energy automation for oil & gas industry - siemens protection ct powered - no auxiliary supply...
TRANSCRIPT
Energy Automation
for Oil & Gas Industry
Energy Sector
© Siemens AG 2008
Energy Automation Slide 2
Process
Automation
Enterprise Resource
Planning (ERP) Enterprise Resource
Planning (ERP)
Manufacturing
Execution
System (MES)
Totally Integrated
Automation
Totally Integrated
Power
Total Building
Solutions
Enterprise Resource
Planning (ERP)
Manufacturing
Execution
System (MES)
Building
Automation
Field
Level
Substation
Automation
System (PAS)
Field
Level
Protection and
Bay Control
HV & MV
Load Shedding
System (LSS)
LV Distribution
Energy Management
System (EMS)
Communication
Hardwired
Busbar / Power cable
Energy Automation for the Oil&Gas Industry
One Piece of a Whole
Energy Automation Slide 3
Nothing runs without electricity !!!
An absolute safe and dependable supply of electrical energy is needed- whether on drilling
platforms or at the refinery, an stormy seas or at extremely low temperatures.
The following key tasks must be taken into account:
Protection and Power Quality – Protecting power infrastructure
Station Automation – Economical control of operations
Energy Management – Integral control of power requirement
Energy automation not only protects your system against possible damages, it also ensures
consistent quality of the electrical power supply - and thus of your processes as well.
In addition, it makes it possible to react quickly to unforeseeable events and to avoid, or at
least minimize, any interruption of the supply
Energy Automation for the Oil&Gas Industry
The purpose
Energy Automation Slide 4
Energy Automation for the Oil&Gas Industry
Our solution portfolio
Energy market
EMM
FDWH
PROPHET Solutions
Communications
and networking
PowerLink PLC / DLC
Modems
AMIS
Tools
Spectrum PowerCC IMM /
Graphical Designer
SICAM PAS UI / Graphical
Designer
TOOLBOX II
DIGSI
Control centers
Spectrum PowerCC
Spectrum Power 4
Station automation
SICAM PAS
SICAM 1703 / SICAM 230
RTU´s
SICAM 1703
SICAM eRTU / miniRTU
TG 805 / TG 5700
Protection / power quality /
field control stations
SIPROTEC
REYROLLE
SICAM BC 1703 ACP
SIMEAS
Energy Automation Slide 5
Our Integrated Energy Automation Solution Portfolio
SIPROTEC SIMEAS SICAM
EMCS Energy Management
and Control
Power CC
Spectrum
Energy Automation Slide 6
1950
1960
1970
1980
1990
2000
SIPROTEC® V1-V3
SIPROTEC® V4
Electromechanical Relais
Analog Relais
Digital Protection Relais
Control
Almost 1.000.000
SIPROTEC V1-V4 Relais
in Operation (08/2008)
Numerical Protection SIPROTEC®
More than 90 Years of Experience
Energy Automation Slide 7
SIPROTEC easy
SIPROTEC Compact Class
SIPROTEC 4
Numerical Protection SIPROTEC®
Actual Portfolio
Energy Automation Slide 8
Generator Protection 7UM Differential Protection 7UT
Distance Protection 7SA6 Line Differential Protection 7SD6 Abzweigschutz 7SA5/6 Busbar Protection 7SS5 Transformer Protection UT5/6
Line Differential Protection SD5/6 Overcurrent Protection 7SJ6
Numerical Protection SIPROTEC®
Application Areas
Energy Automation Slide 9
Functionalit
y
Numerical Protection SIPROTEC®
For each Application the right Relay
Amount of process information
SIPROTEC Compact Class
Protection
SIPROTEC Easy
Protection
SIPROTEC 4
Protection & Control
Energy Automation Slide 10
7SJ45
Overcurrent-Time Protection
CT Powered - no auxiliary supply required
7SJ46
Overcurrent-Time Protection
Auxiliary power supplied
Numerical Protection SIPROTEC®
Scope of Products: SIPROTEC easy
Energy Automation Slide 11
7SJ600 Overcurrent / Overload, 3 CT’s
7SJ601 Overcurrent (reduced functionality)
7SJ602 Overcurrent / Overload, 4 CT’s
7RW600 Over- Undervoltage / Frequency
7SD600 Pilot Wire Line Differential Protection
7SV600 Breaker Failure Protection
7SS60 Busbar Differential Protection
7VH60 High Impedance Diff. Protection
7SN600 Transient Earth-Fault Relay
Numerical Protection SIPROTEC®
Compact Class
Energy Automation Slide 12
7SJ61 O/C and E.F. Protection
7SJ62 Directional O/C and E.F. Protection
7SJ63 as 7SJ62 with large display
7SJ64 as 7SJ63 with Synchrocheck
7SA52 Distance Protection, 4 plug-in com ports
7SA6 Distance Protection, optional large display
7SD5 Line Diff.+ Dist. Protection in one relay
7SD61 Line Differential Protection; 2 terminals
7UM61 Generator/ Motor Protection
7UM62 as 7UM61 with Differential protection
7UT6 Transformer Differential Protection
7SS52 Distributed Numerical Busbar CB Failure Protection
Numerical Protection SIPROTEC®
SIPROTEC 4: Protection & Control
Energy Automation Slide 13
Parameterization, Programming and Testing with DIGSI
Analyzes and Evaluation with SIGRA
CFC Programming Configuration
Testing
Analyzing SIGRA
Energy Automation Slide 14
Energy Automation
Products
SIPROTEC SIMEAS SICAM
EMCS Energy Management
and Control
Power CC
Spectrum
Energy Automation Slide 15
Power Quality
What is Power Quality?
power quality (voltage) security of supply
outage through
break down of
power supply
network events
Power Quality
network events network events
voltage dips
voltage sags
Interruption
surge
flicker
harmonics
system balance
voltage change
Energy Automation Slide 16
Transient Over
voltage
Long Interruption
Flicker Over voltage
Voltage Dip
Slow Voltage
Changes
Rapid Voltage
Changes
Short Interruption
10 ms to 1min < 3 min
> 3 min
Plt = 1
few sec.
1 sec to few ms
>110% UN < UL-L
< 1 %
<90
%..
.>1%
< ±
10%
< ±
5%
Up
to
6kV
1 %
-10 %
100 %
U eff
+10 %
Power Quality
Characteristics of voltage quality (1)
Energy Automation Slide 17
Characteristics Range Parameters
LV MV base factor Interval Observation
period
percentage
Frequency 49,5 Hz to 50,5 Hz
47 Hz to 52 Hz
mean value 10 s 1 week 95%
100%
Slow voltage changes 230 V 10 % U 10 % rms value 10 min 1 week 95%
Rapid voltage changes
5%
max. 10 %
4%
max. 6 %
rms value 10 ms
1 day
100%
Flicker (only long term
flicker)
PR = 1
2 h
1 week
95%
Voltage dips ( <= 1 min)
few 10 to 1000 per year (lower 85 % Uc)
rms value
10 ms
1 year
100%
Short interruption (< 3 min) few 10 to 100 per year (lower 1 % Uc) rms value
10 ms
1 year
100%
Long interruption (> 3 min) few 10 to 50 per year (lower 1 % Uc)
rms value
10 ms
1 year
100%
temporary power frequency
over voltage (L - N)
< 1,5 k V
1,7 to 2,0 U rms value
10 ms
not specified
100%
Transient Over voltages
(L - N)
< 6 kV
peak value
no
not specified
100%
Asymmetry
2 %
in special cases up to 3 %
rms value
10 min
1 week
95%
Harmonics See table harmonics, THD 8 %
rms value
10 min
1 week
95%
Interharmonics
under discussion
under discussion
Power Quality
Characteristics of voltage quality (2)
Energy Automation Slide 18
Power Quality
Types of influence
In the power distribution network
- Atmospheric influence (e.g. thunder storm, frost)
- Other external impact (e.g. cable damage through excavator work)
In a neighboring facilities
- Industrial plant (e.g. welding transformer, furnace in steel industry,
press shop in car industry)
In the entire power supply system
- Short cuts
- Start of big loads (e.g. big motors)
Energy Automation Slide 19
Record of PQ-data and determination of the origin
Record Data
transmission Archiving
Compensation of reactive power and harmonics Prevent voltage dips UPS
Define Measures Improvement
Analyses
Understand and evaluate according PQ-Regulations
Power Quality
Tasks: Measure, Evaluate and Improve
Energy Automation Slide 20
Energy Automation for Oil and Gas Industry
Our Power Quality Portfolio – SIMEAS Hardware
SIMEAS P Power Meter for Electrical Power
Measuring & Monitoring
SIMEAS Q Power Quality Recorder for
Distribution Networks
SIMEAS R Disturbance and PQ Recorder
SIMEAS R PMU Disturbance Recorder with
PMU Feature
Energy Automation Slide 21
Power Quality
Configure, Transmission, Evaluation and Archiving with OSCOP
Energy Automation Slide 22
Disturbance Recorder SIMEAS R
Power Quality Recorder SIMEAS Q
Power Meter SIMEAS P Digital Transducer SIMEAS T
Power Quality Measurement with SIMEAS®
Application Areas
Energy Automation Slide 23
Level 1
Level 2
Level 3 LANWAN
Substation - LAN
SIMEAS R
Fault
Recorder
Analysis Parameterization Central Archive
RMS values
Fault
Location
Automatic Mode:
Data collection
Local Archive
Parameterization
Analysis
Office LAN (Intranet)
DAKON XP (PC with OSCOP)
Power Quality
Structure of a Power Quality Recording System
Field Level
Substation Level
Control Center Level
Energy Automation Slide 24
1970
1980
1990
2000
Electromechanical Recorder
Analog Recorder
Digital Recorder
OSCILLOSTORE
P531
SIMEAS N
OSCILLOSTORE R
SIMEAS R
SIMEAS Q
QUALIMETRE
More than 6.000
SIMEAS R/Q in Operation
Power Quality Measurement with SIMEAS®
More than 30 Years of Experience
Energy Automation Slide 25
Power Quality
Benefit of Power Quality Measurement
Task Explanation Benefit
Continuous monitoring
and recording of the
network power quality in
each station
1. Recognition of critical situations before the error
2. Early identification of possible trends
3. Support for clarification
4. Compliance with Grid codes
5. Support for Power Quality Audit
Saves money
Documentation of network
events
1. Short reaction time
2. Reduction of downtime (preventive maintenance)
3. Support for clarification
Saves money
Saves time
Automatic analyses of
fault recordings and
alarms of connected
disturbance recorders and
relays
Identification of weak points in the power network
1. Ferro resonance
2. Circuit breaker (switching time)
3. Transient faults caused for example through trees
Saves money
Energy Automation Slide 26
Energy Automation
Products
SIPROTEC SIMEAS SICAM
EMCS Energy Management
and Control
Power CC
Spectrum
Energy Automation Slide 27
SICAM PAS – Power Automation System
Content
Introduction
SICAM family
SICAM Power Automation System
Technical Highlights
Your benefits using SICAM PAS
Energy Automation Slide 28
SICAM PAS – Power Automation System
Experience is the base of our competence
Telecontrol and Substation Control for more than 70 years
Power Automation for more than 20 years
1996 2010
Energy Automation Slide 29
SICAM Family –
The right solution for every application
SICAM
PAS
SIPROTEC
SICAM
mini/micro
RTU
SICAM
PAS CC SICAM
eRTU
SICAM
Diamond
Energy Automation Slide 30
F1
Log.IN1
Log.IN2 F2
>1
Log.IN3
1503
1530
2173
1530
2173
8888
1530
1100
Log.Out1
Control Center Control Center
SICAM PAS
Configuration and functions
IEC 60870-5-104 Time signal
IEC 60870-5-101
DNP V3.00
SICAM PAS CC
SICAM PAS
Stand-alone
system
Distributed process interface Process visualization and archiving Telecontrol interface Automation function with CFC Online configuration
Profibus FMS/IEC 60870-5-103
Modbus/Profibus DP
IEC 60870-5-101/DNP V3.00
Ethernet
Energy Automation Slide 31
F1
Log.IN1
Log.IN2 F2
>1
Log.IN3
1503
1530
2173
1530
2173
8888
1530
1100
Log.Out1
SICAM PAS
Distributed system with higher performance
Control Center Control Center
IEC 60870-5-104
Time signal
IEC 60870-5-101
DNP V3.00
SICAM PAS CC
Profibus FMS
IEC 60870-5-103
Modbus/Profibus DP IEC 60870-5-101
DNP V3.00
SICAM PAS
Distributed
System
Ethernet
Energy Automation Slide 32
Control Center
IEC 60870-5-104
SICAM PAS
Redundant
System HMI Clients
Full Server
Station bus
Ethernet
IEC 61850 Profibus FMS
SICAM PAS
High availability by redundancy & IEC 61850
Energy Automation Slide 33
F1
Log.IN1
Log.IN2 F2
>1
Log.IN3
1503
1530
2173
1530
2173
8888
1530
1100
Log.Out1
Control Centre Maintenance
SICAM PAS
High flexibility through new interfaces
IEC 60870-5-104 TCP/IP Time signal
SICAM PAS CC SIMATIC WinCC
Profibus FMS/IEC 60870-5-103
IEC 60870-5-101/DNP V3.00
SICAM PAS
IT-Welt
OPC
SIMATIC
Ethernet
Energy Automation Slide 34
Communication with Control Centres
IEC 60870-5-101
IEC 60870-5-104 (Ethernet TCP/IP)
DNP V3.00
Connection of IEDs and Satellite RTUs
IEC 61850
IEC 60870-5-103,
IEC 60870-5-101 (incl. dial-up traffic)
Profibus FMS, Profibus DP
SINAUT LSA protocol
Data exchange
with OPC Server and Client
SICAM PAS
Technical Highlights
Energy Automation Slide 35
SICAM PAS
Technical Highlights
Local visualization, archiving and logging with SICAM PAS CC (SICAM PAS Control Center) based on SIMATIC WinCC
Data acquisition and trasmission with real time stamp, 1ms solution
Support of the substation automation functions Switching authorities, bay and station blocking
Automation functions with CFC
Automatic transmission and central archiving of fault recording of protection devices connected with IEC 60870-5-103, Profibus FMS and IEC 61850
Redundancy in the bay, station and HMI level
Energy Automation Slide 36
SICAM PAS – Power Automation System
Your benefits using our technology
Efficient operation
Clearly structured HMI display
with SICAM PAS CC based on
Windows technology
Operational Security
Two-stage switching
Security against unauthorized switching
Safer working conditions through the functions like switching authority, bay and/or station blocking
Fast error detection and localisation
Energy Automation Slide 37
SICAM PAS – Power Automation System
Your benefits using our technology
All system components are continuously monitored
SICAM PAS Station Unit:
Fan less, without rotating parts
„Thin system“ based on embedded System especially tailored for the use in substation automation
Monitoring functions (watchdog, temperature…)
Automation function to optimize the plant and increased availability (e.g. shedding)
Tools on board for commissioning, testing
and in operation
Online data in clear text are available for diagnostic purposes
Operational costs and maintenance
Energy Automation Slide 38
SICAM PAS – Power Automation System
Your benefits using our technology
Easy expandability
Many interfaces in different structures
System can be adapted and grow in proportion with the requirements of the substation
Extensions can be executed during operation (onlinge)
IEC 61850
IEC 101
IEC 104 SICAM
PAS
IEC 103
OPC
Auto-
mation
DNP V3.00
Energy Automation Slide 39
Easy and user friendly engineering results in quicker engineering,
thus saving time and costs
Consequent use of data exchange avoid double data input and reduce
typing mistakes
No generation of the parameterization required
No loading of parameters in a separate runtime system
SICAM PAS – Power Automation System
Your benefits using our technology
Easy engineering
Tooltips, Online-help and plausibility checks
supports the user
Alterations can be done by the customer
independent of the supplier‘s expert
Energy Automation Slide 40
SICAM PAS – Power Automation System
Your benefits using our technology
System based on many years of experience developed on a modern
future-oriented platform
Consequent use of standard protocols and interfaces
IEC 61850 is worldwide accepted and required
High distribution of Ethernet (90%)
Easy and cost-optimized migration of substations of the years from
1986 to 2003 – Inexpensive Refurbishment
Our experience in telecontrol and substation automation system
secures the investment for the future:
SICAM established on the market
since 1996
SINAUT LSA / LSA 678 since 1986
Investment security
Energy Automation Slide 41
SICAM PAS – Power Automation System
Your benefits using SICAM PAS
SICAM PAS defines the way to the future
Connection of
existing devices
and substations
Support of
IEC 61850
… builds the bridge to the past
…provides the entry into the IT-wold
…with the right partner PTD EA
Energy Automation Slide 42
1970
1980
1990
2000
Electronic Automation
Digital Substation Control
Industry Standards
LSA
SINAUT LSA
SCAM SAS
SICAM PCC
SICAM PAS
More than 2500
SICAM Systems in Operation
Power Automation
More than 70 Years of Experience
Telecontrol and Substation Control for more than 70 years
Power Automation for more than 20 years
Energy Automation Slide 43
SICAM TM 1703 mic Terminal Module for micro control is a
low-cost, modular, telecontrol unit.
SICAM TM 1703 ACP Compact telecontrol unit with
automation functionality for small to mid size system.
SICAM AK 1703 ACP Modular and flexible control and
automation system based on sub rack technology for every requirement from small and compact systems up to very large systems.
SICAM PAS Power Automation System based on
PC-Technology.
Power Automation
Actual Portfolio
Energy Automation Slide 44
Fu
nc
tio
na
lity
Amount of process information
Ga
tew
ay
Au
tom
ati
c
En
han
ce
d
SICAM AK 1703 SICAM PAS
SICAM TM 1703 mic
SICAM TM 1703 ACP
Power Automation
For each Application the right System
Energy Automation Slide 45
427
72
1776
192
34
Status : January 2004
2500 SICAM applications since market launch August 1996
Power Automation
SICAM applications are in use world wide
Energy Automation Slide 46
Energy Automation
Products
SIPROTEC SIMEAS SICAM
ENMC Electrical Network
Monitoring and Control
Power CC
Spectrum
Energy Automation Slide 47
Electrical Network Monitoring and Control
The purpose
Energy Automation Slide 48
Electrical Network Monitoring and Control
To keep always the overview
Energy Automation Slide 49
Electrical Network Monitoring and Control
Tasks of a Electrical Network Monitoring and Control Systems
Data Acquisition and Monitoring of:
States and binary information occur in the power system (switch gear, circuit breaker, network sections, IO-channels etc.)
RMS-Values (voltage, current, etc.)
Counter-values (energy, CB, etc.)
Fault records (protection relays)m
Automation and control (also remote) of:
IEDs (e.g. protection relays)
Transformer/voltage control
Interlocking
Switch gear
Logging:
Alarm & message (also to remote receivers)
Operation and control tasks
System behavior
Error logging
Others:
HMI (local/remote)
Evaluation (fault records, mean values etc.)
Energy applications (load management, network analyses, operation planning etc.)
Energy Automation Slide 50
Electrical Network Monitoring and Control
Typical Architecture
SCADA- Functionality
Applications
System Services
Base System
Data Management
Data Model (CIM based)
Configuration
Parameter (HW / SW)
OPC Interface Automation Technology
Communication
Substation Automation IEC -101, -104, DNP
ICCP
Distribution &
Transmission
Network Analysis
Forecast &
Scheduling
Applications
Load
Management
E/G/W/DH
Archive ...
Control Center Desktops
Decentralized Desktops
System Management
Data Management
User Interface
HMI
OPC OLE for Process Control
OLE Object Linking and Embedding
SCADA Supervisory Control and Data Acquisition
CIM Common Information Model
DNP Distributed Network Protocol
ICCP Inter-control Center
Communications Protocol
Energy Automation Slide 51
Spectrum PowerCC Windows-based control system for power generation, medium size transport/distribution networks and industry control centers.
SINAUT Spectrum
Unix-based automation system for large and medium sized transport and distribution networks.
Generation
SCADA
BASE
Customized
Applications
Transmission Trading
Distribution
Spectrum PowerCC
Electrical Network Monitoring and Control System
Energy Automation Slide 52
HIS
EA
DNA
DSM
TNA
OA
FA
LTOP
SA
PA EDM
OTS
HIS Historical Information System
EA Energy Accounting Processing
OA Operations Applications
DNA Distribution Network Analyses
DSM Demand Side Management
TNA Transmission Network Applications
FA Forecasting Applications
LTOP Long Term Operational Planning
SA Scheduling Applications
PA Power Applications
EDM Energy Data Management
EMM Energy Market Management
OTS Operator Training Simulator
Spectrum PowerCC
Dedicated Applications for optimized Operation
BASE
SCADA
Customized
Applications
Energy Automation Slide 53
Spectrum PowerCC
Base System
Provides a state-of-the art and persistent system
architecture
Built on standardized hardware and software IT
technologies including object-oriented design
principles
Supports existing communication and industry
standards (e.g. IEC, OPC)
Appropriate application of well-accepted and
established 3rd party products (e.g. RDBMS
ORACLE)
Follows the Component Architectural Model
Architectural Approach
Energy Automation Slide 54
Spectrum PowerCC
Base System
Spectrum PowerCC System Concept
... consistent deployment of latest Technologies and Standards
Spectrum PowerCC
Energy Automation Slide 55
Spectrum PowerCC
Base System
Object Data Model
Customer-defined
Object Types
Standard
Object Types
Customer-entered
Objects (Instances)
Standard Object Types
Standard delivery with the product
Based on CIM standard definition
Examples: Generator, Transformer, Tariff
contract, Server
Customer-defined Object Types
Dependent on industry sector and division
Created while the project is being carried out
Customer-entered Objects (Instances)
Are entered by the user during the data input
phase
Based on prepared object types (templates)
Energy Automation Slide 56
Spectrum PowerCC
Base System
Modular and open system architecture build on component-oriented and object-oriented design
Windows and web technology
Standardized Industry PC hardware
Cluster system technology
Fully Client/Server configuration on the basis of standard LANs and protocols
Open Interfaces on the basis of the Microsoft component technology (ODBC, OLE, OPC, etc.)
Linking of Microsoft Tools via OLE (e.g. EXCEL table formats)
RDBMS base with open interfaces
Nationally and internationally standardized transmission protocols (IEC 60870-5, IEC 60870-6)
Common Information Model IEC 61970 (CIM)
Standards and Components
Energy Automation Slide 57
Spectrum PowerCC
Base System
Modular and open system architecture build on component-oriented and object-oriented design
Distributed functionality with flexible deployment of software functions to hardware components for scalable performance and availability
Object Oriented engineering system with IEC compliant implementation of power system data model (CIM - IEC Standard 61970)
System platform MS Windows, providing user familiarity including simplified system maintenance and easy systems integration (e.g. office environment)
Use of Windows-based de-facto industry standard Automation-System WinCC as graphic user interface
Web-Enabled User Interface
Job-based data maintenance with no interrupt of process control during on-line activation and “Undo”-function
System self-supervision of all major and vital system components
Multilevel security concept
Redundancy and availability features for highest availability and data-safety
Highlights
Energy Automation Slide 58
Electrical Network Monitoring & Control
Overview
Administration Area Substation
Control & Protection (SIPROTEC)
Energy- / Power Management
Ethernet TCP/IP
Power generation
Main Substation
. . . .
Further Substations
G
D
Y
G
D
Y
. . . .
Control
Monitoring
Distribution
management
Data archives
Reports
Interlocking
Protection
Power Quality
Data exchange to process
Load shedding
Generation scheduling
Generation control / Voltage
control
Synchro-check
Synchronization
Bus-tie transfer
1 ms resolution (SOER)
2.5 kV Isolation
IEC Standards
01 02 . . . 03 18 16 17
Station Controler
Level 1
Level 2
Level 3
Energy Automation Slide 59
Electrical Network Monitoring & Control
Large Configuration
LAN (redundant)
Bell
Power System Object
Server-PC (redundant)
Application Server-PC
(redundant)
Client
Bell
Time
Receive
r (e.g. GPS)
Internet
Field Level
Front-end Server-PC (redundant)
IED
Load Shedding
Server-PC
Load Shedding
Control Unit (redundant)
Protection Relay
MCU/MCC
Real-Time Server
(redundant)
SCADA Field Comm.
Load Shedding
Communication Server-PC
(redundant)
External Comm.
Monitoring & Reporting Network Analysis
Distribution Mgt.
Power & Scheduling
Level 1
Level 2
Level 3
Web Client Web Client Web Client
Client
Substation Level
Control Center Level
Energy Automation Slide 60
Integrated solution: Supervise your low- and medium voltage
system with one system.
Central human-machine interface: All activities can be carried
out from one central operator terminal.
Highest supply reliability: Thanks to Load Shedding functionality
High availability and reliability: Thanks to tested components
and the use of proven standards
Optimum utilization of electrical energy: Thanks to load
management functions
Lower operating and maintenance costs: Thanks to the use
of automatic functions
Compliance with local energy saving and environ-mental issues: Thanks to comprehensive monitoring and reporting
functions
Concrete benefits for you:
Energy Automation for the Oil&Gas Industry
One System – many advantages
Energy Automation Slide 61
Energy Automation for the Oil&Gas Industry
To say it with a few words
Pro
ductivity
Protect Control Analyze Improve
Protect against blackouts and
damages.
Reduces downtimes due to
fast error detection and
analyses.
Reduces operating and
maintenance costs.
Reduces energy costs by an
optimized consumption of
energy.
Optimal investment by
knowing the system behavior
and its operating figures.
Energy Automation Slide 62 Jul-08
Thank you for your attention