p63x technicaldatasheet en 630a

VersionVersionVersionVersion: P63x -308 -40x -630 ff IssueIssueIssueIssue: A ReleaseReleaseReleaseRelease: 03 / 2011

MiCOMMiCOMMiCOMMiCOM P631/P632/P633/P634P631/P632/P633/P634P631/P632/P633/P634P631/P632/P633/P634 TranTranTranTransformer Differential sformer Differential sformer Differential sformer Differential ProtectionProtectionProtectionProtection

Technical Data SheetTechnical Data SheetTechnical Data SheetTechnical Data Sheet This document does not replace the Technical Manual

[[[[OneOneOneOne----Box Solutions for Protection and ControlBox Solutions for Protection and ControlBox Solutions for Protection and ControlBox Solutions for Protection and Control] ] ] ] MiCOM P63x 2

P63x_TechnicalDataSheet_EN_30_a Schneider Electric Energy P63x -308 -40x -630 ff

Application and scope

The differential protection devices of the MiCOM P63x series are intended for the fast and selective short-circuit protection of transformers, motors, generators and other installations with two, three or four windings, respectively.

The MiCOM P63x series provides high-speed three-system differential protection using a triple-slope characteristic and two high-set differential elements in combination with transformer inrush restraint, overfluxing restraint and through-stabilization. Amplitude and vector group matching is done just by entering the nominal values of transformer windings and associated CTs

.

For ring bus and breaker-and-a-half applications a virtual winding can be defined for which the current measuring inputs are based on the vector sum of currents from two or three freely selectable windings.

Phase swapping allows motor/generator protection applications with enlarged protection zones.

In addition many supplementary protective functions are incorporated in the devices. Protective functions which are available several times are freely assignable to the windings.

The MiCOM P63x provide four setting groups for easy adaptation to varying system operation conditions.

P631 P632 P633 P634

ANSIANSIANSIANSI IEC 61850IEC 61850IEC 61850IEC 61850Function Function Function Function

groupgroupgroupgroupFunctionFunctionFunctionFunction

87T PhsPDIF1 DIFF Differential protection, phase selective 2 wind. 2 wind. 3 wind. 4 wind.

87N REF_x Restricted earth-fault protection - 2 3 3

50TD

P/Q/N

DtpPhs-/DtpEft-/

DtpNgsPTCOxDTOCx

Definite-time overcurrent protection, 3 stages,

phase-, neg.-sequ.-, residual/starpoint-OC2 2 3 3

51P/Q/NItpPhs-/ItpEft-/

TtpNgsPTCOxIDMTx

Inverse-time overcurrent protection, 1 stage,

phase-, neg.-sequ.-, residual/starpoint-OC2 2 3 3

49 ThmPTTR1 THRMx Thermal overload protection 1 1 2 2

27/59

P/Q/N

VtpPhs-/VtpNgs-/

VtpPss-/VtpRefPTyVx

V<> Over/Undervoltage protection- 1 1 1

81 f<> Over/Underfrequency protection> - 1 1 1

24 V/f Overexcitation protection - 1 1 1

50BF RBRFx CBF_x Circuit breaker failure protection - 2 3 4

CTS Current transformer supervision - 1 1 1

30/74 AlmGGIO1 MCM_x Measuring circuit monitoring 2 2 3 4

LIMIT/LIM_x Limit value monitoring 2 2 3 3

LGC PloGGIOx LOGIC Programmable logic • • • •Measuring inputs

Phase currents 2 x 3 2 x 3 3 x 3 4 x 3

Residual current or star-point current - 2 3 3

Voltage - 1 1 1

Binary inputs and outputs

INP Optical coupler inputs 4 4 … 10 4 … 16 4 … 10

INP Add. optical coupler inputs - 24 24 24

OUTP Output relays 8 … 14 8 … 22 8 … 30 8 … 22

FKEY Function keys 4 4 4 4

Analog inputs and outputs ( • ) ( • ) ( • ) ( • )26 RtdGGIO1 RTD input ( • ) ( • ) ( • ) ( • )

IdcGGIO1 1x Measuring data input 20 mA ( • ) ( • ) ( • ) ( • )2 x Measuring data output 20 mA ( • ) ( • ) ( • ) ( • )

LLN0.SGCB PSS Parameter subset selection • • • •PTRCx/ RDRE1 FT_RC Fault recording • • • •

52 XCBRx, XSWIx,CSWIx DEVxx Control and monitoring of switchgear units − (3) (3) -

CMD_1 Single-pole commands − (12) (12) -

SIG_1 Single-pole signals − (12) (12) -

LGC ILOCK Interlocking logic − ( • ) ( • ) -

16S COMMx2 Communication interfaces, serial,

RS 422/485 or FO ( • ) ( • ) ( • ) ( • )

CLK IRIGB Time synchronisation IRIG-B ( • ) ( • ) ( • ) ( • )

16E IECEthernet Communication interface

per IEC 61850, RJ 45 or FO ( • ) ( • ) ( • ) ( • )

GosGGIOx GOOSE GOOSE Communication ( • ) ( • ) ( • ) ( • )

• = STANDARD; ( • ) = ORDER OPTION

Functional overview

MEASI/

MAESO



All main functions are individually configurable. The user can adapt the device flexibly to the scope of protection required in each particular application.

Due to the powerful, freely configurable logic of the device, special applications can be accommodated.

MiCOM P63x optionally provide in addition to the protection functions the control and supervision functionality for the circuit breaker in the switch bay.

Over 80 predefined bay types are provided for simple efficient configuration of switchgear control functions. With using the control functionality the download of customized bay type can be used too.

External auxiliary devices are largely obviated through the integration of binary inputs and power outputs that are independent of auxiliary voltages, by the direct connection option for current and voltage transformers and by the comprehensive interlocking capability. This simplifies handling of the protection and control technology for a switch bay from planning to final commissioning.

24

V/f

27/59

V<>

81

f<>

IY,b

IY,a

IY,c

V

IP,a

IP,b

IP,c

IP,d

Ivirtual

87

DIFF

49

THRM1

49

THRM2

51

IDMT1

51

IDMT2

51

IDMT3

50

DTOC2

50

DTOC3

87G

REF_1

87G

REF_3

Function diagram

Metering

LIM_1

Overload rec.

Self Monitoring

LIM_2LIM_3

Fault rec.

LGC

ILOCK

Communication

to SCADA / substation control / RTU / modem ...

via RS485 or Fiber optics

using IEC 60870-5-101, -103, Modbus, DNP3, Courier

resp.

via RJ45 or Fiber optics using IEC 61850

16S

COMM1

16S

COMM2

16E

IEC

52

DEV

CLK

IRIGB

CMD_1SIG_1

26

MEASI MEASOTransformer Differential Protection

MiCOM P631/ P632/ P633/ P634

Always availableOptional

LIMIT

50

DTOC1

87G

REF_2

50/62BF

CBF_2

50/62BF

CBF_1

50/62BF

CBF_3

50/62BF

CBF_4

MCM_4MCM_3MCM_2MCM_1

CTS

Control and

Monitoring

of up to 3

switchgear units

Recording and

Data Acquisition

LGC

LOGIC



In addition to the listed functions, as well as comprehensive self monitoring, the following global functions are available in the MiCOM P63x:

• Parameter subset selection (4 independent parameter subsets)

• Measured operating data to support the user during commissioning, testing and operation

• Operating data recording (time-tagged signal logging)

• Overload data acquisition

• Overload recording (time-tagged signal logging)

• Fault data acquisition

• Fault recording (time-tagged signal logging together with fault value recording of the measured phase currents, the neutral/starpoint currents and the voltage).

Design

The MiCOM P63x is of modular design. The pluggable modules are housed in a robust aluminium case and electrically connected via an analog and a digital bus printed circuit board.

The nominal currents or the nominal voltages, respectively, of the measuring inputs can be set with the help of function parameters.

The nominal voltage range of the standard optical coupler inputs is 24 to 250 V DC without internal switching. Optional there are also other ranges with higher pick-up thresholds possible.

All output relays are suitable for both signals and commands.

Besides the standard output relays optionally high speed static trip or high break contacts could be chosen.

The auxiliary voltage input for the power supply is a wide-range design as well. Two selectable versions are available for different nominal voltage ranges in the substation.

The optional 0 to 20 mA input provides open-circuit and overload monitoring, zero suppression defined by a setting, plus the option of linearizing the input variable via 20 adjustable interpolation points.

Two freely selected measured signals (cyclically updated measured operating data and stored measured fault data) can be output as a load-independent direct current via the two optional 0 to 20 mA outputs. The characteristics are defined via 3 adjustable interpolation points allowing a minimum output current (4 mA, for example) for receiver-side open-circuit monitoring, knee-point definition for fine scaling and a limitation to lower nominal currents (10 mA, for example). Where sufficient output relays are available, a freely selected measured variable can be output in BCD-coded form via contacts.

Control and display

• Local control panel with LC-display (4 x 20 alphanumerical characters)

• MiCOM navigation keys

• 6 function keys

• 23 LED indicators, 18 of which allow freely configurable function assignment for red, green or yellow visualization.

• PC interface.

Function keys

MiCOM P63x have six freely configurable function keys. A single function can be assigned to each function key. So circuit breakers and functions can be switched on or off and recorded information can be reset directly via function key.

Instead of a single function, a menu jump list with up to 16 elements can be assigned. Setting parameters, event counters and/or event records can be selected into a menu list. Repeated pressing of the relevant function key will then sequentially trigger the element of the selected menu jump list.

For each function key, the user can define an operating mode suitable to the assigned functionality.

To guard against inadvertent or unauthorized use each function key could be protected with a password.

40TE and 84TE Case options



Detachable HMI

For remote mounting in switchgears the MiCOM P63x can be equipped with a detachable HMI. This design has the advantage of a comfortable device handling even in switch gears with protection arrangements difficult to access.

Detachable HMI mounted a MV switchgear

The design of MiCOM P63x allows a connection or disconnection to the detachable HMI at any time. The HMI hardware module will be completely and automatically recognized.

The visualisation of the device status is done via the display of the HMI and via 4 LED`s at the basic device.

Even if the detachable HMI is not connected all device functions are completely warranted. With a connected HMI the PC-interface of the device cannot be used.

To connect the basic device and the detachable HMI standardised cable (Ethernet cable, max. length 10 m) can be used. One connection cable of three meter length is included in the MiCOM P63x scope of delivery.

Basic device with detachable HMI

Communication interfaces (Optional)

Information exchange is done via the local control panel, the PC interface and 2 optional communication interfaces.

The first communication interfaces is intended for integration of MiCOM P532 with substation control systems. This interface is provided either as a switchable serial protocol (IEC 60870-5-103, IEC 60870-5-101, DNP 3.0, Courier or Modbus), or as an Ethernet communication interface using IEC 61850.

The 2nd communication interface (COMM2) conforms to IEC 60870-5-103 and is intended for remote setting access only.

External time synchronization can be done using a configured binary input, using one of the communication protocols or by using the optional IRIG-B signal input.



Main functions

Main functions are autonomous function groups and can be individually configured or disabled to suit a particular application. Function groups that are not required and have been disabled by the user are masked completely (except for the configuration parameter) and functional support is withdrawn from such groups.

This concept permits an extensive scope of functions and universal application of the protection device in a single design version, while at the same time providing for a clear and straight-forward setting procedure and adaptation to the protection task under consideration.

Differential Protection

Amplitude Matching

On the basis of the primary transformer currents, the MiCOM P63x differential protection devices can be flexibly adapted to the reference currents of the protected object. Amplitude matching is by means of a straight-forward input of the reference power common to all windings plus the nominal voltages and the nominal transformer currents for each winding. The resulting reference currents and matching factors are automatically deduced by the device and checked for compatibility with the internally allowed value ranges.

Vector Group Matching and Zero-Sequence Filtering

Matching of the MiCOM P63x series differential protection devices to the vector group of the protected object is via a straight-forward input of the relevant vector group identification number.

The mathematical formula to be applied to the measured values is automatically selected internally according to the relevant vector group and zero-sequence filtering is taken into account simultaneously. For special applications, zero-sequence filtering may be deactivated separately for each winding.

Tripping Characteristic

The tripping characteristic of the differential protection device has two knees (see Figure 4). The first knee is dependent on the setting of the basic threshold value Id> and is on the load line for single-side feed. The second knee of the tripping characteristic is defined by a setting. Above the user-selected differential current level Id>>>, the restraining current is no longer taken into account.

Through Fault Stabilization

Up to a certain limit, stability in the event of external faults is ensured by means of the bias. Due to the triple-slope tripping characteristic, the stabilization is particularly pronounced for high currents. However, as an additional safeguard for through-currents with transformer saturation, the MiCOM P63x series differential protection devices are provided with a saturation discriminator. Particularly the start-up of directly switched asynchronous motors represents a problem in differential protection due to transient transformer saturation caused by a displacement of the start-up current for relatively high primary time constants. Even under such unfavourable measurement conditions, the MiCOM P63x series differential protection devices perform with excellent stability.



Harmonic Restraint

Stabilization under inrush conditions is based on the presence of second harmonic components in the differential currents. The ratio of the second harmonic component to the fundamental wave for the differential currents of the measuring system serves as the criterion. Optionally, tripping is blocked either across all three measuring systems or selectively for one measuring system. However, from a user-selected differential current level Id>>, the blocking criterion is no longer taken into account. For application as differential protection device for motors or generators, the harmonic restraint can be deactivated.

Overfluxing Restraint

For stabilization under overfluxing conditions, the ratio of the fifth harmonic to the fundamental wave for the differential currents of the measuring system serves as criterion. Tripping is blocked selectively for each measuring system. For differential currents of 4>Iref or higher, the blocking criterion is no longer taken into account. The overfluxing restraint function may be deactivated, if not needed in the application (e.g. mesh-corner or shunt-reactor protection).

Trip time

Differential tripping could be definite time delayed to allow seelctive operation of overlapping differential protection zones.

Restricted Earth Fault Protection

Restricted earth fault protection (REF) is applied on transformers in order to detect ground-faults on a given winding more sensitively than overall transformer differential protection is able to do. The advantage of restricted earth fault protection resides in the linear dependency of the sensitivity on the distance between the fault and the neutral point.

Two different measuring principles are available:

• Biased restricted earth fault protection

• High impedance restricted earth fault protection.

The biased restricted earth fault protection can be applied to transformer windings with grounded neutral point where the neutral point/ground connection is fitted with a current transformer. It is based on comparing the vector sum of the phase currents of the relevant transformer winding to the neutral point current. The vector sum of the phase currents is internally calculated, including amplitude matching for phase and starpoint CT’s.

The first REF function could be used as wrap-around protection of auto-transformers or, in general, electrically-connected multiple end configurations.

REF could be blocked by setting in case overall differential protection picks up, thus stabilizing could be enforced for heavy through fault current conditions.



Overcurrent protection

The overcurrent protection functions operate with separate measuring systems for the evaluation of the three phase currents, the negative-sequence current and the residual current. The negative-sequence current is determined from the filtered fundamental component of the three phase currents. The residual current is obtained either from the fourth current input or from the internal vector addition of the three phase currents, depending on the user’s choice.

The residual and negative-sequence currents stages affect the general starting signal. This effect can be suppressed if desired.

Additionally, the operate values of all overcurrent stages can be set as dynamic parameters. For a settable hold time, switching to the dynamic operate values can be done via an external signal. Once the hold time has elapsed, the static operate values are reinstated.

Starting of some phase current stages and the negative-sequence current stages can be inrush stabilized, if desired. The blocking signals of the inrush stabilization function of differential protection are selective to the measuring system. These signals are linked by OR operators to obtain the criterion for stabilization. As a consequence, stabilization is always effective across all three phases.

Definite time overcurrent protection

Three stages each are provided for the three phase measuring systems. Each stage of the phase current-related measuring system operates with phase-selective starting.

Inrush stabilisation could be enabled for the phase current stage I> and the negative-sequence current stage Ineg>, if required. All other phase current stages, the negative-sequence current stages and all residual current stages are not affected by the stabilization.

Inverse time overcurrent protection

The inverse-time overcurrent protection operates with single-stage. The timer stage of the phase-current-related measuring system operates with phase-selective starting.

For the individual measuring systems, the user can select from a multitude of tripping characteristics.

Inrush stabilisation could be enabled for the phase current stage and the negative-sequence current stage, if required.

Intermittent startings of the phase, negative sequence or residual current stage can be accumulated on the basis of the set tripping

characteristic by means of a settable hold time. Tripping is also performed in accordance with the relevant tripping characteristic.

Thermal overload protection

Using this function, thermal overload protection for lines, transformers and stator windings of h.v. motors can be realized. The highest of the three phase currents serves to track a first-order thermal replica according to IEC 255-8.

The tripping time is determined by the set thermal

time constant τ >of the protected object and the set

tripping level ∆ϑtrip and depends on the

accumulated thermal load ∆ϑ0:

The temperature of the cooling medium can be taken into account in the thermal replica using the optional resistance temperature inputs or the 0 to 20 mA input.

The user has a choice of using a thermal replica on the basis of either relative or absolute temperature.

A warning signal can be issued in accordance with

the set warning level ∆ϑ warning. As an alternative method of generating a warning, the cyclically updated measured operating value of the predicted time remaining before tripping is monitored to check whether it is falling below a set threshold.

No Tripping time characteristic

(k= 0.01 … 10.00)(k= 0.01 … 10.00)(k= 0.01 … 10.00)(k= 0.01 … 10.00) AAAA BBBB CCCC RRRR

0000 Definite Time

per IEC 255-3

1111 Normally inverse 0,14000 0.02000

2222 Very inverse 13.50000 1.00000

3333 Extremely inverse 80.00000 2.00000

4444 Long time inverse 120.00000 1.00000

per ANSI / IEEE C37.112 TripTripTripTrip ReleaseReleaseReleaseRelease

5555 Moderately inverse 0.05150 0.02000 0.11400 4.85000

6666 Very inverse 19.61000 2.00000 0.49100 21.60000

7777 Extremly inverse 28.20000 2.00000 0.12170 29.10000

per ANSI TripTripTripTrip ReleaseReleaseReleaseRelease

8888 Normally inverse 8.93410 2.09380 0.17966 9.00000

9999 Short time inverse 0.26630 1.29690 0.03393 0.50000

10101010 Long time inverse 5.61430 1.00000 2.18592 15.75000

not per standard

11111111 RI-type inverse

not per standard

12121212 RXIDG-type inverse

Constants and formulae (t in s)

kt =

1I

I

Akt

B

B

−

⋅=

−

−

⋅= C

1I

I

Akt

B

B

1I

I

Rkt

B

B

r

−

⋅=

−

⋅=

BI

I

236.0339.0

1kt

⋅−⋅=

BI

Iln35.18.5kt



Over-/Undervoltage Protection

The over-/undervoltage protection function evaluates the fundamental component of the voltage by way of two definite-time overvoltage and undervoltage stages each.

Over-/Underfrequency Protection

Over-/underfrequency protection has four stages. Each of these can be operated in one of the following modes:

• Over-/underfrequency monitoring

• Over-/underfrequency monitoring combined with differential frequency gradient monitoring (df/dt) for system decoupling applications

• Over-/underfrequency monitoring combined with medium frequency gradient monitoring

(∆f/∆t) for load shedding applications

Overexcitation Protection

Overexcitation protection detects impermissible high magnetic flux density in the iron core of power transformers which can occur in case of increase in voltage and/or decrease in frequency. Flux density above the rated value saturates the iron core which may result in power transformer overheating due to large iron losses.

Overexcitation protection processes the voltage to frequency ratio (V/f) in relation to their nominal values. The inverse-time characteristic may be set via 12 value pairs and therefore enables accurate adaptation to power transformer data. In addition a definite-time alarm stage and a definite-time tripping stage are available.

Circuit breaker failure protection

A total of up to 4 circuit breaker functions are provided, to provide this functionality for the circuit breaker on each end separately.

With either the internal or an external trip command, two timer stages are started for the monitoring of the circuit breaker action. If the first timer elapses while the fundamental of the phase current stays above a settable threshold, a 'circuit breaker failure' condition is determined and a re-trip command (e.g. to the 2

nd breaker trip coil) can

be issued.

Upon elapsing of the 2nd

timer stage, a back-trip command can be issued to trip the upstream breaker.

Optionally the measured neutral or calculated residual current could be used as further criterion to determine CB open condition.

If a downstream ‘circuit breaker failure' condition gets signalled via an appropriately configured binary input, while the local general starting is present (as check condition), an instantaneous or definite time delayed trip signal is issued.

Also stub bus protection and pole discrepancy supervision are available as part of CB failure protection function.

...

1.00 1.10 1.20 1.30 1.40 1.50

1

10

100

V/f>>>

V/f>>

...

Characteristics of the overexcitation protection

V/f

Vnom/fnom

t/[s]



Measuring Circuit Monitoring

The measuring circuit monitoring of the MiCOM P63x detects and signals unsymmetrical phase-currents, related to each protected winding end. Each MCM_x is linked to one winding. It may be used as a back-up ‘broken conductor’ protection of the associated feeder.

The monitoring criterion is the ratio of the negative to the positive sequence current. The function operates if the set ratio Ineg/Ipos is exceeded and the positive or the negative sequence current value exceeds 0.02 Inom. After a set time delay a warning signal will be raised.

Current Transformer Supervision (Optional)

The current transformer supervision (CTS) feature is used to detect failure of one or more of the AC phase current inputs to the relay. Failure of a phase CT or an open circuit of the secondary wiring can lead to incorrect operation of current based protection elements. Additionally, interruption of the CT secondary wiring can induce high voltages presenting a danger to life and insulation. The patent pending CTS scheme is designed on the measurement of the negative and positive sequence current levels at all line ends. The advantage of this scheme is that no additional CT or VT inputs are needed aside from those necessary for biased differential protection, therefore further secondary equipment and wiring is not required. Only for the increased computing power the protection device needs an additional coprocessor module.

The technique used allows application of CTS to any differential protection scheme. Operation is independent of the primary power system configuration, unaffected by transformer winding configuration, load levels, methods of earthing and the like.

CT failure is detected if

• Positive sequence current is above set threshold in at least two ends (current measured at one end only indicates a single-end fed internal fault or a low-load condition, in either case CTS must not operate), and

• High negative sequence current is measured at exactly one end with none or only low levels measured in all other ends.

As soon as a CT failure condition is detected, the function will raise the low set threshold of the differential protection, Idiff>, to the set Idiff>(CTS). This threshold should be set above maximum load current to ensure differential protection will not operate under load conditions, but remains active for higher short-circuit currents, which is predominantly the case for internal faults.

CT failure condition signaling can be delayed by a settable delay timer to prevent signaling under transient system conditions. The signals may be latched once the failure condition has been present for a set minimum time. Signals for each end can be used to selectively block the restricted earth fault (REF) protection associated to that end.



Limit monitoring

A multitude of currents, the voltage and the measured temperature are monitored to aid operation of the protected line. This function is not intended to be used for protection purposes, as it has an inherent 1 second delay.

E.g. for the 3-phase currents and the voltage the highest and the lowest value is determined. These are evaluated using an operate value and time delay set by the user. Thereby, these currents and the voltage can be monitored for exceeding an upper limit or falling below a lower limit.

Measured Data Input (optional)

The optional analog I/O module provides a 0 to 20 mA input fort he acquisition of externally measured variables such as transducer outputs. The external input characteristics can be linearized via adjustable interpolation points. This feature also provides for an adaption of the range to, for example, 4 to 20 mA or 0 to 10 mA.

The measured variables acquired by the analog measured data input function are monitored for exceeding or falling below set limits. Furthermore, they are used by thermal overload protection function for the acquisition of the coolant temperature.

Measured Data Output

The protection device provides the options of operating data output a n fault data output. The user can select an output in BCD-coded form through relay contacts or an output in analog form as load-independent current (0 to 20 mA). For an output in BCD-coded form, an appropriate number of free output relays needed to be available. For the current output, a special analog I/O module is required.



Programmable Logic

User-configurable logic enables the user to set up logic operations on binary signals within a framework of Boolean equations. By means of a straightforward configuration procedure, any of the signals of the protection device can be linked by logic ‘OR’ or ‘AND’ operations with the possibility of additional negation operations.

The output signal of an equation can be fed into a further, higher-order equation as an input signal thus leading to a set of interlinked Boolean equations.

The output signal of each equation is fed to a separate timer stage with two timer elements each and a choice of operating modes. Thus the output signal of each equation can be assigned a freely configurable time characteristic.

The two output signals of each equation can be configured to each available input signal after logic OR linking. The user-configurable logic function is then able to influence the individual functions without external wiring (block, reset, trigger, for example).

Via non-storable continuous signals, monostable trigger signals and bistable setting/resetting signals, the Boolean equations can be controlled externally via any of the device’s interfaces.

Programmable logic

Output

signalsFunction groups

Spec. application

(programmable)

LOGIC

HMI

INP

F_KEY

PC

COMM1

COMM2

GOOSE

Fixed device logic

DIFF, REF, DTOC,

IDMT, THERM, ...

Input

signals

HMI

OUTP

LED

PC

COMM1

COMM2

GOOSE

Control functions (optional)

Control functions are optionally available with MiCOM P632 and P633, if the binary I/O module X (6I/6O) and a communication module (with options -92x or -94x) is fitted.

Control functions are designed for the control of up to 3 electrically operated switchgear units equipped with electrical check-back signaling.

For the control of switchgear units either the binary inputs or the optional communication interface or the function keys of the local control panel can be used.

Control panel at the text HMI

Up to 12 single-pole operating signals can be acquired and processed in accordance with their significance for the substation (circuit breaker readiness, for example). For the setting of the debounce and chattering times, 3 independent setting groups are available. These can be assigned to the switching position signaling inputs and single-pole operating signals.

The MICOM P63x issues switching command outputs with the integration of switching readiness and permissibility tests; subsequently the MiCOM P63x monitors the intermediate position times of the switchgear units. If a switchgear malfunction is detected, this fact will be indicated (e.g. by an appropriately configured LED indicator).



Before a switching command output is executed, the interlocking logic of the MiCOM P63x will check whether the new switchgear unit state corresponds to a permissible bay or substation topology. The interlocking logic is set out for each bay in the default setting as bay interlock with and without station interlock. By means of a straight-forward parameter setting procedure, the interlocking equations can be adapted to the prevailing bay and substation topology. The presentation and functioning of the interlocking system correspond to those of the programmable logic.

For integration of the MiCOM P63x into integrated control systems, the equations for the bay interlock with station interlock form the basis of interlock checking.

Without integration into the substation control system or with integration using IEC 61850, the bay interlock without station interlock is used in interlock checking; external ring feeders or signals received via IEC 61850 may be included in the interlocking logic.

If the bay or station topology (as applicable) is permissible then the switching command is issued. If a non-permissible state would result from the switching operation then the switching command is rejected and a signal to this effect is issued.

If the bay type does not require all binary outputs then the remaining outputs are available for free configuration.

In addition to the switching command output, a triggering of binary outputs by continuous commands is possible.

Global Functions

Functions operating globally allow the adaptation of the device’s interfaces to the protected power system, offer support during commissioning and testing and provide continuously updated information on the operation, as well as valuable analysis results following events in the protected system.

Clock synchronization

The device incorporates an internal clock with a resolution of 1ms. All events are time-tagged based on this clock, entered in the recording memory appropriate to their significance and signaled via the communication interface.

Alternatively two external synchronization signals can be used according to the selected communication protocol: using one of the protocols Modbus, DNP3, IEC 60870-5-103, IEC 60870-5-101 or IEC 61850 the device will be synchronized by a time telegram from a higher-level substation control system. With IEC 61850 communication time synchronizations can be done using SNTP services.

In any other case it will be synchronized using the IRIG-B signal input. The internal clock will then be adjusted accordingly and operate with an accuracy of ±10 ms if synchronized via protocol and ±1ms if synchronized via IRIG-B signal.

Parameter subset selection

Function parameters for setting the protection functions are, to a large extent, stored in four independent parameter subsets. Switching between these subsets is readily achieved via any of the device's interfaces.

Operating data recording

For the continuous recording of processes in system operation or of events, a non-volatile ring memory for up to 128 entries is provided. The relevant signals, each fully tagged with date and time at signal start and signal end, are entered in chronological sequence. Included are control actions such as the enabling or disabling of functions as well as local control triggering for testing and resetting. The onset and end of events in the network, as far as these represent a deviation from normal operation (overload or short-circuit, for example) are recorded.



Overload data acquisition

Overload situations in the network represent a deviation from normal system operation and can be permitted for a brief period only. The overload protection functions enabled in the device recognize overload situations in the system and provide for acquisition of overload data such as the magnitude of the overload current, the relative heating during the overload situation and its duration.

Overload recording

While an overload condition persists in the network, the relevant signals, each fully tagged with date and time at signal start and signal end, are entered into a non-volatile memory in chronological sequence. The measured overload data, fully tagged with the date and time of acquisition, are also entered.

Up to eight overload situations can be recorded. If more than eight overload situations occur without interim memory clearance then the oldest overload recording is overwritten.

Fault data acquisition

A short-circuit within the network is described as a fault. The acquisition of the measured fault data is determined by the triggering protection function. Beside neutral and phase currents also the differential and restraining currents of all 3 measuring systems of the differential and of restricted earth-fault protection are provided.

Fault recording

Fault recording comprises event and disturbance recording along with the stored fault measurands.

While a fault condition persists in the power system, the relevant signals, each fully tagged with date and time at signal start and signal end, are entered into a non-volatile memory in chronological sequence . The measured fault data, fully tagged with the date and time of acquisition, are also entered. Furthermore, the sampled values of all analog input variables such as phase currents and phase-to-ground voltages are recorded during a fault.

Up to eight faults can be recorded. If more than eight faults occur without interim memory clearance then the oldest fault recording is overwritten.

Blocking functions

Protection functions and their timer stages can be temporarily blocked in case of commissioning and cyclic testing. For this purpose single or accumulative blocking functions can be used.

The blocking functionalities can be activated and deactivated via the communication interfaces, the function keys or any binary input.

Reset functions

Counter and record information, latching, logical equations or stored measuring values can be reset by single or accumulative functions.

The reset functionalities can be activated via the communication interfaces, the function keys or any binary input of the MiCOM P63x.

Furthermore the user has the possibility to adapt the functional range of the reset key to the required application.

Self monitoring

Comprehensive self-monitoring procedures within the devices ensure that internal hardware or software errors are detected and do not cause malfunctions of the protective devices.

As the auxiliary voltage is turned on, a functional test is carried out. Cyclic self-monitoring tests are run during operation.

If test results deviate from the default value then the corresponding signal is entered into the non-volatile monitoring signal memory. The result of the fault diagnosis determines whether a blocking of the protection device will occur or whether a warning only is issued.

Password protection

For variable configuration requirements the devices are provided with a settable default – password. If required the function keys can be provided with settable barriers (password for each of the keys).

Access barriers protect the enter mode or the function keys in order to guard against inadvertent or unauthorized changing of parameter settings or triggering of control functions.



Local Control

All data required for operation of the MiCOM P63x are entered from the integrated local control panel, and the data important for system management are read out there as well. The following tasks can be handled via the local control panel:

• Switchgear control

• Readout and modification of settings

• Readout of cyclically updated measured operating data and state signals

• Readout of operating data logs and of monitoring signal logs

• Readout of event logs (after overload situations or short-circuits in the power system)

• Resetting of the unit and triggering of further control functions designed to support testing and commissioning tasks

The MiCOM P63x local control panel (HMI) comprises the local control elements and functions described below.

Operation

(1) The integrated local control panel has a graphical back-lit LCD DisplayLCD DisplayLCD DisplayLCD Display with 4 x 20 resp. 16 x 21 alphanumeric characters.

23 resp. 17 LED indicatorsLED indicatorsLED indicatorsLED indicators are provided for signal display. A separate adhesive label is provided for user-defined labeling of these LED indicators according to the chosen configuration.

(2) 5 LED indicators are permanently assigned to signals.

(3) The remaining 18 LED indicators are available for free assignment by the user and can be configured for the colors red, green or yellow. Furthermore different operation and flashing modes are available.

Menu tree

(4) By pressing the navigatnavigatnavigatnavigation keys ion keys ion keys ion keys

, , and guided by the LCD display, the user moves within a plain text menu. All setting parameters and measured variables as well as all local control functions are arranged in this menu which is standardized for all devices of the system. Changes to the settings can be prepared and

confirmed by means of the Enter KeyEnter KeyEnter KeyEnter Key G which also serves to trigger local control functions. In the event of erroneous entries, exit from the enter mode with rejection of the entries is possible at any time by means of the

ClearClearClearClear KeyKeyKeyKey C When the edit mode is not activated, pressing the Clear Key has the effect of resetting the indications.

Pressing the Read KeyRead KeyRead KeyRead Key provides direct access to preselected point(s) in the menu.

Local control panel with text HMI

1

2

3

8

6

4

5

7

P632

Function keys

(5) 6 Function keysFunction keysFunction keysFunction keys (F1…F6) are available for free assignment to any logical binary input or control function. This facilitates control, e.g. of manual trip and close commands.

Type label and PC interface

(6) An upper cover identifying the product name. The cover may be raised to provide access to the product model number anproduct model number anproduct model number anproduct model number and ratingsd ratingsd ratingsd ratings.

(7) A lower cover concealing the RS232 serial RS232 serial RS232 serial RS232 serial interfaceinterfaceinterfaceinterface to connect a personal computer.

(8) To guard the lower cover against unauthorized opening it is provided a facility for fitting a security lead sealsecurity lead sealsecurity lead sealsecurity lead seal.



Display panels

The configuration of the local control panel allows the installation of measured value “panels” on the LCD display. The panels are automatically displayed depending on operation conditions of the system. Priority increases from normal operation to operation under overload conditions and finally operation following a short circuit in the system. The protection device thus provides the measured value data relevant for the prevailing conditions.

Devices with the optional control functions have additionally a control panel display to show the active switchgear status and for local control via function keys.

Mechanical Design

The device is supplied in two case designs.

• Surface-mounting case

• Flush-mounting case

Both cases are available with fixed or detachable HMI. With all case versions, connection is via threaded terminal ends with the option of either pin or ring-terminal connection.

Two 40T flush-mounting cases can be combined to form a complete 19" mounting rack.

The plug-in modules may be combined to suit the individual requirements. The components fitted in an individual unit can be determined from the type identification label on the front panel of the unit.

The identificationidentificationidentificationidentification of the modules fitted in the device is carried out by the device itself. During each startup of the device, the number and type of fitted modules are established by interrogation via the digital bus, the admissibility of the set of fitted components is checked and appropriate configuration parameters - in accordance with the fitted set of modules - are released for application. The device identification values additionally read out by the device provide information on the type, variant and design version of each individual module.

C

Local control with text HMI

Bay panel Measured value panel(s)

Control and Display panels

Record view

Oper/Rec/OP_RCOperat. data record

(state dependent)

+

X0 : Closed

Q0 : ClosedQ8 : Open

Remote Locked

>

Voltage A-B prim.

20,7 kVVoltage B-V prim.

20,6 kV

Device type

Parameters

Device ID

Configuration parameter

Function parameter

Global

Main functions

Parameter subset 1

Parameter subset ...

Control

Operation

Cyclic measurants

Control and testing

Operating data recording

Measured operating data

Physical state signals

Logical state signals

Events

Event counters

Measured fault data

Event recording

Menu tree



Transformer module T

The transformer module converts the measured current and voltage variables to the internal processing levels and provides for electrical isolation.

Power supply module V

The power supply module ensures the electrical isolation of the device as well as providing the power supply. Depending on the chosen design version, optical coupler inputs and output relays are provided in addition.

Processor module P

The processor module performs the analog/digital conversion of the measured variables as well as all digital processing tasks.

Local control module L

The local control module encompasses all control and display elements as well as a PC interface. The local control module is located behind the front panel and connected to the processor module via a ribbon cable.

Bus modules B

Bus modules are printed circuit boards (PCBs). They provide the electrical connection between the other modules. Two types of bus modules are used, namely analog and digital bus PCB.

Binary I/O modules X (Optional)

The binary I/O modules are equipped with optical couplers for binary signal input as well as output relays for the output of signals and commands or combinations of these.

Analog module Y (Optional)

The analog module is fitted with a PT100 input, a 20 mA input and two 20 mA outputs. One output relay each is assigned to two 20 mA outputs. One output relay each is assigned to the two 20 mA outputs. Additionally, four optical coupler inputs are available.

Communication modules A (Optional)

The optional communication module provides one or two information interfaces for the integration of the protection device into a substation control system and for remote access. The communication module is plugged into the processor module.

GGC

GG

G

G

G

MiCOM

TRIP

ALARM

OUT OF SERVICE

HEAL THY

EDIT M ODE

F1

F2

F3

F4

F5

F6



Technical Data

CE Marking

This product complies with the essential requirements of the This product complies with the essential requirements of the This product complies with the essential requirements of the This product complies with the essential requirements of the following European directives:following European directives:following European directives:following European directives: EMC Directive 2004/108/EC Low Voltage Directive 2006/95/EC

General Data

DesignDesignDesignDesign

Surface-mounted case suitable for wall installation or flush-mounted case for 19" cabinets and for control panels

Installation positionInstallation positionInstallation positionInstallation position

Vertical ±30°

Degree of ProtectionDegree of ProtectionDegree of ProtectionDegree of Protection

Per DIN VDE 0470 and EN 60529 or IEC 529. IP 52 for the front panel Flush mounted case IP 50 for the case (excl. the rear connection area) IP 20 for the rear connection area, pin terminal connection IP 10 for the rear connection area, ring terminal connection Surface mounted case IP 50 for the case IP 50 for the fully enclosed connection area with the supplied rubber grommets fitted

Weight Weight Weight Weight

Case 40T: max. 7 kg Case 84T: max. 11 kg

DimensionsDimensionsDimensionsDimensions

See “Dimensions”

Terminal Connection DiagramsTerminal Connection DiagramsTerminal Connection DiagramsTerminal Connection Diagrams

See “Connections”

TerminalsTerminalsTerminalsTerminals

PC Interface (X6)PC Interface (X6)PC Interface (X6)PC Interface (X6) DIN 41652 connector , type D-Sub, 9-pin

CommunCommunCommunCommunication Interfaces COMM1, COMM2ication Interfaces COMM1, COMM2ication Interfaces COMM1, COMM2ication Interfaces COMM1, COMM2 Optical fibers (X7 and X8): F-SMA-interface per IEC 60874-2 per plastic fiber or BFOC-(ST

®)-interface 2.5 per IEC 60874-10-1 per glass fiber

or Leads (X9, X10): Threaded terminal ends M2 for wire cross sections up to 1.5 mm

2

Communication Interface IECCommunication Interface IECCommunication Interface IECCommunication Interface IEC Optical fibers (X7 and X8): BFOC-(ST

®)-interface 2.5 per IEC 60874-10-1 per glass fiber

or Optical fibers (X13): SC-interface per IEC60874-14-4 per glass fiber and Leads (X12): RJ45 connector per ISO/IEC 8877

IRIGIRIGIRIGIRIG----B Interface (X11)B Interface (X11)B Interface (X11)B Interface (X11) BNC plug

CurrentCurrentCurrentCurrent----Measuring InputsMeasuring InputsMeasuring InputsMeasuring Inputs Threaded terminals for pin-terminal connection: Threaded terminal ends M5, self-centering with wire protection for

conductor cross sections of ≤ 4 mm2

or Threaded terminals M4 for ring-terminal connection

Other Inputs and Outputs Other Inputs and Outputs Other Inputs and Outputs Other Inputs and Outputs Threaded terminals for pin-terminal connection: Threaded terminal ends M3, self-centering with wire protection for conductor cross sections of 0.2 to 2.5 mm2 or Threaded terminals M4 for ring-terminal connection

Creepage Distance and ClearanceCreepage Distance and ClearanceCreepage Distance and ClearanceCreepage Distance and Clearance

Per EN 61010Per EN 61010Per EN 61010Per EN 61010----1 and IEC 6641 and IEC 6641 and IEC 6641 and IEC 664----1,1,1,1, pollution degree 3, working voltage 250 V, overvoltage category III, impulse test voltage 5 kV



Environmental Conditions

Ambient temperature rangeAmbient temperature rangeAmbient temperature rangeAmbient temperature range

Recommended temperature range: –5 °C...+55 °C, or +23 °F...+131 °F Limit temperature range for: Operating -25 °C...+55 °C or -13 °F...+131 °F Storage and transit -25 °C...+70 °C or -13 °F...+158 °F

Ambient humidity rangeAmbient humidity rangeAmbient humidity rangeAmbient humidity range

≤ 75 % relative humidity (anual mean),

Condensation not permissible

Solar radiationSolar radiationSolar radiationSolar radiation

Avoid exposure of the front panel to direct solar radiation.

Tests

Type tests

Environmental testsEnvironmental testsEnvironmental testsEnvironmental tests

Temperature stabilitiy testTemperature stabilitiy testTemperature stabilitiy testTemperature stabilitiy test Per IEC 60068-2-1 -25 °C or -13 °F storage (96 hours) -40 °C or -40 °F operation (96 hours) Per IEC 60068-2-2 +85 °C or 185 °F storage (96 hours) +85 °C or 185 °F operation (96 hours) Per IEC 60068-2-14 Change of temperature, 5 cycles, 1°C / min rate of change

Ambient humidity range testAmbient humidity range testAmbient humidity range testAmbient humidity range test Per IEC 60068-2-3

56 days at ≤ 93 % relative humidity and 40 °C,

Per IEC 60068-2-30 Damp heat, cyclic (12 + 12 hours)

93 % relative humidity, + 25 …+ 55 °C

Corrosive environment testsCorrosive environment testsCorrosive environment testsCorrosive environment tests

Industrial corrosive environment/Industrial corrosive environment/Industrial corrosive environment/Industrial corrosive environment/ poor environmental control, mixed gas flow test. poor environmental control, mixed gas flow test. poor environmental control, mixed gas flow test. poor environmental control, mixed gas flow test. Per IEC 60068-2-60: 1995, Part 2, Test Ke, Method (class) 3 21 days at 75% relative humidity and +30°C exposure to elevated concentrations of H2222S, NO2222, Cl2222 and SO2222

EMCEMCEMCEMC

Interference suppressionInterference suppressionInterference suppressionInterference suppression Per EN 55022 or IEC CISPR 22, Class A

Immunity to damped oscillatImmunity to damped oscillatImmunity to damped oscillatImmunity to damped oscillatory wavesory wavesory wavesory waves Per IEC 61000-4-12, Class III, 100-kHz Damped Oscillatory Waves Common-mode test voltage: 2.5 kV, Differential test voltage: 1.0 kV,

Test duration: > 2 s, Source impedance: 200 Ω

Per IEC 255 Part 22-1 or IEC 60255-22-1, Class III, 1-MHz Damped Oscillatory Waves Common-mode test voltage: 2.5 kV, Differential test voltage: 1.0 kV,

Test duration: > 2 s, Source impedance: 200 Ω

Immunity to electrostatic discharge Immunity to electrostatic discharge Immunity to electrostatic discharge Immunity to electrostatic discharge Per EN 60255-22-2 or IEC 60255-22-2, Level 4, Contact discharge, single discharges : > 10, Holding time: > 5 s, Test voltage: 8 kV,

Test generator: 50...100 MΩ, 150 pF / 330 Ω

Immunity to radiated electromagnetic energyImmunity to radiated electromagnetic energyImmunity to radiated electromagnetic energyImmunity to radiated electromagnetic energy Per EN 61000-4-3 and ENV 50204, Level 3, Antenna distance to tested device: > 1 m on all sides, Test field strength, frequ. band 80...1000 MHz: 10 V / m, Test using AM: 1 kHz / 80 %, Single test at 900 MHz: AM 200 Hz / 100 %

Electrical fast transient or burst requirements Electrical fast transient or burst requirements Electrical fast transient or burst requirements Electrical fast transient or burst requirements Per IEC 60255-22-4, Class B: Power supply: Amplitude: 2 kV, Burst frequency: 5 kHz Inputs / Outputs: Amplitude: 2 kV, Burst frequency: 5 kHz Communication: Amplitude: 1 kV, Burst frequency: 5 kHz Per DIN EN 61000-4-4, severity level 4: Power supply: Amplitude: 4 kV, Burst frequency: 2,5 kHz and 5 kHz Inputs / Outputs: Amplitude: 2 kV, Burst frequency: 5 kHz Communication: Amplitude: 2 kV, Burst frequency: 5 kHz Rise time of one pulse: 5 ns, Impulse duration (50% value): 50 ns, Burst duration: 15 ms, Burst cycle: 300 ms,

Source impedance: 50 Ω

Conducted disturbance induced by radiofrequency fields Conducted disturbance induced by radiofrequency fields Conducted disturbance induced by radiofrequency fields Conducted disturbance induced by radiofrequency fields Per IEC 60255-22-7, Class A: Phase-to-Phase: Voltage 150 V (r.m.s.),

Coupling resistor 100 Ω

Coupling capacitor 0.1 µF, for 10 s. Phase-to-Ground: Voltage 300 V (r.m.s.),

Coupling resistor 220 Ω

Coupling capacitor 0.47 µF, for 10 s.

Surge immunitySurge immunitySurge immunitySurge immunity Per EN 61000-4-5 or IEC 61000-4-5, Level 4, Testing of power supply circuits, unsymmetrically / symmetrically operated lines, Open-circt. voltg. front time/time to half-value: 1.2 / 50 >s, Short-circuit current front time/time to half-value: 8 / 20 >s, Amplitude: 4 / 2 kV, Pulse frequency: > 5 / min,

Source impedance: 12 / 42 Ω

Immunity to conducted disturbances induced by radio Immunity to conducted disturbances induced by radio Immunity to conducted disturbances induced by radio Immunity to conducted disturbances induced by radio frequency fields frequency fields frequency fields frequency fields Per EN 61000-4-6 or IEC 61000-4-6, Level 3, Disturbing test voltage: 10 V

Power frequency magnetic field immunityPower frequency magnetic field immunityPower frequency magnetic field immunityPower frequency magnetic field immunity Per EN 61000-4-8 or IEC 61000-4-8, Level 4, Frequency: 50 Hz, Test field strength: 30 A / m, 100 A / m

Alternating component (ripple) in DC auxiliary energizing Alternating component (ripple) in DC auxiliary energizing Alternating component (ripple) in DC auxiliary energizing Alternating component (ripple) in DC auxiliary energizing quantityquantityquantityquantity Per IEC 255-11, 12 %



InsulationInsulationInsulationInsulation

Voltage test Voltage test Voltage test Voltage test Per IEC 255-5 or DIN EN 61010, 2 kV~, 60 s For the voltage test of the power supply inputs, direct voltage (2.8 kVDC) must be used. The PC Interface must not be subjected to the voltage test.

Impulse voltage Impulse voltage Impulse voltage Impulse voltage withstand testwithstand testwithstand testwithstand test Per IEC 255-5, Front time: 1.2 µs, Time to half-value: 50 µs,

Peak value: 5 kV, Source impedance: 500 Ω

Mechanical robustnessMechanical robustnessMechanical robustnessMechanical robustness

Vibration testVibration testVibration testVibration test Per DIN EN 60255-21-1 or IEC 255-21-1, test severity class 1: frequency range in operation: 10...60 Hz, 0.035 mm, 60...150 Hz, 0.5 g, frequency range during transport: 10...150 Hz, 1 g

Shock response and withstand test, bump test Shock response and withstand test, bump test Shock response and withstand test, bump test Shock response and withstand test, bump test Per DIN EN 60255-21-2 or. IEC 255-21-2, acceleration and pulse duration: Shock Response test to verify full operability (during operation): test severity class 1, 5 g for 11 ms, Shock Response test to verify endurance (during transport): test severity class 1, 15 g for 11 ms

Seismic test Seismic test Seismic test Seismic test Per DIN EN 60255-21-3 or IEC 255-21-3, test procedure A, Class 1: frequency range: 5...8 Hz, 3.5 mm / 1.5 mm, 8...35 Hz, 10 / 5 m/s2 3 × 1 cycle

Vibration test Vibration test Vibration test Vibration test 1)1)1)1) Per DIN EN 60255-21-1 or IEC 255-21-1, test severity class 2: frequency range in operation: 10...60 Hz, 0.075 mm, 60...150 Hz, 1.0 g, frequency range during transport: 10...150 Hz, 2 g

Shock response and withstand test, bump test Shock response and withstand test, bump test Shock response and withstand test, bump test Shock response and withstand test, bump test 1)1)1)1) Per DIN EN 60255-21-2 or IEC 255-21-2, acceleration and pulse duration: Shock Response test to verify full operability (during operation): test severity class 2, 10 g für 11 ms, Shock Response test to verify endurance (during transport): test severity class 1, 15 g für 11 ms Shock bump test to verify permanent shock (during transport): test severity class 1, 10 g für 16 ms

Seismic test Seismic test Seismic test Seismic test 1)1)1)1) Per DIN EN 60255-21-3 or IEC 255-21-3, test procedure A, Class 2 frequency range: 5...8 Hz, 7.5 mm / 3.5 mm, 8...35 Hz, 20 / 10 m/s2 3 × 1 cycle

1) Enhanced mechanical robustness for the following case variants:

Flush mounted case, version 2 (with angle brackets and frame)

Surface mounted case

Routine testsRoutine testsRoutine testsRoutine tests

Voltage testVoltage testVoltage testVoltage test Per IEC 255-5: 2.2 kVAC, 1 s For the voltage test of the power supply inputs, direct voltage (2.8 kVDC) must be used. The PC Interface must not be subjected to the voltage test.

Additional thermal testAdditional thermal testAdditional thermal testAdditional thermal test 100 % controlled thermal endurance test, inputs loaded.

Ratings

Measurement inputsMeasurement inputsMeasurement inputsMeasurement inputs

Frequency:Frequency:Frequency:Frequency: Nominal frequency fnom: 50 Hz and 60 Hz (settable) Operating range: 0.95...1.05 fnom Frequnecy protection: 40…70 Hz

CurrentCurrentCurrentCurrent Nominal current Inom: 1 A and 5 A (settable) Nominal consumption per phase: < 0.1 VA at Inom Load rating: continuous: 4 Inom for 10 s: 30 Inom for 1 s: 100 Inom Nominal surge current: 250 Inom

VoltageVoltageVoltageVoltage Nominal voltage Vnom: 50...130 V AC (settable) Nominal consumption per phase: < 0.3 VA at Vnom=130 V AC Load rating: continuous 150 V AC

Binary signal inputsBinary signal inputsBinary signal inputsBinary signal inputs

Max. permissible voltage: 300 V DC

Switching threshold (as per order option) Switching threshold (as per order option) Switching threshold (as per order option) Switching threshold (as per order option) order option: Standard variant: 18V (VA,nom: 24 ... 250 VDC): Switching threshold range 14 V ... 19 VDC Special variant with switching thresholds from 58 ... 72 % of the nominal supply voltage (VA,nom) (definitively "low" at VA < 58 % of the nominal supply voltage, definitively "high" at VA > 72 % of the nominal supply voltage): "Special variant 73 V": nom. supply voltage 110 VDC "Special variant 90 V": nom. supply voltage 127 VDC "Special variant 146 V": nom. supply voltage 220 VDC "Special variant 155 V": nom. supply voltage 250 VDC

Power consumption (as per order option):Power consumption (as per order option):Power consumption (as per order option):Power consumption (as per order option): Standard variant: VA = 19...110VDC : 0.5 W +/-30%

VA > 110VDC : VA ∗ 5 mA +/- 30 %

Special variants:

VA > switching threshold: VA ∗ 5mA +/-30 %

Note:Note:Note:Note: The standard variant of binary signal inputs (opto-couplers) is recommended in most applications, as these inputs operate with any voltage from 19V. Special versions with higher pick-up/drop-off thresholds are provided for applications where a higher switching threshold is expressly required.



Analog inputs and outputsAnalog inputs and outputsAnalog inputs and outputsAnalog inputs and outputs

DC inputDC inputDC inputDC input Input current: 0...26 mA Value range 0.00...1.20 IDC,nom (IDC,nom = 20 mA) Maximum permissible continuous current: 50 mA Maximum permissible input voltage: 17 V

Input load: 100 Ω

Open-circiut monitoring: 0...10 mA (adjustable) Overload monitoring: > 24.8 mA Zero suppression: 0.000...0.200 IDC,nom (adjustable)

Resistance temperature detectorResistance temperature detectorResistance temperature detectorResistance temperature detector For analog module only PT100 permitted, Value range: -40...+215 °C

3-wire configuration: max. 20 Ω per conductor

open and short-circuit input permitted Open circuit monitoring:

Θ > +215 °C (or Θ > +419 °F) and

Θ < -40 °C (or Θ < -40 °F)

DC outputDC outputDC outputDC output Output current: 0 … 20 mA

Maximum permissible load: 500 Ω

Maximum output voltage: 15 V

Output relaysOutput relaysOutput relaysOutput relays

Binary module X (4H, 6I6H)Binary module X (4H, 6I6H)Binary module X (4H, 6I6H)Binary module X (4H, 6I6H) wiwiwiwith highth highth highth high----break contactsbreak contactsbreak contactsbreak contacts, , , , applicable to DC circuits onlyapplicable to DC circuits onlyapplicable to DC circuits onlyapplicable to DC circuits only Rated voltage: 250 VDC Continuous current: 10 A Short-duration current: 250 A for 0.03 s 30 A for 3 s Breaking capacity: 7500 W resistive or 30 A at 250 VDC maximum values: 30 A and 300 VDC 2500 W inductive (L/R = 40 ms) or 10 A at 250 VDC

maximum values: 10 A and 300 VDC

Other modules Other modules Other modules Other modules Rated voltage: 250 VDC, 250 VAC Continuous current: 5 A Short-duration current: 30 A for 0.5 s Breaking capacity: 0.2 A at 220 VDC and L/R = 40 ms,

4 A at 230 VAC and cos ϕ = 0.4

IRIGIRIGIRIGIRIG----B interfaceB interfaceB interfaceB interface

Min./max. input voltage level (peak-peak): 100 mVpp / 20 Vpp

Input impedance: 33 kΩ at 1 kHz

Galvanic isolation: 2 kV

Power SupplyPower SupplyPower SupplyPower Supply

Nominal auxiliary voltage Nominal auxiliary voltage Nominal auxiliary voltage Nominal auxiliary voltage VA,nom: 48…250 VDC and 100...230 VAC or VA,nom: 24 VDC (depends on ordering)

Operating rangeOperating rangeOperating rangeOperating range for direct voltage: 0.8…1.1 VA,nom with a residual of up to 12 % of VA,nom for alternating current: 0.9…1.1 VA,nom

Nominal consumption Nominal consumption Nominal consumption Nominal consumption at VA = 220 VDC and maximum number of modules fitted in case 40T: Initial / Active position approx.: 13 W / 29 W in case 84T: Initial / Active position approx.: 13 W / 37 W

StartStartStartStart----up peak currentup peak currentup peak currentup peak current < 3 A, duration 0.25 ms

StoredStoredStoredStored----energy timeenergy timeenergy timeenergy time

≥ 50 ms for interruption of VA ≥ 220 VDC

PC interfacePC interfacePC interfacePC interface

Transmission rate: 300...115200 bit/s (settable)

Serial Communication interfacesSerial Communication interfacesSerial Communication interfacesSerial Communication interfaces

Communication interface COMM1:Communication interface COMM1:Communication interface COMM1:Communication interface COMM1: Protocol per order either IEC 60870-5-103 or Can be switched (optional) between IEC 60870-5-103, IEC 870-5-101, Modbus, DNP 3.0, Courier

Transmission rate: 300...64000 bit/s (settable)

Communication interface COMM2:Communication interface COMM2:Communication interface COMM2:Communication interface COMM2: Protocol per IEC 60870-5-103 Transmission rate: 300...57600 bit/s (settable)

Wire leadsWire leadsWire leadsWire leads Per RS 485 or RS 422, 2 kV isolation Distance to be bridged: peer to peer link: max. 1200 m multi-endpoint link: max. 100 m

Plastic fiber ConnectionPlastic fiber ConnectionPlastic fiber ConnectionPlastic fiber Connection Optical wavelength : typ. 660 nm Optical output: min. – 7,5 dBm Optical sensivity: min. – 20 dBm Optical input: max. – 5 dBm Distance to be bridged: max. 45 m

1)

Glass fiber connection G 50/125Glass fiber connection G 50/125Glass fiber connection G 50/125Glass fiber connection G 50/125 Optical wavelength : typ. 820 nm Optical output: min. – 19,8 dBm Optical sensivity: min. – 24 dBm Optical input: max. – 10 dBm Distance to be bridged: max. 400 m

1)

Glass fiber connection G 62,5/125 Glass fiber connection G 62,5/125 Glass fiber connection G 62,5/125 Glass fiber connection G 62,5/125 Optical wavelength : typ. 820 nm Optical output: min. – 16 dBm Optical sensivity: min. – 24 dBm Optical input: max. – 10 dBm Distance to be bridged: max. 1400 m

1)

Communication interface IECCommunication interface IECCommunication interface IECCommunication interface IEC

Ethernet based communication per IEC 61850

Wire leadsWire leadsWire leadsWire leads Transmission rate: 100 Mbit/s RJ45, 1.5kV-isolation, Distance to be bridged: max. 100 m

Glass fiber connection G 50/125Glass fiber connection G 50/125Glass fiber connection G 50/125Glass fiber connection G 50/125 (ST or SC) (ST or SC) (ST or SC) (ST or SC) Transmission rate: 100 Mbit/s Optical wavelength: typ. 1300 nm Optical output: min. –23.5 dBm Optical sensitivity: min. -31 dBm Optical input: max. -14 dBm

Glass fiber cGlass fiber cGlass fiber cGlass fiber connection G 62.6onnection G 62.6onnection G 62.6onnection G 62.6/125/125/125/125 (ST or SC) (ST or SC) (ST or SC) (ST or SC) Transmission rate: 100 Mbit/s Optical wavelength: typ. 1300 nm Optical output: min. -20 dBm Optical sensitivity: min. -31 dBm Optical input: max. -14 dBm

IRIGIRIGIRIGIRIG----B interfaceB interfaceB interfaceB interface

Format B122, Amplitude modulated, 1 kHz carrier signal, BCD time-of-year code

1) Distance to be bridged for optical outputs and inputs that are

equal on both ends, taking into account a system reserve of 3 dB

and typical fiber attenuation.



Typical characteristic data

Main functionMain functionMain functionMain function Minimum output pulse for a trip command: 0.1 to 10 s (settable)

Differential protectionDifferential protectionDifferential protectionDifferential protection Operate time inclusive output relay:

≤ 16 ms without inrush stabilisation or Idiff > Idiff>>

≤ 32 ms with inrush stabilisation

Reset time (measured variable from fault infeed to 0):

≤ 30 ms, approx. 25 ms

DefiniteDefiniteDefiniteDefinite----time and inversetime and inversetime and inversetime and inverse----time overcurrent protectiontime overcurrent protectiontime overcurrent protectiontime overcurrent protection Operate time inclusive output relay (measured variable from 0 to 2-fold operate value):


Reset time (measured variable from 2-fold operate value to 0):


Starting resetting ratio: approx. 0.95

OverOverOverOver----/undervoltage protection/undervoltage protection/undervoltage protection/undervoltage protection Operate time inclusive of output relay (measured variable from nominal value to 1.2-fold operate value or measured variable from nominal value to 0.8-fold operate value):


Reset time (measured variable from 1.2-fold operate value to nominal value or measured variable from 0.8-fold operate value to nominal value):


Starting resetting ratio: settable hysteresis 1...10%

Overexcitation Overexcitation Overexcitation Overexcitation protectionprotectionprotectionprotection Starting resetting ratio: approx. 0.95

Deviations of the operate values

‘‘‘‘Reference conditionsReference conditionsReference conditionsReference conditions’’’’ Sinusoidal signals with nominal frequency fnom,

total harmonic distortion ≤ 2 %,

ambient temperature 20 °C and nominal auxiliary voltage VA,nom

‘Deviation’ ‘Deviation’ ‘Deviation’ ‘Deviation’ Deviation relative to the set value under reference conditions

Differential protectionDifferential protectionDifferential protectionDifferential protection Measuring system at Id > 0,2 Iref: ± 5 % Harmonic restraint: ± 10 %

Restricted Earthfault ProtectionRestricted Earthfault ProtectionRestricted Earthfault ProtectionRestricted Earthfault Protection Measuring system at Id > 0,2 Iref: ± 5 %

OvercurrentOvercurrentOvercurrentOvercurrent----time protectiontime protectiontime protectiontime protection Operate values: ± 5 %

Thermal overload protectionThermal overload protectionThermal overload protectionThermal overload protection Operate value Θ: ± 5 %

OverOverOverOver----/undervoltage protection/undervoltage protection/undervoltage protection/undervoltage protection Operate values V<>: ± 5 % related to set value ± 1 % related to nominal value

OverOverOverOver----/Underfrequency Protection /Underfrequency Protection /Underfrequency Protection /Underfrequency Protection Operate values f<>: +/- 30mHz (fnom = 50 Hz) +/- 40mHz (fnom = 60 Hz)

Operate values df/dt: +/- 0,1Hz/s (fnom = 50 or 60 Hz)

Overexcitation protectionOverexcitation protectionOverexcitation protectionOverexcitation protection Operate values: ± 3 %

Direct CurrentDirect CurrentDirect CurrentDirect Current InputInputInputInput 20 mA 20 mA 20 mA 20 mA Operate values: ± 1 %

ResistanceResistanceResistanceResistance ThermometerThermometerThermometerThermometer PT100PT100PT100PT100 Operate values: ± 2 ° bzw. ± 1%

Analog Measured Data OutputAnalog Measured Data OutputAnalog Measured Data OutputAnalog Measured Data Output 20 mA 20 mA 20 mA 20 mA Operate value: ± 1 % Output residual ripple with max. load: ± 1 %

Deviations of the timer stages

‘‘‘‘Reference coReference coReference coReference conditionsnditionsnditionsnditions’’’’ Sinusoidal signals with nominal frequency fnom,



‘Deviation’ ‘Deviation’ ‘Deviation’ ‘Deviation’ Deviation relative to the set value under reference conditions

DefiniteDefiniteDefiniteDefinite----time stagestime stagestime stagestime stages ± 1% + 20...40 ms

InverseInverseInverseInverse----time stagestime stagestime stagestime stages ± 5 % + 10...25 ms (measured variable greater than 2 Iref) ± 7,5 % + 10...20 ms for IEC characteristic ‘extremely inverse‘ and for thermal overload protection

Deviations in measured data acquisition

‘‘‘‘Reference condReference condReference condReference conditionsitionsitionsitions’’’’ Sinusoidal signals with nominal frequency fnom,



‘Deviation’ ‘Deviation’ ‘Deviation’ ‘Deviation’ Deviation relative to the relevant nominal value under reference conditions

Operating dataOperating dataOperating dataOperating data Currents / measuring inputs: ± 1 % Voltages / measuring input: ± 0.5 % Currents / internally calculated : ± 2 % Voltages / internally calculated : ± 2 % Frequency: ± 10 mHz

Fault dataFault dataFault dataFault data Phase and neutral/starpoint currents: ± 3 % Restraining and differential currents: ± 5 %

Internal clockInternal clockInternal clockInternal clock With free running internal clock: < 1 min / month With external synchronization

via protocol, synch. interval ≤ 1 min: ± 10 ms

via IRIG-B signal input: ± 1 ms

Resolution in fault data acquisition

Time resolution fault data acquisition:Time resolution fault data acquisition:Time resolution fault data acquisition:Time resolution fault data acquisition: 20 samples / cycle

Currents Currents Currents Currents Dynamic range: 33 Inom

Amplitude resolution at Inom = 1 A: 2.0 mAr.m.s. at Inom = 5 A: 10.1 mAr.m.s.

VoltageVoltageVoltageVoltage Dynamic range: 150 V Amplitude resolution: 9.2 mVr.m.s



Address list

Function parameters

Global functionsGlobal functionsGlobal functionsGlobal functions

PC link (PC):PC link (PC):PC link (PC):PC link (PC): Command blocking: No / Yes Sig./meas.val.block.: No / Yes

Communication link 1 (COMM1):Communication link 1 (COMM1):Communication link 1 (COMM1):Communication link 1 (COMM1): Command block. USER: No / Yes Sig./meas.block.USER: No / Yes

Communication link 2 (COMM2):Communication link 2 (COMM2):Communication link 2 (COMM2):Communication link 2 (COMM2): Command block. USER: No / Yes Sig./meas.block.USER: No / Yes

Binary output (OUTP):Binary output (OUTP):Binary output (OUTP):Binary output (OUTP): Outp.rel.block USER: No / Yes

Main function (MAIN):Main function (MAIN):Main function (MAIN):Main function (MAIN): Device on-line: No (= off) / Yes (= on) Test mode USER: No / Yes Nominal frequ. fnom: 50 Hz / 60 Hz Phase sequence: A – B – C / A – C – B Time tag: 1stEgde.,OpMem sorted / 1stEgde.,OpMem unsort after debounce time valid for y = ‚a‘ to ‚‘d‘ Inom C.T. prim.,end y: 1...50000 A Inom device, end y: 1.0 A/5.0 A Conn. Meas.circ. IP,y: Standard / Opposite valid for y = ‚a‘ to ‚c‘ Inom C.T. Yprim.,end y: 1...50000 A IY,nom device, end y: 1.0 A/5.0 A Conn. Meas.circ. IY,y: Standard / Opposite Vnom V.T. prim.: 0.1...1500.0 kV Vnom V.T. sec.: 50...130 V Meas. Value rel. IP: 0.00...0.20 Inom Meas. Value rel. Ineg: 0.000…0.200 Inom Meas. Value rel. Ipos: 0.000…0.200 Inom Meas. Value rel. IN: 0.000...0.200 Inom Meas. Value rel. IY: 0.000...0.200 IN,nom Meas. Value rel. V: 0.00...0.20 Vnom Settl. T. IP,max,del: 0.1...60.0 min Fct. assign. reset 1: see selection table Fct. assign. reset 2: see selection table valid for y = ‚1‘ to ‚4‘ Fct. assign. block. y: see selection table Fct. assign. trip cmd. y: see selection table Min.dur. trip cmd. y: 0.10...10.00 s Latching trip cmd. y: No/Yes Trip cmd.block. USER: No/Yes Fct. assign. fault: see function table valid for y = ‚1‘ to ‚3‘ Sig. asg. CBy open: see selection table Sig. asg. CBy closed: see selection table Debounce time gr. y: 0.00...2.54 s Chatt.mon. time gr. y: 0.0...25.4 s Change of state gr. y: 0...254 Inp.asg. ctrl.enabl.: see selection table Cmd. dur.long cmd.: 1...254 s Cmd. dur. short cmd.: 1...254 s Inp.asg.interl.deact: see selection table Inp.asg. L/R key sw.: see selection table Auto-assignment I/O: No / Yes Electrial control: Remote / Local Delay Man.Op.Superv.: 0...255 s W. ext. cmd. termin.: No / Yes Inp.assign. tripping: see selection table Prot.trip>CB tripped: see selection table Inp. asg. CB trip: see selection table Inp.asg.CB tr.en.ext: see selection table Inp.asg. CB trip ext: see selection table Inp.asg. mult.sig. 1: see selection table Inp.asg. mult.sig. 2: see selection table

Parameter subset selection (PSS):Parameter subset selection (PSS):Parameter subset selection (PSS):Parameter subset selection (PSS): Control via USER: No / Yes Param.subs.sel. USER: Parameter subset 1 / … Parameter subset 4 Keep time: 0.000...65.000 s / Blocked

Self monitoring (SFMON):Self monitoring (SFMON):Self monitoring (SFMON):Self monitoring (SFMON): Fct. assign. warning: see selection table Mon.sig. retention: 0...240 h / Blocked

Fault Recording (FT_RC):Fault Recording (FT_RC):Fault Recording (FT_RC):Fault Recording (FT_RC): Fct. assign. trigger: see selection table Id>: 0.01...30.00 Iref / Blocked IR>: 0.01...30.00 Iref / Blocked Pre-fault time: 1...50 Periods Post-fault time: 1...50 Periods Max. recording time: 5...300 Periods

General functionsGeneral functionsGeneral functionsGeneral functions

Main function (MAIN):Main function (MAIN):Main function (MAIN):Main function (MAIN): valid for y = ‚a‘ to ‚c‘ Evaluation IN, end y: Calculated / Measured Current summation: Without End (a) + end (b) / End (a) + end (c) / End (a) + end (d) End (b) + end (c) / End (b) + end (d) / End (c) + end (d) End (a) + end (b) + end (c) / End (a) + end (b) + end (d) End (a) + end (c) + end (d) / End (b) + end (c) + end (d) End (a) – end (b) / End (a) – end (c) / End (a) – end (d) End (b) – end (c) / End (b) – end (d) / End (c) – end (d) Hold time dyn.param.: 0.00...100.00 s / Blocked

Differential protection (DIFF):Differential protection (DIFF):Differential protection (DIFF):Differential protection (DIFF): General enable USER: No/Yes Reference power Sref: 0.1...5000.0 MVA valid for y = ‚a‘ to ‚‘d‘ Ref. curr. Iref,y: 0.000...50.000 kA Matching fact. kam,y: 0.000...5.000 Meas. value rel. Id: 0.000...0.200 Iref Meas. value rel. IR: 0.000...0.200 Iref

Restricted EarthRestricted EarthRestricted EarthRestricted Earth----Fault Protection (REF_1)Fault Protection (REF_1)Fault Protection (REF_1)Fault Protection (REF_1):::: General enable USER: No/Yes Select. meas. input : End a valid for y = ‚b‘ to ‚‘d‘ Add.meas.inp. end y: No/Yes Reference power Sref: 0.1...5000.0 MVA Ref. curr. Iref: 0.000...50.000 kA valid for y = ‚a‘ to ‚‘d‘ Match. fact. kam,N,y: 0.000...50.000 Matching fact. kam,Y: 0.000...50.000 Meas. value rel. Id: 0.00...0.20 Iref Meas. value rel. IR: 0.00...0.20 Iref

Restricted EarthRestricted EarthRestricted EarthRestricted Earth----Fault Protection (REF_2,REF_3)Fault Protection (REF_2,REF_3)Fault Protection (REF_2,REF_3)Fault Protection (REF_2,REF_3):::: General enable USER: No/Yes Select. meas. input : End b / End c Reference power Sref: 0.1...5000.0 MVA Ref. curr. Iref: 0.000...50.000 kA Matching fact. kam,N: 0.000...50.000 Matching fact. kam,Y: 0.000...50.000 Meas. value rel. Id: 0.00...0.20 Iref Meas. value rel. IR: 0.00...0.20 Iref

DefiniDefiniDefiniDefinitetetete----time overcurrent protection time overcurrent protection time overcurrent protection time overcurrent protection (DTOC1, DTOC2, DTOC3)(DTOC1, DTOC2, DTOC3)(DTOC1, DTOC2, DTOC3)(DTOC1, DTOC2, DTOC3):::: Enabled USER: No/Yes Select. meas. input: End a/ End b/ End c/ End d/ Current summation

InverseInverseInverseInverse----time overcurrent protection time overcurrent protection time overcurrent protection time overcurrent protection ((((IDMT1IDMT1IDMT1IDMT1, IDMT2, IDMT3, IDMT2, IDMT3, IDMT2, IDMT3, IDMT2, IDMT3):):):): Enabled USER: No/Yes Select. meas. input: End a/ End b/ End c/ End d/ Current summation



Thermal Overload ProThermal Overload ProThermal Overload ProThermal Overload Protection (THRM1, THRM2):tection (THRM1, THRM2):tection (THRM1, THRM2):tection (THRM1, THRM2): General enable USER: No/Yes Select. meas. input: End a/ End b/ End c/ End d/ Current summation Operating mode: Absolute replica / Relative replica O/T f.Iref persist x: -40…300 °C

OverOverOverOver----/Undervoltage Protection (V<>):/Undervoltage Protection (V<>):/Undervoltage Protection (V<>):/Undervoltage Protection (V<>): General enable USER: No/Yes

OverOverOverOver----/Underffrequency Protection (f<>):/Underffrequency Protection (f<>):/Underffrequency Protection (f<>):/Underffrequency Protection (f<>): General enable USER: No/Yes Evaluation time : 3...6 Periods Undervolt.block.V<: 0.20...1.00 Vnom

Overfluxing Protection (V/f):Overfluxing Protection (V/f):Overfluxing Protection (V/f):Overfluxing Protection (V/f): General enable USER: No/Yes

Current Transformer Supervision (CTS): General enable USER: No/Yes

MeasuringMeasuringMeasuringMeasuring----Circuit Monitoring Circuit Monitoring Circuit Monitoring Circuit Monitoring (MCM_1, MCM_2, MCM_3, MCM_4):(MCM_1, MCM_2, MCM_3, MCM_4):(MCM_1, MCM_2, MCM_3, MCM_4):(MCM_1, MCM_2, MCM_3, MCM_4): General enable USER: No/Yes Select. meas. input: End a/ End b/ End c/ End d/ Current summation

Circuit breaker failure protection Circuit breaker failure protection Circuit breaker failure protection Circuit breaker failure protection (CBF(CBF(CBF(CBF_1,_1,_1,_1, CBFCBFCBFCBF_2,_2,_2,_2, CBFCBFCBFCBF_3,_3,_3,_3, CBFCBFCBFCBF_4_4_4_4)))) General enable USER: No / Yes Select.meas. input: End a/ End b/ End c/ End d Fct.assignm. starting: see selection table Start with man. trip: No / Yes Fct.assignm. CBAux.: see selection table I<: 0.05…20.00 Inom IN<: 0.05…20.00 Inom Evaluation IN: Without / Calculated / Measured t1 3p: 0.00…100.00 s / Blocked t2: 0.00…100.00 s / Blocked Min.dur. trip cmd. t1: 0.10…10.00 s Min.dur. trip cmd. t2: 0.10…10.00 s Latching trip cmd. t1: No/Yes Latching trip cmd. t2: No/Yes Delay/starting trig.: 0.00…100.00 s / Blocked Delay/fault beh. CB: 0.00…100.00 s / Blocked Delay/CB sync.superv.: 0.00…100.00 s / Blocked

Limit value monitoring (LIMIT):Limit value monitoring (LIMIT):Limit value monitoring (LIMIT):Limit value monitoring (LIMIT): General enable USER: No / Yes valid for y = ‚>’ / ,>>’ / ,<’ / ,<<‘: IDC,lin y: 0.100...1.100 IDC,nom / Blocked tIDC,lin y: 0.00...20.00 s / Blocked T y: -20...200°C tT y: 0...1000 s / Blocked

Limit value monitoring (LIMLimit value monitoring (LIMLimit value monitoring (LIMLimit value monitoring (LIM_1,_1,_1,_1, LIMLIMLIMLIM____2222,,,, LIMLIMLIMLIM_3_3_3_3):):):): General enable USER: No / Yes Select.meas. input: End a/ End b/ End c/ End d/ Current summation valid for y = ‚>’ / ,>>’ / ,<’ / ,<<‘: I y: 0.10... 2.40 Inom / Blocked tI y: 1...1000 s / Blocked

Programmable Logic (LOGIC):Programmable Logic (LOGIC):Programmable Logic (LOGIC):Programmable Logic (LOGIC): General enable USER: No / Yes valid for y = ‚1‘ to ‚8‘: Set y USER: No / Yes valid for y = ‚1‘ to ‚32‘: Fct.assignm. outp. y: see selection table Op. mode t output y: Without timer stage Oper./release.delay Oper.del./puls.dur Op./rel.delay,retrig Op.del./puls.dur.,rt Minimum time Time t1 output y: 0.00...600.00 s Time t2 output y: 0.00...600.00 s Sig.assig. outp. y: see selection table Sig.assig. outp. y(t): see selection table

Commands (CMD_1):Commands (CMD_1):Commands (CMD_1):Commands (CMD_1): valid for y = ‚C001‘ to ‚C012‘ Design. command y: y / Motor relay / Shunt winding Oper. mode cmd. y: Long command / Short command / Persistent command

Signaling (SIG_1):Signaling (SIG_1):Signaling (SIG_1):Signaling (SIG_1): valid for y = ‚S001‘ to ‚S012‘ Designat. signal y: see selection table Oper. mode sig. y: Without function / Start/end signal / Transient signal Gr.asg. debounc. y: Group 1 / Group 2 / Group 3 Min. sig. dur. y: 0...254 s

Parameter subsetParameter subsetParameter subsetParameter subset

valid for parameter subsets x = = ‚1‘ to ‚4‘:

Main function (MAIN):Main function (MAIN):Main function (MAIN):Main function (MAIN): valid for y = ‚a‘ to ‚d‘: Vnom prim., end y: 0.1...1500.0 kV Phase reversal y PS1: No swap/ A-B swapped/ B-C swapped/ C-A swapped

Differential protection (DIFF):Differential protection (DIFF):Differential protection (DIFF):Differential protection (DIFF): Enable PSx: No/Yes Vector grp. ends a-b: 0...11 Vector grp. ends a-c: 0...11 Vector grp. ends a-d: 0...11 Idiff> PSx: 0.10...2.50 Iref Idiff>> PSx: 2.5...30.0 Iref Idiff>>> PSx: 2.5...30.0 Iref / Blocked Idiff>(CTS) PSx: 0.10...30.00 Iref m1 PSx: 0.10...1.50 m2 PSx: 0.10...1.50 IR,m2 PSx: 1.5...10.0 Iref Op. Mode rush rst.PSx: Without / Not phase-selective / Phase selective RushI(2f0)/I(f0) PSx: 10...50 % valid for y = ‚a‘ to ‚‘d‘ 0-seq. filt.y en.PSx: No/Yes Overflux.bl. en.PSx: No/Yes Ov. I(5f0)/I(f0) PSx: 10...80 % Op.del.,trip sig.PSx: 0.00…100 s Hyst. effective PSx: No/Yes

Restricted EarthRestricted EarthRestricted EarthRestricted Earth----Fault Protection (REF_1,REF_2,REF_3):Fault Protection (REF_1,REF_2,REF_3):Fault Protection (REF_1,REF_2,REF_3):Fault Protection (REF_1,REF_2,REF_3): Enable PSx: No/Yes Operating mode PSx: Low imped. / sum (IP) Low imped. / IP,max High impedance Bl.f.DIFF trigg. PSx: No/Yes CTS effective PSx: No/Yes Idiff> PSx: 0.10...1.00 Iref Idiff>>> PSx: 2.5...30.0 Iref / Blocked m1 PSx: 0.00…1.00 m2 PSx: 0.15…1.50 IR,m2 PSx: 0.10…1.50 Iref

DefiniteDefiniteDefiniteDefinite----time overcurrent protection time overcurrent protection time overcurrent protection time overcurrent protection ((((DTOC1, DTOC2, DTOC3DTOC1, DTOC2, DTOC3DTOC1, DTOC2, DTOC3DTOC1, DTOC2, DTOC3):):):): Enable PSx: No / Yes Block tim.st. IN PSx: Without / For single-ph. Start / For multi-ph. Start Gen.starting mode PSx: W/o start IN/Ineg / With start IN/Ineg tGS PSx: 0.00...100.00 s / Blocked Rush restr.enabl. PSx: No/Yes valid for y = ‚>‘ to ‚>>>‘: Iy PSx: 0.10...30.00 Inom / Blocked Iy dynamic PSx: 0.10...30.00 Inom / Blocked tIy PSx: 0.00...100.00 s / Blocked Ineg y PSx: 0.10...8.00 Inom / Blocked Ineg y dynamic PSx: 0.10...8.00 Inom / Blocked tIneg y: 0.00...100.00 s / Blocked INy: 0.10...8.00 Inom / Blocked INy dynamic: 0.10...8.00 Inom / Blocked tINy: 0.00...100.00 s / Blocked



InverseInverseInverseInverse----timetimetimetime overcurrent protection ( overcurrent protection ( overcurrent protection ( overcurrent protection (IDMT1, IDMT2, IDMT3IDMT1, IDMT2, IDMT3IDMT1, IDMT2, IDMT3IDMT1, IDMT2, IDMT3):):):): Enable PSx: No / Yes Block tim.st. IN PSx: Without / For single-ph. Start / For multi-ph. Start Gen.starting mode PSx: W/o start IN/Ineg / With start IN/Ineg tGS PSx: 0.00...100.00 s / Blocked Rush restr.enabl PSx: No/Yes valid for y = ‚P‘, ,neg‘ or ‚N‘: Iref,y PSx: 0.10...4.00 Inom / Blocked Iref,y dynamic PSx: 0.10...4.00 Inom / Blocked Characteristic y PSx: Definite Time IEC Standard Inverse IEC Very Inverse IEC Extr. Inverse IEC Long Time Inv. IEEE Moderately Inv. IEEE Very Inverse IEEE Extremely Inv. ANSI Normally Inv. ANSI Short Time Inv. ANSI Long Time Inv. RI-Type Inverse RXIDG-Type Inverse Factor kt,y PSx: 0.05...10.00 Min. trip t. y PSx: 0.00…10 s Hold time y PSx: 0.00...600.00 s Release y PSx: Without delay / delayed as per char.

Thermal Overload Protection (THERMThermal Overload Protection (THERMThermal Overload Protection (THERMThermal Overload Protection (THERM1,1,1,1, THERM THERM THERM THERM2222):):):): Enable PSx: No/Yes Iref PSx: 0.10...4.00 Inom Start.fact.OL_RC PSx: 1.05...1.50 Tim.const. 1 >Ibl PSx: 1.0...1000.0 min Tim.const. 2<Ibl PSx: 1.0...1000.0 min

Max.perm.obj.tmp. PSx: 0...300 °C

Max.perm.cool.tmp PSx: 0...70 °C

Select CTA PSx: Default temp. value / from PT100 / from 20 mA input

Default CTA PSx: -40...70 °C

Bl. f. CTA fault PSx: No/Yes Rel. O/T warning PSx: 50…200 % Rel. O/T trip PSx: 50…200 % Hysteresis trip PSx: 2…30 % Warning pre-trip PSx: 0.0...1000.0 min / Blocked

OverOverOverOver----/undervoltage protection (V<>):/undervoltage protection (V<>):/undervoltage protection (V<>):/undervoltage protection (V<>): Enable PSx: No / Yes V> PSx: 0.20...1,50 Vnom / Blocked V>> PSx: 0.20...1.50 Vnom / Blocked tV> PSx: 0.00...100.00 s / Blocked tV>> PSx: 0.00...100.00 s / Blocked V< PSx: 0.20...1.50 Vnom / Blocked V<< PSx: 0.20...1.50 Vnom / Blocked Vmin> PSx: 0.00…0.60 Vnom / Blocked tV< PSx: 0.00...100.00 s / Blocked tV<< PSx: 0.00...100.00 s / Blocked tTransient PSx: 0.00...100.00 s / Blocked Hyst. V<> meas. PSx: 1...10 %

OverOverOverOver----/Underfrequency Protection (f<>):/Underfrequency Protection (f<>):/Underfrequency Protection (f<>):/Underfrequency Protection (f<>): Enable PSx: No/Yes valid for y = ‚1‘ to ‚4‘: Oper. mode fy PSx: f / f with df/dt / f w. Delta f/Delta t fy PSx: 40.00...70.00 Hz / Blocked tfy PSx: 0.00...10.00 s / Blocked dfy/dt PSx: 0.1...10.0 Hz/s / Blocked Delta fy PSx: 0.01...5.00 Hz / Blocked Delta ty PSx: 0.04...3.00 s

Overfluxing Protection (V/f):Overfluxing Protection (V/f):Overfluxing Protection (V/f):Overfluxing Protection (V/f): Enable PSx: No/Yes V/f> (alarm) PSx: 1.00...1.20 Vnom/fnom / Blocked V/f(t)> PSx: 1.05...1.50 Vnom/fnom / Blocked V/f>> PSx: 1.05...1.60 Vnom/fnom / Blocked tV/f> PSx: 0...10000 s / Blocked t at V/f=1.05 PSx: 1.0…6000.0 s t at V/f=1.10 PSx: 1.0…6000.0 s t at V/f=1.15 PSx: 1.0…6000.0 s t at V/f=1.20 PSx: 1.0…6000.0 s t at V/f=1.25 PSx: 1.0…6000.0 s t at V/f=1.30 PSx: 1.0…6000.0 s t at V/f=1.35 PSx: 1.0…6000.0 s t at V/f=1.40 PSx: 1.0…6000.0 s t at V/f=1.45 PSx: 1.0…6000.0 s t at V/f=1.50 PSx: 1.0…6000.0 s t at V/f=1.55 PSx: 1.0…6000.0 s t at V/f=1.60 PSx: 1.0…6000.0 s Reset time PSx: 0…60000 s tV/f>> PSx: 0…10000 s / Blocked

Current Transformer Supervision (CTS):Current Transformer Supervision (CTS):Current Transformer Supervision (CTS):Current Transformer Supervision (CTS): Enable PSx: No/Yes Ipos> PSx: 0.05…4.00 Iref Ineg/Ipos> PSx: 0.05…1.00 Ineg/Ipos>> PSx: 0.05…1.00 t(Alarm) PSx: 0.00…10.00 s t(Latch) PSx: 0.00…10.00 s

MeasuringMeasuringMeasuringMeasuring----circuit monitoring circuit monitoring circuit monitoring circuit monitoring (MCM_1,(MCM_1,(MCM_1,(MCM_1, MCM_2, MCM_2, MCM_2, MCM_2, MCM_3, MCM_3, MCM_3, MCM_3, MCM_4): MCM_4): MCM_4): MCM_4): Enable PSx: No/Yes Ineg/Ipos> PSx: 0.20…1.00 Operate delay. PSx: 0.10…100.00 s

ControlControlControlControl

Main function (MAIN): Main function (MAIN): Main function (MAIN): Main function (MAIN): BI active USER: No / Yes SI active USER: No / Yes Inp.asg. fct.block.1: see selection table Inp.asg. fct.block.2: see selection table Op. delay fct. block: 0...60 s Perm.No.mot.drive op: 1…20 CB1 max. oper. cap.: 1...99 CB2 max. oper. cap.: 1...99 CB1 ready fct.assign: see selection table CB2 ready fct.assign: see selection table

External device (DEV01 to DEVExternal device (DEV01 to DEVExternal device (DEV01 to DEVExternal device (DEV01 to DEV00003333):):):): Designat. ext. dev.: see selection table Op.time switch. dev.: 0...254 s Latching time: 0.00...2.54 s Gr. assign.debounce: Group 1 ... Group 3 Interm. pos. suppr.: No / Yes Stat.ind.interm.pos.: No / Yes Oper.mode cmd: Long command / Short command / Time control Inp.asg. sw.tr. plug: see selection table With gen.trip cmd.1: No / Yes With gen.trip cmd.2: No / Yes With close cmd./prot: No / Yes Inp.asg.el.ctrl.open: see selection table Inp.asg.el.ctr.close: see selection table Inp. asg. end Open: see selection table Inp. asg. end Close: see selection table Open w/o stat.interl: No / Yes Close w/o stat. int.: No / Yes Fct.assig.BIwSI open: see selection table Fct.assig.BIwSI clos: see selection table Fct.asg.BI w/o SI op: see selection table Fct.asg.BI w/o SI cl: see selection table

Interlocking logic (ILOCK):Interlocking logic (ILOCK):Interlocking logic (ILOCK):Interlocking logic (ILOCK): valid for y = ‚1‘ to ‚32‘ Fct.assignm. outp. y: see selection table



Operation

Measured operating data

Measured data input (MEASI):Measured data input (MEASI):Measured data input (MEASI):Measured data input (MEASI): Current IDC: 0.00...24.00 mA Current IDC p.u.: 0.00...1.20 IDC,nom Curr. IDC,lin. p.u.: 0.00...1.20 IDC,nom Scaled value IDC,lin: -32000...32000 Temperature T: -40.0...215.0 °C Temperature Tmax : -40.0...215.0 °C Temperature p.u. T: -0.40...2.15 100 °C

Measured data outpuMeasured data outpuMeasured data outpuMeasured data output (MEASO):t (MEASO):t (MEASO):t (MEASO): Current A-1: 0.00...20.00 mA Current A-2: 0.00...20.00 mA

Main function (MAIN):Main function (MAIN):Main function (MAIN):Main function (MAIN): Date: 01.01.1997...31.12.2096 dd.mm.yy Time: 00:00:00...23:59:59 hh:mm:ss Time switching: Standard time / Daylight saving time Frequency f: 40.00...70.00 Hz valid for y = ‚a‘ to ‚d‘: Curr. IPmax,y prim.: 0...25000 A IP,max, prim. delay y.: 0...25000 A IP,max, prim. stored y: 0...25000 A Curr. IP,min, y prim.: 0...25000 A Current IA,y prim.: 0...25000 A Current IB,y prim.: 0...25000 A Current IC y prim.: 0...25000 A Current Ineg y prim.: 0…25000 A Current Ipos y prim.: 0…25000 A Current IN,y prim.: 0...25000 A Current IY, a prim.:0…25000 A Current IY, b prim.:0…25000 A Current IY, c prim.:0…25000 A Voltage V prim.: 0.0...2500.0 kV valid for y = ‚a‘ to ‚d‘: Curr. IP,max,y p.u..: 0.00...25.00 Inom IP, max p.u. delay y.: 0.00...25.00 Inom IP max. p.u.,stored y.: 0.00...25.00 Inom Curr. IP,min,y p.u.: 0.00...25.00 Inom Current IA,y p.u.: 0.00...25.00 Inom Current IB,y p.u.: 0.00...25.00 Inom Current IC,y p.u.: 0.00...25.00 Inom Current Ineg y p.u.: 0.00…25.00 Inom Current Ipos y p.u.: 0.00...25.00 Inom Current IN,y p.u.: 0.000...25.000 Inom Current IY,a p.u.: 0.000...25.000 Inom Current IY,b p.u.: 0.000...25.000 Inom Current IY,c p.u.: 0.000...25.000 Inom IP,max,add p.u.: 0.00…25.00 Inom IP,min,add p.u.: 0.00…25.00 Inom Current IA,add p.u.: 0.00…25.00 Inom Current IB,add p.u.: 0.00…25.00 Inom Current IC,add p.u.: 0.00…25.00 Inom Curr. Ineg, add p.u.: 0.00…25.00 Inom Curr. Ipos, add p.u.: 0.00…25.00 Inom Current IN,add p.u.: 0.000…25.000 Inom Voltage V p.u.: 0.00...25.00 Vnom valid for y = ‚a‘ to ‚d‘: Angle phi AB, end y: -180...180°

Angle phi BC, end y: -180...180°

Angle phi CA, end y: -180...180°

Angle phi A, end a-b: -180...180 ° Angle phi B, end a-b: -180...180 ° Angle phi C, end a-b: -180...180 ° Angle phi A, end a-c: -180...180 ° Angle phi B, end a-c: -180...180 ° Angle phi C, end a-c: -180...180 ° Angle phi A, end a-d: -180...180 ° Angle phi B, end a-d: -180...180 ° Angle phi C, end a-d: -180...180 ° Angle phi NY, end a: -180...180 ° Angle phi NY, end b: -180...180 ° Angle phi NY, end c: -180...180 °

Differential protection (DIFF)Differential protection (DIFF)Differential protection (DIFF)Differential protection (DIFF) Diff. current 1: 0.000...40.000 Iref Restrain. current 1: 0.000...40.000 Iref Diff. current 2: 0.000...40.000 Iref Restrain. current 2: 0.000...40.000 Iref Diff. current 3: 0.000...40.000 Iref Restrain. current 3: 0.000...40.000 Iref

Restricted EarthRestricted EarthRestricted EarthRestricted Earth----Fault Protection (REF_1,Fault Protection (REF_1,Fault Protection (REF_1,Fault Protection (REF_1,REF_2,REF_2,REF_2,REF_2,REF_3):REF_3):REF_3):REF_3): valid for y = ‚1‘ to ‚3‘: Diff. current,REF_y: 0.00...20.00 Iref Restrain.curr.,REF_y: 0.00...20.00 Iref

Thermal Overload Protection (THRM1,Thermal Overload Protection (THRM1,Thermal Overload Protection (THRM1,Thermal Overload Protection (THRM1, THRM2) THRM2) THRM2) THRM2) valid for y = ‚1‘ to ‚2‘: Status replica, THy: -25000...25000 % Object temperat., THy: -40...300 °C Coolant temp. THy: -40...200 °C Pre-trip t. left, THy: 0.0...1000.0 min Status repl., p.u.THy: -25.00...25.00 Object temp. p.u. y .: -0.04...0.30 100 °C Coolant temp. p.u. y: -0.04...0.20 100 °C Temp. offset repl. y: -25000...25000 %

Overfluxing Protection (V/f)Overfluxing Protection (V/f)Overfluxing Protection (V/f)Overfluxing Protection (V/f) Excitation V/f p.u.: 0.00…10.00 Status replica in %: 0…100 % Status replica p.u.: 0.00…1.00



Dimensional drawings

Surface mounted case 40T

Surface mounted case 84T

213.4

242.6

260.2

257.1

147.5

177.5

184.5

TRIP

ALARM

OUT OF SERVICE

HEALTHY

EDIT MODE

147.5

177.5

184.5

434.8

464.0

481.6

257.1

TRIP

ALARM

OUT OF SERVICE

HEALTHY

EDIT MODE




Flush mounted case 40T with panel cutout, version 1 (without angle brackets)

Flush mounted case 84T with panel cutout, version 1 (without angle brackets)

227.9

253.6

177.5

434.8

284.9

259.0

5.0

159.0

168.0

5.0

25.9

410.0

TRIP

ALARM

OUT OF SERVICE

HEALTHY

EDIT MODE

227.9

253.6

177.5

213.4

203.0

155.4

5.0

5.0

181.3159.0

168.0

TRIP

ALARM

OUT OF SERVICE

HEALTHY

EDIT MODE




Flush mounted case 40T with panel cutout, version 2 (with angle brackets and frame)

Flush mounted case 84T with panel cutout, version 2 (with angle brackets and frame)

227.9

253.6

177.5

101.6

6.4

445.9

464.0

101.6

186.5

434.8

464.0

481.6

TRIP

ALARM

OUT OF SERVICE

HEALTHY

EDIT MODE

227.9

253.6

177.5

101.6

6.4

224.5

242.6

101.6

186.5

213.4

242.6

260.2

TRIP

ALARM

OUT OF SERVICE

HEALTHY

EDIT MODE




TRIP

ALARM

OUT OF SERVICE

HEALTHY

WARNING:Connection for remote

control panel only.Not for networkconnection!

213.4 20.7

46.3

177.5

197.5

3.0

181.3

148.0

168.0

107.3

192.5

TRIP

ALARM

OUT OF SERVICE

HEALTHY

EDIT MODE

TRIP

ALARM

OUT OF SERVICE

HEALTHY

WARNING:Connection for remote

control panel only.Not for networkconnection!



Location of the modules

01

01

02

02

03 04

04

05 06 07

07

08 09

09

10

VXTAP

alt.

CH1

CH2

A

ETH

CH2

03 05 06 08 10

6J 6O 4I

8O

alt.

X

4H

01

01

02

02

03 04

04

05 06 07

07

08 09

09

10

03 05 06 08 10

VXTAP

alt.

CH1

CH2

A

ETH

CH2

6J 6O 4I

8O

alt.

X

4H

01

01

02

02

03

03 05 06 07 08 09 15 16 17 18 19 20 2104

VTAP

alt.

CH1

CH2

A

ETH

CH2

4J

1V

4I

8O

T

4J

X

6O

X

24I

Y

4I

X

6I

8O

05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

alt.

10 11 12 13 14

alt.

X

4H

alt.

X

6I

6O

01

01

02

02

03 04

04

05 06 07

07

08 09

09

10

VXTAP

alt.

CH1

CH2

A

ETH

CH2

03 05 06 08 10

4J

1V

6I

8O

4I

8O

T

4J

X

6O

X

24I

alt.

Y

4I

alt.

X

4H

alt.

X

6I

6O

01

01

02

02

03 04

04

05 06 07

07

08 09

09

10

VTAP

alt.

CH1

CH2

A

ETH

CH2

03 05 06 08 10

4J

1V

4I

8O

T

4J

X

6O

T

4J

alt.

X

4H

01

01

02

02

03

03 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

VXTAP

alt.

CH1

CH2

A

ETH

CH2

4J

1V

6I

8O

4I

8O

T

4J

X

6O

X

24I

Y

4I

X

6I

8O

T

4J

05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

alt.

X

4H

alt.

X

6I

6O

01

01

02

02

03

03 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

VTAP

alt.

CH1

CH2

A

ETH

CH2

4J

1V

4I

8O

T

4J

X

6O

X

24I

Y

4I

X

6I

8O

T

4J

05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

X

6I

8O

alt.

X

4H

alt.

X

6I

6O

01

01

02

02

03

03 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

VTAP

alt.

CH1

CH2

A

ETH

CH2

4J1V

4I8O

T

4J

X

6O

X

24I

Y

4I

X

6I8O

T

4J

05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

T

3J

alt.

X

4H

01

01

02

02

03

03 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

VTAP

alt.

CH1

CH2

A

ETH

CH2

4J1V

4I8O

T

4J

X

6O

X

24I

Y

4I

X

6I8O

T

4J

05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 2104

T

3J

alt.

X

4H



X_1

1

2

3

4

5

6

7

8

9

X_1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

Ring

K_01

K_02

K_03

K_04

K_05

K_06

K_07

K_08

Binary

module

U_01

U_02

U_03

U_04

U_05

U_06

Output relays

Pin

X_3

1

2

3

4

5

6

7

8

9

X_2

1

2

3

4

5

6

7

8

9

Type X6I / 8O

Signal inputs

Vin

Vin

Vin

Vin

Vin

Vin

X_1

1

2

3

4

5

6

7

8

9

X_1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

Ring

Type X

High-break

contacts

Pin

X_3

1

2

3

4

5

6

7

8

9

X_2

1

2

3

4

5

6

7

8

9

K_01

4H

K_02

K_04

K_03

+

+

+

+

Binary

module

Connection of the modules (1/2)

’_’ is used as a wildcard for the location (slot number)

X_1

1

2

3

4

5

6

7

8

9

X_1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

Ring

K_01

K_02

K_03

K_04

K_05

K_06

K_07

K_08

Power supply

Type V

U100

Power supply

module

Signal inputs

U_01

U_02

U_03

U_04

Output relays

Pin

X_3

1

2

3

4

5

6

7

8

9

X_2

1

2

3

4

5

6

7

8

9Vin

Vin

Vin

Vin

PE

Vaux

4I / 8O

+-

X_1

1

2

3

4

5

6

7

8

9

X_1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

Ring

Output relays

Pin

X_3

1

2

3

4

5

6

7

8

9

X_2

1

2

3

4

5

6

7

8

9

K_01

K_02

K_03

K_04

K_05

K_06

1)

1)

1)

1)

Type X 6O

Binary

module

1)Binary module X (6O) optional with 4 static outputs, in parallel with closer contact K_02.2, K_03.1, K_04, K_05

Ring

Type T

Pin

4J

Transformer

module

Current measuring

inputs

IA,x

IB,x

IC,x

IN,x

Tx1

Tx2

Tx3

Tx4

X0_1

1

2

3

4

5

6

7

8

X0_2

1

2

3

4

5

6

7

8

Ring

Type T

Pin

3J

Transformer

module

X092

1

2

3

4

5

6

Current measuring

inputs

IA,d

IB,d

IC,d

T41

T42

T43

X091

1

2

3

4

5

6

X032

1

2

3

4

5

6

Ring

Type T

Pin

6J

Transformer

module

Current measuring

inputs

IA,a

IB,a

IC,a

T11

T12

T13

X042

1

2

3

4

5

6

IA,b

IB,b

IC,b

T21

T22

T23

X031

1

2

3

4

5

6

7

8

9

10

11

12

X031

1

4

Ring

Type T

Pin

V

Voltage measuring

input

4J / 1V

Transformer

module

T5

X032

1

2

3

4

5

6

7

8

Current measuring

inputs

IA,a

IB,a

IC,a

IN,a

T11

T12

T13

T14

X031

13

14

1

2

3

4

5

6

7

8



X8

TX

Type A

IEC 61850

optical fiber link ST

Per order

COMM2

wire link

or

optical fiber link SC

X//Y

RS 485

D2[R]

X10

1

2

3

4

5 D1[T]

U20

U17X/Y

U18X/Y

X7

RX

Communication

module ETH / CH2

X12

1

U26

X/Y

U25X//Y

X13

RX

TX

and wire link

RJ45

X11

1

X8

1

Type A

Channel 1

optical fiber link

Per order

##

IRIG-B

time synchronization

Channel 2

wire link only

or wire link

X//Y

RS 485

D2[R]

X10

1

2

3

4

5 D1[T]

U20

X//Y

RS 485

D2[R]

X9

1

2

3

4

5 D1[T]

U19

U17X//Y

U18X//Y

X7

1

U21

Communication

module CH1 / CH2

X_3

1

2

3

4

5

6

X_2

1

2

3

4

5

6

7

8

9

X_1

1

2

3

4

5

6

7

8

9

X_1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

Ring

Analog

module

U_01

U_02

U_03

U_04

Pin

Type Y4I

Signal and measuring

inputs

Measuring outputs

K_01

U_080..20 mA

valid

K_02

U_090..20 mA

valid

U

#U

#

U_05

U_06

U

#

U

#

0..20 mA

PT100

Vin

Vin

Vin

Vin

Connection of the modules (2/2)

’_’ is used as a wildcard for the location (slot number)

X_1

1

2

3

4

5

6

7

8

9

X_1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

15

17

18

19

20

21

22

23

24

25

26

27

Output relays

X_3

1

2

3

4

5

6

7

8

9

X_2

1

2

3

4

5

6

7

8

9

K_01

K_02

K_03

K_04

K_05

K_06

Signal inputs

U_01

U_02

U_03

U_04

U_05

U_06

Ring Pin

Vin

Vin

Vin

Vin

Vin

Vin

Binary

moduleType X6I / 6O

X_1

1

2

3

4

5

6

7

8

9

X_1

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

Ring

Binary

module

Signal inputs

Pin

X_3

1

2

3

4

5

6

7

8

9

X_2

1

2

3

4

5

6

7

8

9

Type X24I

U_17

U_18

U_19

U_20

U_21

U_22

U_23

U_24

U_01

U_02

U_03

U_04

U_05

U_06

U_07

U_08

U_09

U_10

U_11

U_12

U_13

U_14

U_15

U_16

Vin

Vin

Vin



Connection example (P633)

b

A

B

C

A B C

a

c

X051 X052

Current measuring

inputs

2IA

2IB

2IC

T21

T22

T23

T242IN

Ring Pin

Typ T4J

Transformer

module

X071 X072

Current measuring

inputs

3IA

3IB

3IC

T31

T32

T33

T343IN

Ring Pin

Typ T4J

Transformer

module

1

2

3

4

5

6

7

8

1

2

3

4

5

6

7

8

1

2

3

4

5

6

7

8

1

2

3

4

5

6

7

8

X031

1

4

Ring

Type T

Pin

V

Voltage measuring

input

4J / 1V

Transformer

module

T5

X032

1

2

3

4

5

6

7

8

Current measuring

inputs

IA,a

IB,a

IC,a

IN,a

T11

T12

T13

T14

X031

13

14

1

2

3

4

5

6

7

8

A B C

I>



Order information MiCOM P631

Two Winding Transformer Differential Two Winding Transformer Differential Two Winding Transformer Differential Two Winding Transformer Differential

Protection Protection Protection Protection P 6 3 1 -P 6 3 1 -P 6 3 1 -P 6 3 1 - 0000 0000 0000 0000 -308-308-308-308 -4xx-4xx-4xx-4xx -630-630-630-630 -46x-46x-46x-46x -9x-9x-9x-9x xxxx -8xx-8xx-8xx-8xx

Basic device:Basic device:Basic device:Basic device:

Basic device 40TE, pin-terminal connection, 3 -407

Basic device 40TE, ring-terminal connection, 4 -408

basic complement with 4 binary inputs, 8 output relays

and 6 function keys

Mounting option and display:Mounting option and display:Mounting option and display:Mounting option and display:

Surface-mounted, local control panel with text display 3

Flush-mounted, local control panel with text display 4

Surface-mounted, with detachable HMI 7

Flush-mounted,with detachable HMI 9

Processor extension and Current transformer:Processor extension and Current transformer:Processor extension and Current transformer:Processor extension and Current transformer:

With DSP-Coprocessor, Inom = 1 A / 5 A (T11...T13 / T21...23) 2) 12) 8

Inom = 1 A / 5 A (T11...T13 / T21...23) 2) 9

Power supply and additional binary I/O options:Power supply and additional binary I/O options:Power supply and additional binary I/O options:Power supply and additional binary I/O options:

VA,nom = 24 VDC 3

VA,nom = 48 ... 250 VDC / 100 ... 230 VAC 4

VA,nom = 24 VDC and 6 output relays, 4 with thyristor 6

VA,nom = 48 ... 250 VDC / 100 ... 230 VAC 7

and 6 output relays, 4 with thyristor

VA,nom = 24 VDC and 6 output relays 8

VA,nom = 48 ... 250 VDC / 100 ... 230 VAC and 6 output relays 9

VA,nom = 24 VDC and 4 high break contacts C

VA,nom = 48 ... 250 VDC / 100 ... 230 VAC and 4 high break contacts D

Switching threshold on binary inputs:Switching threshold on binary inputs:Switching threshold on binary inputs:Switching threshold on binary inputs:

>18 V (standard variant) Without order extension No.

>90 V (60...70% of VA,nom = 125...150 V) 8) -461

>155 V (60...70% of VA,nom = 220...250 V) 8) -462

>73 V (67% of VA,nom = 110 V) 8) -463

>146 V (67% of VA,nom = 220 V) 8) -464

With communication / information interface:With communication / information interface:With communication / information interface:With communication / information interface:

Without Without order extension No.

Protocol IEC 60870-5-103 -91

Protocol can be switched between: -92

IEC 60870-5-101/-103, Modbus, DNP3, Courier

and IRIG-B input for clock synchronization

and 2nd interface (RS485, IEC 60870-5-103)

For connection to wire, RS485, isolated 1

For connection to plastic fiber, FSMA connector 2

For connection to glass fiber, ST connector 4

Protocol IEC61850, single connection -94

For connection to 100 Mbit/s Ethernet, glass fiber SC and wire RJ45 6


For connection to 100 Mbit/s Ethernet, glass fiber ST and wire RJ45 7


Language:Language:Language:Language:

English (German) 4) Without order extension No.

Px40 English (German) 4) -800

German (English) 4) Not yet available - On request -801

French (English) 4) Not yet available - On request -802

Spanish (English) 4) Not yet available - On request -803

Polish (English) 4) Not yet available - On request -804

Russian (English) 4) 7) Not yet available - On request -805

2) Switching via parameter, default setting is underlined!

4) Second included language in brackets

7) Hardware option, supports cyrillic letters instead of special West. Europe characters

8) Standard variant recommended if higher pickup threshold not explicitly required by the application

12) Current Transformer Supervision (CTS) requires DSP-Coprocessor





Protection Protection Protection Protection P 6 3 2 -P 6 3 2 -P 6 3 2 -P 6 3 2 - 0000 1111 -308-308-308-308 -4xx-4xx-4xx-4xx -630-630-630-630 -46x-46x-46x-46x -9x-9x-9x-9x xxxx -8xx-8xx-8xx-8xx





and 6 function keys








Inom = 1 A / 5 A (T11...T14 / T21...24) 2) 9

Voltage transformer:Voltage transformer:Voltage transformer:Voltage transformer:

Vnom = 50 ... 130 V (1-pole) 1

Additional binary I/O options:Additional binary I/O options:Additional binary I/O options:Additional binary I/O options:

Without 0

With 1 binary module (add. 6 binary inputs and 8 output relays) 1

With 1 binary module (add. 6 binary inputs and 6 output relays (2-pole)) 5

for the control of up to 3 switchgear units


VA,nom = 24 VDC 3

VA,nom = 48 ... 250 VDC / 100 ... 230 VAC 4


VA,nom = 48 ... 250 VDC / 100 ... 230 VAC 7






Further add. options:Further add. options:Further add. options:Further add. options:

Without 0

With analog module 2

With binary module (add. 24 binary inputs) 4








>90 V (60...70% of VA,nom = 125...150 V) 8) -461

>155 V (60...70% of VA,nom = 220...250 V) 8) -462

>73 V (67% of VA,nom = 110 V) 8) -463

>146 V (67% of VA,nom = 220 V) 8) -464



Protocol IEC 60870-5-103 -91

Protocol can be switched between: 18) -92







Protocol IEC61850, single connection 18) -94







Px40 English (German) 4) Not yet available - On request -800

German (English) 4) -801










18) Communication option required for control function




Three Winding Transformer Differential Three Winding Transformer Differential Three Winding Transformer Differential Three Winding Transformer Differential







and 6 function keys








Inom = 1 A / 5 A (T11...T14 / T21...24) 2) 9

Inom = 1 A / 5 A (T31...T34) 2) 9


Vnom = 50 ... 130 V (1-pole) 1


Without 14) 0


With 2 binary modules (add. 12 binary inputs and 16 output relays) 5) 2

With 1 binary module (add. 6 binary inputs and 6 output relays (2-pole)) 5


With 1 binary module (add. 6 binary inputs and 6 output relays (2-pole)) 5) 8


and 1 binary module (add. 6 binary inputs and 8 output relays)


VA,nom = 24 VDC 3

VA,nom = 48 ... 250 VDC / 100 ... 230 VAC 4


VA,nom = 48 ... 250 VDC / 100 ... 230 VAC 7







Without 0

With analog module 5) 2

With binary module (add. 24 binary inputs) 5) 4

With analog module and binary module (add. 24 binary inputs) 5) 6




Three Winding Transformer Differential Three Winding Transformer Differential Three Winding Transformer Differential Three Winding Transformer Differential




>90 V (60...70% of VA,nom = 125...150 V) 8) -461

>155 V (60...70% of VA,nom = 220...250 V) 8) -462

>73 V (67% of VA,nom = 110 V) 8) -463

>146 V (67% of VA,nom = 220 V) 8) -464



Protocol IEC 60870-5-103 -91

Protocol can be switched between: 18) -92







Protocol IEC61850, single connection 18) -94







Px40 English (German) 4) -800

German (English) 4) Not yet available - On request -801







5) For 84TE version only




18) Communication option required for control function




Four Winding Transformer Differential Four Winding Transformer Differential Four Winding Transformer Differential Four Winding Transformer Differential






and 6 function keys








Inom = 1 A / 5 A (T11...T14 / T21...24) 2) 9

Inom = 1 A / 5 A (T31...T34 / T41…T43) 2) 9


Vnom = 50 ... 130 V (1-pole) 1


Without 14) 0



VA,nom = 24 VDC 3

VA,nom = 48 ... 250 VDC / 100 ... 230 VAC 4


VA,nom = 48 ... 250 VDC / 100 ... 230 VAC 7







Without 0

With analog module 2

With binary module (add. 24 binary inputs) 4

With analog module and binary module (add. 24 binary inputs) 5) 6




Four Winding Transformer Differential Four Winding Transformer Differential Four Winding Transformer Differential Four Winding Transformer Differential




>90 V (60...70% of VA,nom = 125...150 V) 8) -461

>155 V (60...70% of VA,nom = 220...250 V) 8) -462

>73 V (67% of VA,nom = 110 V) 8) -463

>146 V (67% of VA,nom = 220 V) 8) -464



Protocol IEC 60870-5-103 -91

Protocol can be switched between: -92







Protocol IEC61850, single connection -94







Px40 English (German) 4) Not yet available - On request -800

German (English) 4) -801










Schneider Electric As standards, specifications and designs change from time to time, please ask for contribution

35, rue Joseph Monier – CS30323 of the information given in this publication. F - 92500 Rueil-Malmaison cedex (France)

Tel: +33 (0)1 41 29 85 00

Fax: +33 (0)1 41 29 71 00

RCS Nanterre 954 503w

Capital social 896 313 776 Design: Schneider Electric

www.schneider-electric.com Photos: Schneider Electric

EnergyAutomation-P63x-TDS-630-EN 03 / 2011

2010 Schneider Electric. All rights reserved

p63x technicaldatasheet en 630a

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