Module is blocked by undervoltage.81[5].Blo TripCmd Signal: Trip Command blocked81[5].ExBlo TripCmd Signal: External Blocking of the Trip Command81[5].Pickup 81 Signal: Pickup Frequency Protection81[5].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change 81[5].Pickup Vector Surge Signal: Pickup Vector Surge81[5].Pickup Signal: Pickup Frequency Protection (collective signal)81[5].Trip 81 Signal: Frequency has exceeded the limit.81[5].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[5].Trip Vector Surge Signal: Trip delta phi81[5].Trip Signal: Trip Frequency Protection (collective signal)81[5].TripCmd Signal: Trip Command81[5].ExBlo1-I Module Input State: External Blocking181[5].ExBlo2-I Module Input State: External Blocking281[5].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command81[6].Active Signal: Active81[6].ExBlo Signal: External Blocking81[6].Blo by V< Signal: Module is blocked by undervoltage.81[6].Blo TripCmd Signal: Trip Command blocked81[6].ExBlo TripCmd Signal: External Blocking of the Trip Command

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ETR-5000 IM02602013E

Name Description

81[6].Pickup 81 Signal: Pickup Frequency Protection81[6].Pickup df/dt | DF/DT Pickup instantaneous or average value of the rate-of-frequency-

change 81[6].Pickup Vector Surge Signal: Pickup Vector Surge81[6].Pickup Signal: Pickup Frequency Protection (collective signal)81[6].Trip 81 Signal: Frequency has exceeded the limit.81[6].Trip df/dt | DF/DT Signal: Trip df/dt or DF/DT81[6].Trip Vector Surge Signal: Trip delta phi81[6].Trip Signal: Trip Frequency Protection (collective signal)81[6].TripCmd Signal: Trip Command81[6].ExBlo1-I Module Input State: External Blocking181[6].ExBlo2-I Module Input State: External Blocking281[6].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command32[1].Active Signal: Active32[1].ExBlo Signal: External Blocking32[1].Blo TripCmd Signal: Trip Command blocked32[1].ExBlo TripCmd Signal: External Blocking of the Trip Command32[1].Pickup Signal: Pickup Power Protection32[1].Trip Signal: Trip Power Protection32[1].TripCmd Signal: Trip Command32[1].ExBlo1-I Module Input State: External Blocking32[1].ExBlo2-I Module Input State: External Blocking32[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command32[2].Active Signal: Active32[2].ExBlo Signal: External Blocking32[2].Blo TripCmd Signal: Trip Command blocked32[2].ExBlo TripCmd Signal: External Blocking of the Trip Command32[2].Pickup Signal: Pickup Power Protection32[2].Trip Signal: Trip Power Protection32[2].TripCmd Signal: Trip Command32[2].ExBlo1-I Module Input State: External Blocking32[2].ExBlo2-I Module Input State: External Blocking32[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command32[3].Active Signal: Active32[3].ExBlo Signal: External Blocking32[3].Blo TripCmd Signal: Trip Command blocked32[3].ExBlo TripCmd Signal: External Blocking of the Trip Command32[3].Pickup Signal: Pickup Power Protection32[3].Trip Signal: Trip Power Protection32[3].TripCmd Signal: Trip Command

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IM02602013E ETR-5000

Name Description

32[3].ExBlo1-I Module Input State: External Blocking32[3].ExBlo2-I Module Input State: External Blocking32[3].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command32V[1].Active Signal: Active32V[1].ExBlo Signal: External Blocking32V[1].Blo TripCmd Signal: Trip Command blocked32V[1].ExBlo TripCmd Signal: External Blocking of the Trip Command32V[1].Pickup Signal: Pickup Power Protection32V[1].Trip Signal: Trip Power Protection32V[1].TripCmd Signal: Trip Command32V[1].ExBlo1-I Module Input State: External Blocking32V[1].ExBlo2-I Module Input State: External Blocking32V[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command32V[2].Active Signal: Active32V[2].ExBlo Signal: External Blocking32V[2].Blo TripCmd Signal: Trip Command blocked32V[2].ExBlo TripCmd Signal: External Blocking of the Trip Command32V[2].Pickup Signal: Pickup Power Protection32V[2].Trip Signal: Trip Power Protection32V[2].TripCmd Signal: Trip Command32V[2].ExBlo1-I Module Input State: External Blocking32V[2].ExBlo2-I Module Input State: External Blocking32V[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command32V[3].Active Signal: Active32V[3].ExBlo Signal: External Blocking32V[3].Blo TripCmd Signal: Trip Command blocked32V[3].ExBlo TripCmd Signal: External Blocking of the Trip Command32V[3].Pickup Signal: Pickup Power Protection32V[3].Trip Signal: Trip Power Protection32V[3].TripCmd Signal: Trip Command32V[3].ExBlo1-I Module Input State: External Blocking32V[3].ExBlo2-I Module Input State: External Blocking32V[3].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandZI[1].Active Signal: ActiveZI[1].ExBlo Signal: External BlockingZI[1].Blo TripCmd Signal: Trip Command blockedZI[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandZI[1].Bkr Blo Signal: Blocked by Breaker FailureZI[1].Phase Pickup Signal: Zone Interlocking Phase Pickup

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ETR-5000 IM02602013E

Name Description

ZI[1].Phase Trip Signal: Zone Interlocking Phase Trip ZI[1].Ground Pickup Signal: Zone Interlocking Ground PickupZI[1].Ground Trip Signal: Zone Interlocking Ground Trip ZI[1].Pickup Signal: Pickup Zone InterlockingZI[1].Trip Signal: Zone Interlocking TripZI[1].TripCmd Signal: Zone Interlocking Trip CommandZI[1].Phase OUT Signal: Zone Interlocking Phase OUTZI[1].Ground OUT Signal: Zone Interlocking Ground OUTZI[1].OUT Signal: Zone Interlocking OUTZI[1].IN Signal: Zone Interlocking INZI[1].ExBlo1-I Module Input State: External Blocking1ZI[1].ExBlo2-I Module Input State: External Blocking2ZI[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandZI[2].Active Signal: ActiveZI[2].ExBlo Signal: External BlockingZI[2].Blo TripCmd Signal: Trip Command blockedZI[2].ExBlo TripCmd Signal: External Blocking of the Trip CommandZI[2].Bkr Blo Signal: Blocked by Breaker FailureZI[2].Phase Pickup Signal: Zone Interlocking Phase PickupZI[2].Phase Trip Signal: Zone Interlocking Phase Trip ZI[2].Ground Pickup Signal: Zone Interlocking Ground PickupZI[2].Ground Trip Signal: Zone Interlocking Ground Trip ZI[2].Pickup Signal: Pickup Zone InterlockingZI[2].Trip Signal: Zone Interlocking TripZI[2].TripCmd Signal: Zone Interlocking Trip CommandZI[2].Phase OUT Signal: Zone Interlocking Phase OUTZI[2].Ground OUT Signal: Zone Interlocking Ground OUTZI[2].OUT Signal: Zone Interlocking OUTZI[2].IN Signal: Zone Interlocking INZI[2].ExBlo1-I Module Input State: External Blocking1ZI[2].ExBlo2-I Module Input State: External Blocking2ZI[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command24[1].Active Signal: Active24[1].ExBlo Signal: External Blocking24[1].Blo TripCmd Signal: Trip Command blocked24[1].ExBlo TripCmd Signal: External Blocking of the Trip Command24[1].Pickup Signal: Pickup24[1].Trip Signal: Trip24[1].TripCmd Signal: Trip Command

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IM02602013E ETR-5000

Name Description

24[1].ExBlo1-I Module Input State: External Blocking124[1].ExBlo2-I Module Input State: External Blocking224[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip Command24[2].Active Signal: Active24[2].ExBlo Signal: External Blocking24[2].Blo TripCmd Signal: Trip Command blocked24[2].ExBlo TripCmd Signal: External Blocking of the Trip Command24[2].Pickup Signal: Pickup24[2].Trip Signal: Trip24[2].TripCmd Signal: Trip Command24[2].ExBlo1-I Module Input State: External Blocking124[2].ExBlo2-I Module Input State: External Blocking224[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandSOTF.Active Signal: ActiveSOTF.ExBlo Signal: External BlockingSOTF.Rvs Blo Signal: Reverse BlockingSOTF.enabled Signal: Switch Onto Fault enabled. This Signal can be used to

modify Overcurrent Protection Settings.SOTF.I< Signal: No Load Current.SOTF.ExBlo1-I Module Input State: External BlockingSOTF.ExBlo2-I Module Input State: External BlockingSOTF.Rvs Blo-I Module Input State: Reverse BlockingSOTF.Ext SOTF-I Module Input State: External Switch Onto Fault AlarmCLPU.Active Signal: ActiveCLPU.ExBlo Signal: External BlockingCLPU.Rvs Blo Signal: Reverse BlockingCLPU.enabled Signal: Cold Load enabledCLPU.detected Signal: Cold Load detectedCLPU.I< Signal: No Load Current.CLPU.Load Inrush Signal: Load InrushCLPU.Settle Time Signal: Settle TimeCLPU.ExBlo1-I Module Input State: External BlockingCLPU.ExBlo2-I Module Input State: External BlockingCLPU.Rvs Blo-I Module Input State: Reverse BlockingExP[1].Active Signal: ActiveExP[1].ExBlo Signal: External BlockingExP[1].Blo TripCmd Signal: Trip Command blockedExP[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandExP[1].Alarm Signal: AlarmExP[1].Trip Signal: Trip

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ETR-5000 IM02602013E

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ExP[1].TripCmd Signal: Trip CommandExP[1].ExBlo1-I Module Input State: External Blocking1ExP[1].ExBlo2-I Module Input State: External Blocking2ExP[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandExP[1].Alarm-I Module Input State: AlarmExP[1].Trip-I Module Input State: TripExP[2].Active Signal: ActiveExP[2].ExBlo Signal: External BlockingExP[2].Blo TripCmd Signal: Trip Command blockedExP[2].ExBlo TripCmd Signal: External Blocking of the Trip CommandExP[2].Alarm Signal: AlarmExP[2].Trip Signal: TripExP[2].TripCmd Signal: Trip CommandExP[2].ExBlo1-I Module Input State: External Blocking1ExP[2].ExBlo2-I Module Input State: External Blocking2ExP[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandExP[2].Alarm-I Module Input State: AlarmExP[2].Trip-I Module Input State: TripExP[3].Active Signal: ActiveExP[3].ExBlo Signal: External BlockingExP[3].Blo TripCmd Signal: Trip Command blockedExP[3].ExBlo TripCmd Signal: External Blocking of the Trip CommandExP[3].Alarm Signal: AlarmExP[3].Trip Signal: TripExP[3].TripCmd Signal: Trip CommandExP[3].ExBlo1-I Module Input State: External Blocking1ExP[3].ExBlo2-I Module Input State: External Blocking2ExP[3].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandExP[3].Alarm-I Module Input State: AlarmExP[3].Trip-I Module Input State: TripExP[4].Active Signal: ActiveExP[4].ExBlo Signal: External BlockingExP[4].Blo TripCmd Signal: Trip Command blockedExP[4].ExBlo TripCmd Signal: External Blocking of the Trip CommandExP[4].Alarm Signal: AlarmExP[4].Trip Signal: TripExP[4].TripCmd Signal: Trip CommandExP[4].ExBlo1-I Module Input State: External Blocking1ExP[4].ExBlo2-I Module Input State: External Blocking2

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IM02602013E ETR-5000

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ExP[4].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandExP[4].Alarm-I Module Input State: AlarmExP[4].Trip-I Module Input State: TripSudden Press.Active Signal: ActiveSudden Press.ExBlo Signal: External BlockingSudden Press.Blo TripCmd Signal: Trip Command blockedSudden Press.ExBlo TripCmd Signal: External Blocking of the Trip CommandSudden Press.Alarm Signal: AlarmSudden Press.Trip Signal: TripSudden Press.TripCmd Signal: Trip CommandSudden Press.ExBlo1-I Module Input State: External Blocking1Sudden Press.ExBlo2-I Module Input State: External Blocking2Sudden Press.ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandSudden Press.Alarm-I Module Input State: AlarmSudden Press.Trip-I Module Input State: TripExt Oil Temp.Active Signal: ActiveExt Oil Temp.ExBlo Signal: External BlockingExt Oil Temp.Blo TripCmd Signal: Trip Command blockedExt Oil Temp.ExBlo TripCmd Signal: External Blocking of the Trip CommandExt Oil Temp.Alarm Signal: AlarmExt Oil Temp.Trip Signal: TripExt Oil Temp.TripCmd Signal: Trip CommandExt Oil Temp.ExBlo1-I Module Input State: External Blocking1Ext Oil Temp.ExBlo2-I Module Input State: External Blocking2Ext Oil Temp.ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandExt Oil Temp.Alarm-I Module Input State: AlarmExt Oil Temp.Trip-I Module Input State: TripExt Temp Superv[1].Active Signal: ActiveExt Temp Superv[1].ExBlo Signal: External BlockingExt Temp Superv[1].Blo TripCmd Signal: Trip Command blockedExt Temp Superv[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandExt Temp Superv[1].Alarm Signal: AlarmExt Temp Superv[1].Trip Signal: TripExt Temp Superv[1].TripCmd Signal: Trip CommandExt Temp Superv[1].ExBlo1-I Module Input State: External Blocking1Ext Temp Superv[1].ExBlo2-I Module Input State: External Blocking2Ext Temp Superv[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandExt Temp Superv[1].Alarm-I Module Input State: AlarmExt Temp Superv[1].Trip-I Module Input State: Trip

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ETR-5000 IM02602013E

Name Description

Ext Temp Superv[2].Active Signal: ActiveExt Temp Superv[2].ExBlo Signal: External BlockingExt Temp Superv[2].Blo TripCmd Signal: Trip Command blockedExt Temp Superv[2].ExBlo TripCmd Signal: External Blocking of the Trip CommandExt Temp Superv[2].Alarm Signal: AlarmExt Temp Superv[2].Trip Signal: TripExt Temp Superv[2].TripCmd Signal: Trip CommandExt Temp Superv[2].ExBlo1-I Module Input State: External Blocking1Ext Temp Superv[2].ExBlo2-I Module Input State: External Blocking2Ext Temp Superv[2].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandExt Temp Superv[2].Alarm-I Module Input State: AlarmExt Temp Superv[2].Trip-I Module Input State: TripExt Temp Superv[3].Active Signal: ActiveExt Temp Superv[3].ExBlo Signal: External BlockingExt Temp Superv[3].Blo TripCmd Signal: Trip Command blockedExt Temp Superv[3].ExBlo TripCmd Signal: External Blocking of the Trip CommandExt Temp Superv[3].Alarm Signal: AlarmExt Temp Superv[3].Trip Signal: TripExt Temp Superv[3].TripCmd Signal: Trip CommandExt Temp Superv[3].ExBlo1-I Module Input State: External Blocking1Ext Temp Superv[3].ExBlo2-I Module Input State: External Blocking2Ext Temp Superv[3].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandExt Temp Superv[3].Alarm-I Module Input State: AlarmExt Temp Superv[3].Trip-I Module Input State: TripURTD.W1-A Superv Signal: Supervision Channel Winding1 Phase AURTD.W1-B Superv Signal: Supervision Channel Winding1 Phase BURTD.W1-C Superv Signal: Supervision Channel Winding1 Phase CURTD.W2-A Superv Signal: Supervision Channel Winding2 Phase AURTD.W2-B Superv Signal: Supervision Channel Winding2 Phase BURTD.W2-C Superv Signal: Supervision Channel Winding2 Phase CURTD.Amb1 Superv Signal: Supervision Channel Ambient1URTD.Amb2 Superv Signal: Supervision Channel Ambient2URTD.Aux1 Superv Signal: Supervision Channel Auxiliary1URTD.Aux2 Superv Signal: Supervision Channel Auxiliary2URTD.Aux3 Superv Signal: Supervision Channel Auxiliary3URTD.Aux4 Superv Signal: Supervision Channel Auxiliary4URTD.Superv Signal: URTD Supervision ChannelURTD.active Signal: URTD active

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IM02602013E ETR-5000

Name Description

URTD.Outs forced Signal: The State of at least one Relay Output has been set by force. That means that the state of at least one Relay is forced and hence does not show the state of the assigned signals.

RTD.Active Signal: ActiveRTD.ExBlo Signal: External BlockingRTD.Blo TripCmd Signal: Trip Command blockedRTD.ExBlo TripCmd Signal: External Blocking of the Trip CommandRTD.Alarm Alarm RTD Temperature ProtectionRTD.Trip Signal: TripRTD.TripCmd Signal: Trip CommandRTD.W1-A Trip Winding1 Phase A Signal: TripRTD.W1-A Alarm Winding1 Phase A Alarm RTD Temperature ProtectionRTD.W1-A Timeout Alarm Winding1 Phase A Timeout AlarmRTD.W1-A Invalid Winding1 Phase A Signal: Invalid Temperature Measurement


RTD.W1-B Trip Winding1 Phase B Signal: TripRTD.W1-B Alarm Winding1 Phase B Alarm RTD Temperature ProtectionRTD.W1-B Timeout Alarm Winding1 Phase B Timeout AlarmRTD.W1-B Invalid Winding1 Phase B Signal: Invalid Temperature Measurement


RTD.W1-C Trip Winding1 Phase C Signal: TripRTD.W1-C Alarm Winding1 Phase C Alarm RTD Temperature ProtectionRTD.W1-C Timeout Alarm Winding1 Phase C Timeout AlarmRTD.W1-C Invalid Winding1 Phase C Signal: Invalid Temperature Measurement


RTD.W2-A Trip Winding2 Phase A Signal: TripRTD.W2-A Alarm Winding2 Phase A Alarm RTD Temperature ProtectionRTD.W2-A Timeout Alarm Winding2 Phase A Timeout AlarmRTD.W2-A Invalid Winding2 Phase A Signal: Invalid Temperature Measurement


RTD.W2-B Trip Winding2 Phase B Signal: TripRTD.W2-B Alarm Winding2 Phase B Alarm RTD Temperature ProtectionRTD.W2-B Timeout Alarm Winding2 Phase B Timeout AlarmRTD.W2-B Invalid Winding2 Phase B Signal: Invalid Temperature Measurement


RTD.W2-C Trip Winding2 Phase C Signal: TripRTD.W2-C Alarm Winding2 Phase C Alarm RTD Temperature ProtectionRTD.W2-C Timeout Alarm Winding2 Phase C Timeout Alarm

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ETR-5000 IM02602013E

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RTD.W2-C Invalid Winding2 Phase C Signal: Invalid Temperature Measurement Value (e.g caused by an defective or interrupted RTD Measurement)

RTD.Amb 1 Trip Ambient 1 Signal: TripRTD.Amb 1 Alarm Ambient 1 Alarm RTD Temperature ProtectionRTD.Amb 1 Timeout Alarm Ambient 1 Timeout AlarmRTD.Amb 1 Invalid Ambient 1 Signal: Invalid Temperature Measurement Value (e.g

caused by an defective or interrupted RTD Measurement)RTD.Amb 2 Trip Ambient 2 Signal: TripRTD.Amb 2 Alarm Ambient 2 Alarm RTD Temperature ProtectionRTD.Amb 2 Timeout Alarm Ambient 2 Timeout AlarmRTD.Amb 2 Invalid Ambient 2 Signal: Invalid Temperature Measurement Value (e.g

caused by an defective or interrupted RTD Measurement)RTD.Aux 1 Trip Auxiliary 1 Signal: TripRTD.Aux 1 Alarm Auxiliary 1 Alarm RTD Temperature ProtectionRTD.Aux 1 Timeout Alarm Auxiliary 1 Timeout AlarmRTD.Aux 1 Invalid Auxiliary 1 Signal: Invalid Temperature Measurement Value (e.g



caused by an defective or interrupted RTD Measurement)RTD.Aux4 Trip Auxiliary 4 Signal: TripRTD.Aux4 Alarm Auxiliary 4 Alarm RTD Temperature ProtectionRTD.Aux4 Timeout Alarm Auxiliary 4 Timeout AlarmRTD.Aux4 Invalid Auxiliary 4 Signal: Invalid Temperature Measurement Value (e.g

caused by an defective or interrupted RTD Measurement)RTD.Trip WD W1 Group Trip all Windings of group W1RTD.Alarm WD W1 Group Alarm all Windings of group W1RTD.TimeoutAlmWDW1Grp Timeout Alarm of group W1RTD.WD W1 Group Invalid Winding W1 Group Signal: Invalid Temperature Measurement


RTD.Trip WD W2 Group Trip all Windings of group W2RTD.Alarm WD W2 Group Alarm all Windings of group W2RTD.TimeoutAlmWDW2Grp Timeout Alarm of group W2

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IM02602013E ETR-5000

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RTD.WD W2 Group Invalid Winding W2 Group Signal: Invalid Temperature Measurement Value (e.g caused by an defective or interrupted RTD Measurement)

RTD.Trip Amb Group Trip all Windings of group AmbientRTD.Alarm Amb Group Alarm all Windings of group AmbientRTD.TimeoutAlmAmbGrp Timeout Alarm of group AmbientRTD.Amb Group Invalid Ambient Group Signal: Invalid Temperature Measurement Value

(e.g caused by an defective or interrupted RTD Measurement)RTD.Trip Any Group Trip Any GroupRTD.Alarm Any Group Alarm Any GroupRTD.TimeoutAlmAnyGrp Timeout Alarm Any GroupRTD.Voting Trip Grp 1 Voting Trip Group 1RTD.Voting Trip Grp 2 Voting Trip Group 2RTD.Timeout Alarm Alarm timeout expiredRTD.Trip Aux Group Trip Auxiliary GroupRTD.Alarm Aux Group Alarm Auxiliary GroupRTD.TimeoutAlmAuxGrp Timeout Alarm Auxiliary GroupRTD.AuxGrpInvalid Invalid Auxiliary GroupRTD.ExBlo1-I Module Input State: External Blocking1RTD.ExBlo2-I Module Input State: External Blocking2RTD.ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandBF[1].Active Signal: ActiveBF[1].ExBlo Signal: External BlockingBF[1].Pickup Signal: BF-Module Started (Pickup)BF[1].Trip Signal: Breaker Failure TripBF[1].Lockout Signal: LockoutBF[1].Res Lockout Signal: Reset LockoutBF[1].ExBlo1-I Module Input State: External Blocking1BF[1].ExBlo2-I Module Input State: External Blocking2BF[1].Trigger1 Module Input: Trigger that will start the BFBF[1].Trigger2 Module Input: Trigger that will start the BFBF[1].Trigger3 Module Input: Trigger that will start the BFBF[2].Active Signal: ActiveBF[2].ExBlo Signal: External BlockingBF[2].Pickup Signal: BF-Module Started (Pickup)BF[2].Trip Signal: Breaker Failure TripBF[2].Lockout Signal: LockoutBF[2].Res Lockout Signal: Reset LockoutBF[2].ExBlo1-I Module Input State: External Blocking1BF[2].ExBlo2-I Module Input State: External Blocking2

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ETR-5000 IM02602013E

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BF[2].Trigger1 Module Input: Trigger that will start the BFBF[2].Trigger2 Module Input: Trigger that will start the BFBF[2].Trigger3 Module Input: Trigger that will start the BFTCM[1].Active Signal: ActiveTCM[1].ExBlo Signal: External BlockingTCM[1].Pickup Signal: Pickup Trip Circuit SupervisionTCM[1].Not Possible Not possible because no state indicator assigned to the breaker.TCM[1].CinBkr-52a-I Module Input State: Feed-back signal of the Bkr (52a)TCM[1].CinBkr-52b-I Module Input State: Feed-back signal of the Bkr. (52b)TCM[1].ExBlo1-I Module Input State: External Blocking1TCM[1].ExBlo2-I Module Input State: External Blocking2TCM[2].Active Signal: ActiveTCM[2].ExBlo Signal: External BlockingTCM[2].Pickup Signal: Pickup Trip Circuit SupervisionTCM[2].Not Possible Not possible because no state indicator assigned to the breaker.TCM[2].CinBkr-52a-I Module Input State: Feed-back signal of the Bkr (52a)TCM[2].CinBkr-52b-I Module Input State: Feed-back signal of the Bkr. (52b)TCM[2].ExBlo1-I Module Input State: External Blocking1TCM[2].ExBlo2-I Module Input State: External Blocking2CTS[1].Active Signal: ActiveCTS[1].ExBlo Signal: External BlockingCTS[1].Pickup Signal: Pickup Current Transformer Measuring Circuit SupervisionCTS[1].ExBlo1-I Module Input State: External Blocking1CTS[1].ExBlo2-I Module Input State: External Blocking2CTS[2].Active Signal: ActiveCTS[2].ExBlo Signal: External BlockingCTS[2].Pickup Signal: Pickup Current Transformer Measuring Circuit SupervisionCTS[2].ExBlo1-I Module Input State: External Blocking1CTS[2].ExBlo2-I Module Input State: External Blocking2LOP.Active Signal: ActiveLOP.ExBlo Signal: External BlockingLOP.Pickup Signal: Pickup Loss of PotentialLOP.LOP Blo Signal: Loss of Potential blocks other elementsLOP.ExBlo1-I Module Input State: External Blocking1LOP.ExBlo2-I Module Input State: External Blocking2ECr.Cr Oflw VAh Net Signal: Counter Overflow VAh NetECr.Cr Oflw Wh Net Signal: Counter Overflow Wh NetECr.Cr Oflw Wh Fwd Signal: Counter Overflow Wh FwdECr.Cr Oflw Wh Rev Signal: Counter Overflow Wh Rev

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IM02602013E ETR-5000

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ECr.Cr Oflw VArh Net Signal: Counter Overflow VArh NetECr.Cr Oflw VArh Lag Signal: Counter Overflow VArh LagECr.Cr Oflw VArh Lead Signal: Counter Overflow VArh LeadECr.VAh Net Res Cr Signal: VAh Net Reset CounterECr.Wh Net Res Cr Signal: Wh Net Reset CounterECr.Wh Fwd Res Cr Signal: Wh Fwd Reset CounterECr.Wh Rev Res Cr Signal: Wh Rev Reset CounterECr.VArh Net Res Cr Signal: VArh Net Reset CounterECr.VArh Lag Res Cr Signal: VArh Lag Reset CounterECr.VArh Lead Res Cr Signal: VArh Lead Reset CounterECr.Res all Energy Cr Signal: Reset of all Energy CountersECr.Cr OflwW VAh Net Signal: Counter VAh Net will overflow soonECr.Cr OflwW Wh Net Signal: Counter Wh Net will overflow soonECr.Cr OflwW Wh Fwd Signal: Counter Wh Fwd will overflow soonECr.Cr OflwW Wh Rev Signal: Counter Wh Rev will overflow soonECr.Cr OflwW VArh Net Signal: Counter VArh Net will overflow soonECr.Cr OflwW VArh Lag Signal: Counter VArh Lag will overflow soonECr.Cr OflwW VArh Lead Signal: Counter VArh Lead will overflow soonSysA.Active Signal: ActiveSysA.ExBlo Signal: External BlockingSysA.Alarm Watt Power Signal: Alarm WATTS peakSysA.Alarm VAr Power Signal: Alarm VArs peakSysA.Alarm VA Power Signal: Alarm VAs peakSysA.Alarm Watt Demand Signal: Alarm WATTS demand valueSysA.Alarm VAr Demand Signal: Alarm VARs demand valueSysA.Alarm VA Demand Signal: Alarm VAs demand valueSysA.Alm Current Demd Signal: Alarm Current demand valueSysA.Alarm I THD Signal: Alarm Total Harmonic Distortion CurrentSysA.Alarm V THD Signal: Alarm Total Harmonic Distortion VoltageSysA.Trip Watt Power Signal: Trip WATTS peakSysA.Trip VAr Power Signal: Trip VArs peakSysA.Trip VA Power Signal: Trip VAs peakSysA.Trip Watt Demand Signal: Trip WATTS demand valueSysA.Trip VAr Demand Signal: Trip VARs demand valueSysA.Trip VA Demand Signal: Trip VAs demand valueSysA.Trip Current Demand Signal: Trip Current demand valueSysA.Trip I THD Signal: Trip Total Harmonic Distortion CurrentSysA.Trip V THD Signal: Trip Total Harmonic Distortion VoltageSysA.ExBlo-I Module Input State: External Blocking

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ETR-5000 IM02602013E

Name Description

Wired Inputs.Bkr Trouble-I Breaker TroubleWired Inputs.52a M1-I State of the module input: Main 1 Breaker ClosedWired Inputs.52b M1-I State of the module input: Main 1 Breaker OpenWired Inputs.TOCa M1-I State of the module input: Main 1 Breaker Connected Wired Inputs.43/10 M1-I State of the module input: Main 1 Breaker Selected To Trip Wired Inputs.52a M2-I State of the module input: Main 2 Breaker ClosedWired Inputs.52b M2-I State of the module input: Main 2 Breaker OpenWired Inputs.TOCa M2-I State of the module input: Main 2 Breaker Connected Wired Inputs.43/10 M2-I State of the module input: Main 2 Breaker Selected To TripWired Inputs.52a T-I State of the module input: Tie Breaker ClosedWired Inputs.52b T-I State of the module input: Tie Breaker OpenWired Inputs.TOCa T-I State of the module input: Tie Breaker Connected Wired Inputs.43/10 T-I State of the module input: Tie Breaker Selected To TripWired Inputs.43 M-I State of the module input: System In ManualWired Inputs.43 A-I State of the module input: System in AutoWired Inputs.43 P1-I State of the module input: Preferred Source 1Wired Inputs.43 P2-I State of the module input: Preferred Source 2DI-8P X1.DI 1 Signal: Digital InputDI-8P X1.DI 2 Signal: Digital InputDI-8P X1.DI 3 Signal: Digital InputDI-8P X1.DI 4 Signal: Digital InputDI-8P X1.DI 5 Signal: Digital InputDI-8P X1.DI 6 Signal: Digital InputDI-8P X1.DI 7 Signal: Digital InputDI-8P X1.DI 8 Signal: Digital InputRO-4Z X2.ZI OUT Signal: Zone Interlocking OUTRO-4Z X2.RO 1 Signal: Relay OutputRO-4Z X2.RO 2 Signal: Relay OutputRO-4Z X2.RO 3 Signal: Relay OutputRO-4Z X2.RO 4 Signal: Relay OutputRO-4Z X2.DISARMED! Signal: CAUTION! RELAYS DISARMED in order to safely perform


RO-4Z X2.Outs forced Signal: The State of at least one Relay Output has been set by force. That means that the state of at least one Relay is forced and hence does not show the state of the assigned signals.

RO-4Z X5.ZI OUT Signal: Zone Interlocking OUTRO-4Z X5.RO 1 Signal: Relay OutputRO-4Z X5.RO 2 Signal: Relay Output

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IM02602013E ETR-5000

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RO-4Z X5.RO 3 Signal: Relay OutputRO-4Z X5.RO 4 Signal: Relay OutputRO-4Z X5.DISARMED! Signal: CAUTION! RELAYS DISARMED in order to safely perform


RO-4Z X5.Outs forced Signal: The State of at least one Relay Output has been set by force. That means that the state of at least one Relay is forced and hence does not show the state of the assigned signals.

RO-4 X5.RO 1 Signal: Relay OutputRO-4 X5.RO 2 Signal: Relay OutputRO-4 X5.RO 3 Signal: Relay OutputRO-4 X5.RO 4 Signal: Relay OutputRO-4 X5.DISARMED! Signal: CAUTION! RELAYS DISARMED in order to safely perform


RO-4 X5.Outs forced Signal: The State of at least one Relay Output has been set by force. That means that the state of at least one Relay is forced and hence does not show the state of the assigned signals.

AnIn[1].Broken wire Signal: Broken wire. This signal is only valid, if the analog input is used in the 4..20 mA mode.

AnIn[1].Input forced The value of analog Input has been set by force. That means that the value of the analog Input is forced and does not represent the real measured value.

AnIn[2].Broken wire Signal: Broken wire. This signal is only valid, if the analog input is used in the 4..20 mA mode.

AnIn[2].Input forced The value of analog Input has been set by force. That means that the value of the analog Input is forced and does not represent the real measured value.

Pres[1].Active Signal: ActivePres[1].ExBlo Signal: External BlockingPres[1].Blo TripCmd Signal: Trip Command blockedPres[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandPres[1].Pickup Signal: PickupPres[1].Trip Signal: TripPres[1].TripCmd Signal: Trip CommandPres[1].ExBlo1-I Module Input State: External Blocking1Pres[1].ExBlo2-I Module Input State: External Blocking2Pres[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandPres[2].Active Signal: ActivePres[2].ExBlo Signal: External BlockingPres[2].Pickup Signal: Pickup

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ETR-5000 IM02602013E

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Pres[2].Alarm AlarmPres[2].ExBlo1-I Module Input State: External Blocking1Pres[2].ExBlo2-I Module Input State: External Blocking2Tmp1[1].Active Signal: ActiveTmp1[1].ExBlo Signal: External BlockingTmp1[1].Blo TripCmd Signal: Trip Command blockedTmp1[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandTmp1[1].Pickup Signal: PickupTmp1[1].Trip Signal: TripTmp1[1].TripCmd Signal: Trip CommandTmp1[1].ExBlo1-I Module Input State: External Blocking1Tmp1[1].ExBlo2-I Module Input State: External Blocking2Tmp1[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandTmp1[2].Active Signal: ActiveTmp1[2].ExBlo Signal: External BlockingTmp1[2].Pickup Signal: PickupTmp1[2].Alarm AlarmTmp1[2].ExBlo1-I Module Input State: External Blocking1Tmp1[2].ExBlo2-I Module Input State: External Blocking2Tmp2[1].Active Signal: ActiveTmp2[1].ExBlo Signal: External BlockingTmp2[1].Blo TripCmd Signal: Trip Command blockedTmp2[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandTmp2[1].Pickup Signal: PickupTmp2[1].Trip Signal: TripTmp2[1].TripCmd Signal: Trip CommandTmp2[1].ExBlo1-I Module Input State: External Blocking1Tmp2[1].ExBlo2-I Module Input State: External Blocking2Tmp2[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandTmp2[2].Active Signal: ActiveTmp2[2].ExBlo Signal: External BlockingTmp2[2].Pickup Signal: PickupTmp2[2].Alarm AlarmTmp2[2].ExBlo1-I Module Input State: External Blocking1Tmp2[2].ExBlo2-I Module Input State: External Blocking2Vibr[1].Active Signal: ActiveVibr[1].ExBlo Signal: External BlockingVibr[1].Blo TripCmd Signal: Trip Command blockedVibr[1].ExBlo TripCmd Signal: External Blocking of the Trip Command

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IM02602013E ETR-5000

Name Description

Vibr[1].Pickup Signal: PickupVibr[1].Trip Signal: TripVibr[1].TripCmd Signal: Trip CommandVibr[1].ExBlo1-I Module Input State: External Blocking1Vibr[1].ExBlo2-I Module Input State: External Blocking2Vibr[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandVibr[2].Active Signal: ActiveVibr[2].ExBlo Signal: External BlockingVibr[2].Pickup Signal: PickupVibr[2].Alarm AlarmVibr[2].ExBlo1-I Module Input State: External Blocking1Vibr[2].ExBlo2-I Module Input State: External Blocking2VBat[1].Active Signal: ActiveVBat[1].ExBlo Signal: External BlockingVBat[1].Blo TripCmd Signal: Trip Command blockedVBat[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandVBat[1].Pickup Signal: PickupVBat[1].Trip Signal: TripVBat[1].TripCmd Signal: Trip CommandVBat[1].ExBlo1-I Module Input State: External Blocking1VBat[1].ExBlo2-I Module Input State: External Blocking2VBat[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandVBat[2].Active Signal: ActiveVBat[2].ExBlo Signal: External BlockingVBat[2].Pickup Signal: PickupVBat[2].Alarm AlarmVBat[2].ExBlo1-I Module Input State: External Blocking1VBat[2].ExBlo2-I Module Input State: External Blocking2TapV[1].Active Signal: ActiveTapV[1].ExBlo Signal: External BlockingTapV[1].Blo TripCmd Signal: Trip Command blockedTapV[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandTapV[1].Pickup Signal: PickupTapV[1].Trip Signal: TripTapV[1].TripCmd Signal: Trip CommandTapV[1].ExBlo1-I Module Input State: External Blocking1TapV[1].ExBlo2-I Module Input State: External Blocking2TapV[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandTapV[2].Active Signal: Active

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TapV[2].ExBlo Signal: External BlockingTapV[2].Pickup Signal: PickupTapV[2].Alarm AlarmTapV[2].ExBlo1-I Module Input State: External Blocking1TapV[2].ExBlo2-I Module Input State: External Blocking2AnaP[1].Active Signal: ActiveAnaP[1].ExBlo Signal: External BlockingAnaP[1].Blo TripCmd Signal: Trip Command blockedAnaP[1].ExBlo TripCmd Signal: External Blocking of the Trip CommandAnaP[1].Pickup Signal: PickupAnaP[1].Trip Signal: TripAnaP[1].TripCmd Signal: Trip CommandAnaP[1].ExBlo1-I Module Input State: External Blocking1AnaP[1].ExBlo2-I Module Input State: External Blocking2AnaP[1].ExBlo TripCmd-I Module Input State: External Blocking of the Trip CommandAnaP[2].Active Signal: ActiveAnaP[2].ExBlo Signal: External BlockingAnaP[2].Pickup Signal: PickupAnaP[2].Alarm AlarmAnaP[2].ExBlo1-I Module Input State: External Blocking1AnaP[2].ExBlo2-I Module Input State: External Blocking2AnOut[1].Force Mode For commissioning purposes or for maintenance, Analog Outputs

can be set by force. By means of this function the normal Analog Outputs can be overwritten (forced).

AnOut[2].Force Mode For commissioning purposes or for maintenance, Analog Outputs can be set by force. By means of this function the normal Analog Outputs can be overwritten (forced).

Event rec.Res all rec Signal: All records deletedWaveform rec.Recording Signal: RecordingWaveform rec.Memory full Signal: Memory FullWaveform rec.Clear fail Signal: Clear Failure in MemoryWaveform rec.Res all rec Signal: All records deletedWaveform rec.Res record Signal: Delete Record Waveform rec.Man. Trigger Signal: Manual TriggerWaveform rec.Start1-I State of the module input:: Trigger event / start recording if:Waveform rec.Start2-I State of the module input:: Trigger event / start recording if:Waveform rec.Start3-I State of the module input:: Trigger event / start recording if:Waveform rec.Start4-I State of the module input:: Trigger event / start recording if:Waveform rec.Start5-I State of the module input:: Trigger event / start recording if:Waveform rec.Start6-I State of the module input:: Trigger event / start recording if:Waveform rec.Start7-I State of the module input:: Trigger event / start recording if:

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Waveform rec.Start8-I State of the module input:: Trigger event / start recording if:Fault rec.Res record Signal: Delete Record Fault rec.Man. Trigger Signal: Manual TriggerFault rec.Start1-I State of the module input:: Trigger event / start recording if:Fault rec.Start2-I State of the module input:: Trigger event / start recording if:Fault rec.Start3-I State of the module input:: Trigger event / start recording if:Fault rec.Start4-I State of the module input:: Trigger event / start recording if:Fault rec.Start5-I State of the module input:: Trigger event / start recording if:Fault rec.Start6-I State of the module input:: Trigger event / start recording if:Fault rec.Start7-I State of the module input:: Trigger event / start recording if:Fault rec.Start8-I State of the module input:: Trigger event / start recording if:Trend rec.Hand Reset Hand ResetModbus.Transmission Signal: Communication ActiveModbus.Comm Cmd 1 Communication CommandModbus.Comm Cmd 2 Communication CommandModbus.Comm Cmd 3 Communication CommandModbus.Comm Cmd 4 Communication CommandModbus.Comm Cmd 5 Communication CommandModbus.Comm Cmd 6 Communication CommandModbus.Comm Cmd 7 Communication CommandModbus.Comm Cmd 8 Communication CommandModbus.Comm Cmd 9 Communication CommandModbus.Comm Cmd 10 Communication CommandModbus.Comm Cmd 11 Communication CommandModbus.Comm Cmd 12 Communication CommandModbus.Comm Cmd 13 Communication CommandModbus.Comm Cmd 14 Communication CommandModbus.Comm Cmd 15 Communication CommandModbus.Comm Cmd 16 Communication CommandIEC61850.VirtInp1 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp2 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp3 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp4 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp5 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp6 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp7 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp8 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp9 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp10 Signal: Virtual Input (IEC61850 GGIO Ind)

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IEC61850.VirtInp11 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp12 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp13 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp14 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp15 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtInp16 Signal: Virtual Input (IEC61850 GGIO Ind)IEC61850.VirtOut1-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut2-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut3-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut4-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut5-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut6-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut7-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut8-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut9-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut10-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut11-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut12-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut13-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut14-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut15-I Module input state: Binary state of the Virtual Output (GGIO)IEC61850.VirtOut16-I Module input state: Binary state of the Virtual Output (GGIO)IRIG-B.Active Signal: ActiveIRIG-B.Inverted Signal: IRIG-B invertedIRIG-B.Control Signal1 Signal: IRIG-B Control SignalIRIG-B.Control Signal2 Signal: IRIG-B Control SignalIRIG-B.Control Signal4 Signal: IRIG-B Control SignalIRIG-B.Control Signal5 Signal: IRIG-B Control SignalIRIG-B.Control Signal6 Signal: IRIG-B Control SignalIRIG-B.Control Signal7 Signal: IRIG-B Control SignalIRIG-B.Control Signal8 Signal: IRIG-B Control SignalIRIG-B.Control Signal9 Signal: IRIG-B Control SignalIRIG-B.Control Signal10 Signal: IRIG-B Control SignalIRIG-B.Control Signal11 Signal: IRIG-B Control SignalIRIG-B.Control Signal12 Signal: IRIG-B Control SignalIRIG-B.Control Signal13 Signal: IRIG-B Control SignalIRIG-B.Control Signal14 Signal: IRIG-B Control SignalIRIG-B.Control Signal15 Signal: IRIG-B Control SignalIRIG-B.Control Signal16 Signal: IRIG-B Control Signal

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IRIG-B.Control Signal17 Signal: IRIG-B Control SignalIRIG-B.Control Signal18 Signal: IRIG-B Control SignalSNTP.SNTP active Signal: If there is no valid SNTP signal for 120 sec, SNTP is

regarded as inactive.Statistics.ResFc all Signal: Resetting of all Statistic values (Current Demand, Power

Demand, Min, Max)Statistics.ResFc I Demand Signal: Resetting of Statistics - Current Demand (avg, peak avg)Statistics.ResFc P Demand Signal: Resetting of Statistics - Power Demand (avg, peak avg)Statistics.ResFc Max Signal: Resetting of all Maximum values Statistics.ResFc Min Signal: Resetting of all Minimum values Statistics.StartFc 1-I State of the module input: Start of Statistics 1 (Update the

displayed Demand )Statistics.StartFc 2-I State of the module input: Start of Statistics 2 (Update the

displayed Demand )Logic.LE1.Gate Out Signal: Output of the logic gateLogic.LE1.Timer Out Signal: Timer OutputLogic.LE1.Out Signal: Latched Output (Q)Logic.LE1.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE1.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE1.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE1.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE1.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE1.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE2.Gate Out Signal: Output of the logic gateLogic.LE2.Timer Out Signal: Timer OutputLogic.LE2.Out Signal: Latched Output (Q)Logic.LE2.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE2.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE2.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE2.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE2.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE2.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE3.Gate Out Signal: Output of the logic gateLogic.LE3.Timer Out Signal: Timer OutputLogic.LE3.Out Signal: Latched Output (Q)Logic.LE3.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE3.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE3.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE3.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE3.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE3.Reset Latch-I State of the module input: Reset Signal for the Latching

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Name Description

Logic.LE4.Gate Out Signal: Output of the logic gateLogic.LE4.Timer Out Signal: Timer OutputLogic.LE4.Out Signal: Latched Output (Q)Logic.LE4.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE4.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE4.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE4.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE4.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE4.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE5.Gate Out Signal: Output of the logic gateLogic.LE5.Timer Out Signal: Timer OutputLogic.LE5.Out Signal: Latched Output (Q)Logic.LE5.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE5.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE5.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE5.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE5.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE5.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE6.Gate Out Signal: Output of the logic gateLogic.LE6.Timer Out Signal: Timer OutputLogic.LE6.Out Signal: Latched Output (Q)Logic.LE6.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE6.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE6.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE6.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE6.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE6.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE7.Gate Out Signal: Output of the logic gateLogic.LE7.Timer Out Signal: Timer OutputLogic.LE7.Out Signal: Latched Output (Q)Logic.LE7.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE7.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE7.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE7.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE7.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE7.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE8.Gate Out Signal: Output of the logic gateLogic.LE8.Timer Out Signal: Timer OutputLogic.LE8.Out Signal: Latched Output (Q)

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Logic.LE8.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE8.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE8.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE8.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE8.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE8.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE9.Gate Out Signal: Output of the logic gateLogic.LE9.Timer Out Signal: Timer OutputLogic.LE9.Out Signal: Latched Output (Q)Logic.LE9.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE9.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE9.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE9.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE9.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE9.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE10.Gate Out Signal: Output of the logic gateLogic.LE10.Timer Out Signal: Timer OutputLogic.LE10.Out Signal: Latched Output (Q)Logic.LE10.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE10.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE10.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE10.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE10.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE10.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE11.Gate Out Signal: Output of the logic gateLogic.LE11.Timer Out Signal: Timer OutputLogic.LE11.Out Signal: Latched Output (Q)Logic.LE11.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE11.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE11.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE11.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE11.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE11.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE12.Gate Out Signal: Output of the logic gateLogic.LE12.Timer Out Signal: Timer OutputLogic.LE12.Out Signal: Latched Output (Q)Logic.LE12.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE12.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE12.Gate In2-I State of the module input: Assignment of the Input Signal

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Logic.LE12.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE12.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE12.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE13.Gate Out Signal: Output of the logic gateLogic.LE13.Timer Out Signal: Timer OutputLogic.LE13.Out Signal: Latched Output (Q)Logic.LE13.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE13.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE13.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE13.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE13.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE13.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE14.Gate Out Signal: Output of the logic gateLogic.LE14.Timer Out Signal: Timer OutputLogic.LE14.Out Signal: Latched Output (Q)Logic.LE14.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE14.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE14.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE14.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE14.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE14.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE15.Gate Out Signal: Output of the logic gateLogic.LE15.Timer Out Signal: Timer OutputLogic.LE15.Out Signal: Latched Output (Q)Logic.LE15.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE15.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE15.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE15.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE15.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE15.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE16.Gate Out Signal: Output of the logic gateLogic.LE16.Timer Out Signal: Timer OutputLogic.LE16.Out Signal: Latched Output (Q)Logic.LE16.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE16.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE16.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE16.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE16.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE16.Reset Latch-I State of the module input: Reset Signal for the Latching

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Logic.LE77.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE77.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE77.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE78.Gate Out Signal: Output of the logic gateLogic.LE78.Timer Out Signal: Timer OutputLogic.LE78.Out Signal: Latched Output (Q)Logic.LE78.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE78.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE78.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE78.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE78.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE78.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE79.Gate Out Signal: Output of the logic gateLogic.LE79.Timer Out Signal: Timer OutputLogic.LE79.Out Signal: Latched Output (Q)Logic.LE79.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE79.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE79.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE79.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE79.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE79.Reset Latch-I State of the module input: Reset Signal for the LatchingLogic.LE80.Gate Out Signal: Output of the logic gateLogic.LE80.Timer Out Signal: Timer OutputLogic.LE80.Out Signal: Latched Output (Q)Logic.LE80.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE80.Gate In1-I State of the module input: Assignment of the Input SignalLogic.LE80.Gate In2-I State of the module input: Assignment of the Input SignalLogic.LE80.Gate In3-I State of the module input: Assignment of the Input SignalLogic.LE80.Gate In4-I State of the module input: Assignment of the Input SignalLogic.LE80.Reset Latch-I State of the module input: Reset Signal for the LatchingSgen.Running Signal: Measuring value simulation is runningSgen.Ex Start Simulation-I State of the module input:External Start of Fault Simulation (Using

the test parameters)Sgen.ExBlo Module Input State: External BlockingSgen.Ex ForcePost-I State of the module input:Force Post state. Abort simulation.Sys.PS 1 Signal: Parameter Set 1Sys.PS 2 Signal: Parameter Set 2Sys.PS 3 Signal: Parameter Set 3Sys.PS 4 Signal: Parameter Set 4Sys.PSS manual Signal: Manual switch over of a Parameter Set

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Sys.PSS via Comm Signal: Parameter Set Switch via CommunicationSys.PSS via Inp fct Signal: Parameter Set Switch via Input FunctionSys.Min. 1 param changed Signal: At least one parameter has been changedSys.Program Mode Bypass Signal: Short-period bypass of the Program Mode.Sys.Maint Mode Active Signal: Arc Flash Reduction Maintenance ActiveSys.Maint Mode Inactive Signal: Arc Flash Reduction Maintenance InactiveSys.MaintMode Manually Signal: Arc Flash Reduction Maintenance Manual ModeSys.Maint Mode Comm Signal: Arc Flash Reduction Maintenance Comm ModeSys.Maint Mode DI Signal: Arc Flash Reduction Maintenance Digital Input ModeSys.Ack LED Signal: LEDs AcknowledgmentSys.Ack RO Signal: Acknowledgment of the Relay Output ContactsSys.Ack Comm Signal: Acknowledge CommunicationSys.Ack TripCmd Signal: Reset Trip CommandSys.Ack LED-HMI Signal: LEDs Acknowledgment :HMISys.Ack RO-HMI Signal: Acknowledgment of the Relay Output Contacts :HMISys.Ack Comm-HMI Signal: Acknowledge Communication :HMISys.Ack TripCmd-HMI Signal: Reset Trip Command :HMISys.Ack LED-Comm Signal: LEDs Acknowledgment :CommunicationSys.Ack RO-Comm Signal: Acknowledgment of the Relay Output Contacts

:CommunicationSys.Ack Counter-Comm Signal: Reset of all Counters :CommunicationSys.Ack Comm-Comm Signal: Acknowledge Communication :CommunicationSys.Ack TripCmd-Comm Signal: Reset Trip Command :CommunicationSys.Ack LED-I Module Input State: LEDs Acknowledgment by Digital Input.Sys.Ack RO-I Module Input State: Acknowledgment of the Relay Output

Contacts.Sys.Ack Comm-I Module Input State: Acknowledge Communication via Digital Input.

The replica that Communication has received from the device is to be reset.

Sys.PS1-I State of the module input, respectively of the signal, that should activate this Parameter Setting Group.




Sys.Maint Mode-I Module Input State: Arc Flash Reduction Maintenance Switch

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Special Assignment List for all Digital Input Signals and all Logic Outputs

Name Description

-.- No assignmentDI-8P X1.DI 1 Signal: Digital InputDI-8P X1.DI 2 Signal: Digital InputDI-8P X1.DI 3 Signal: Digital InputDI-8P X1.DI 4 Signal: Digital InputDI-8P X1.DI 5 Signal: Digital InputDI-8P X1.DI 6 Signal: Digital InputDI-8P X1.DI 7 Signal: Digital InputDI-8P X1.DI 8 Signal: Digital InputLogic.LE1.Gate Out Signal: Output of the logic gateLogic.LE1.Timer Out Signal: Timer OutputLogic.LE1.Out Signal: Latched Output (Q)Logic.LE1.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE2.Gate Out Signal: Output of the logic gateLogic.LE2.Timer Out Signal: Timer OutputLogic.LE2.Out Signal: Latched Output (Q)Logic.LE2.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE3.Gate Out Signal: Output of the logic gateLogic.LE3.Timer Out Signal: Timer OutputLogic.LE3.Out Signal: Latched Output (Q)Logic.LE3.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE4.Gate Out Signal: Output of the logic gateLogic.LE4.Timer Out Signal: Timer OutputLogic.LE4.Out Signal: Latched Output (Q)Logic.LE4.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE5.Gate Out Signal: Output of the logic gateLogic.LE5.Timer Out Signal: Timer OutputLogic.LE5.Out Signal: Latched Output (Q)Logic.LE5.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE6.Gate Out Signal: Output of the logic gateLogic.LE6.Timer Out Signal: Timer OutputLogic.LE6.Out Signal: Latched Output (Q)Logic.LE6.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE7.Gate Out Signal: Output of the logic gateLogic.LE7.Timer Out Signal: Timer OutputLogic.LE7.Out Signal: Latched Output (Q)Logic.LE7.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE8.Gate Out Signal: Output of the logic gate

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Name Description


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IM02602013E ETR-5000

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Logic.LE76.Out Signal: Latched Output (Q)Logic.LE76.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE77.Gate Out Signal: Output of the logic gateLogic.LE77.Timer Out Signal: Timer OutputLogic.LE77.Out Signal: Latched Output (Q)Logic.LE77.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE78.Gate Out Signal: Output of the logic gateLogic.LE78.Timer Out Signal: Timer OutputLogic.LE78.Out Signal: Latched Output (Q)Logic.LE78.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE79.Gate Out Signal: Output of the logic gateLogic.LE79.Timer Out Signal: Timer OutputLogic.LE79.Out Signal: Latched Output (Q)Logic.LE79.Out inverted Signal: Negated Latched Output (Q NOT)Logic.LE80.Gate Out Signal: Output of the logic gateLogic.LE80.Timer Out Signal: Timer OutputLogic.LE80.Out Signal: Latched Output (Q)Logic.LE80.Out inverted Signal: Negated Latched Output (Q NOT)

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ETR-5000 IM02602013E

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IM02602013E ETR-5000

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ETR-5000 IM02602013E

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IM02602013E ETR-5000

Instruction Leaflet IM02602013EEffective 3/6/12

ETR-5000

This instruction leaflet is published solely for information purposesand should not be considered all-inclusive. If further information isrequired, you should consult an authorized Eaton sales representative.

The sale of the product shown in this literature is subject to theterms and conditions outlined in appropriate Eaton selling policiesor other contractual agreement between the parties. This literature is not intended to and does not enlarge or add to any such contract.

The sole source governing the rights and remedies of any purchaser of this equipment is the contract between the purchaser and Eaton.

NO WARRANTIES, EXPRESSED OR IMPLIED, INCLUDING WARRANTIES OF FITNESS FOR A PARTICULAR PURPOSE OR MERCHANTABILITY, OR WARRANTIES ARISING FROM COURSE OF DEALING OR USAGE OF TRADE, ARE MADE REGARDING THE INFORMATION, RECOMMENDATIONS, AND DESCRIPTIONS CONTAINED HEREIN. In no event will Eaton be responsible to the purchaser or User in contract, in tort (including negligence), strict liability or otherwise for any special, indirect, incidental or consequential damage or loss whatsoever, including but not limited to damage or loss of use of equipment, plant or power system, cost of capital, loss of power, additional expenses in the use of existing power facilities, or claims against the purchaser or User by its customers resulting from the use of the information, recommendations and description contained herein.

Eaton CorporationElectrical Group1000 Cherrington ParkwayMoon Township, PA 15108United States877-ETN-CARE (877-386-2273)Eaton.com© 2012 Eaton CorporationAll Rights ReservedPrinted in USAPublication No. IM02602013E

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