abb bv - 1 6-11-2001 power management for industrial plants. industrial it for power ems
TRANSCRIPT
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Power Management for Industrial Plants.
IndustrialIT forPower EMS
IndustrialIT for Power EMS
Electrical Process
System configuration
Functionality Power EMS
References
Benefits
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Critical Loads
Limited In-plant Generation
Insufficient reliability of Public Grid
Why Power EMS?
Load Shedding}Several Generators
Contracted Power ImportationPower Control}
Different Electrical Operational
Configurations possibleMode Control}
Complex Distribution Networks
“Local only” Control facilitiesSCADA}
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Why ABB Power EMS?
Deep knowledge of the electrical process 15 years experience in Power EMS in many projects
(green-field and running plants) Standard software, well documented, tested, proven technology Fast Response Time for Load Shedding, Mode Control, Power
Control, Re-acceleration High Resolution and Accuracy of
Sequence of Event recording Comply to class 3 EMC immunity Single responsibility: One supplier for Power EMS integrated with
protection, governor, excitation, tapchanger, Motor Control Centre, Variable Speed Drive, etc.
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M MMM M MMM MMM M MM MM M MMM
M MMM
G G
M MM M
G G
M MM M
6 kV
GGG GGG
MM
33 kV
A B B T r a n s m i t O yN e t w o r k P a r t n e r
FE E D E R TE R M IN A L R E F5 4 1A B B N e t w o r k P a r t n e r
U a ux = 80 .. .2 65 Vd c / ac
fn = 50 H z
In = 1 /5 A (I)
1 M RS xxxxxx
9 8 15 0U n = 10 0 /1 1 0 V (U )
U on = 1 0 0 /1 1 0 V (U o )
Ion = 1 / 5 A (Io )
9 50 9
A B B T r a n s m i t O yN e t w o r k P a r t n e r
FE E D E R TE R M IN A L R E F5 4 1A B B N e t w o r k P a r t n e r
U a ux = 80 .. .2 65 Vd c / ac
fn = 50 H z
In = 1 /5 A (I)
1 M RS xxxxxx
9 8 15 0U n = 10 0 /1 1 0 V (U )
U on = 1 0 0 /1 1 0 V (U o )
Ion = 1 / 5 A (Io )
9 50 9
A B B T r a n s m i t O yN e t w o r k P a r t n e r
FE E D E R TE R M IN A L R E F5 4 1A B B N e t w o r k P a r t n e r
U a ux = 80 .. .2 65 Vd c / ac
fn = 50 H z
In = 1 /5 A (I)
1 M RS xxxxxx
9 8 15 0U n = 10 0 /1 1 0 V (U )
U on = 1 0 0 /1 1 0 V (U o )
Ion = 1 / 5 A (Io )
9 50 9
A B B T r a n s m i t O yN e t w o r k P a r t n e r
FE E D E R TE R M IN A L R E F5 4 1A B B N e t w o r k P a r t n e r
U a ux = 80 .. .2 65 Vd c / ac
fn = 50 H z
In = 1 /5 A (I)
1 M RS xxxxxx
9 8 15 0U n = 10 0 /1 1 0 V (U )
U on = 1 0 0 /1 1 0 V (U o )
Ion = 1 / 5 A (Io )
9 50 9
A B B T r a n s m i t O yN e t w o r k P a r t n e r
FE E D E R TE R M IN A L R E F5 41A B B N e t w o r k P a r t n e r
U a ux = 80 .. .2 65 Vd c / ac
fn = 50 H z
In = 1 /5 A (I)
1 M RS xxxxxx
9 8 15 0U n = 10 0 /1 1 0 V (U )
U on = 1 0 0 /1 1 0 V (U o )
Ion = 1 / 5 A (Io )
9 50 9
G G G
400 V
Typical Electrical Network of Industries
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Fast Functions are performed by Controllers: Load Shedding / Re-Acceleration / Re-Starting Power Control Mode Control
MCC
A B B T r a n s m i t O yN e t w o r k P a r t n e r
F E E D E R T E R M IN A L R E F 5 4 1A B B N e t w o r k P a r t n e r
U a u x = 8 0 . . .2 6 5 V d c / a c
fn = 5 0 H z
In = 1 /5 A ( I)
1 M R S x x x x x x
9 8 1 5 0U n = 1 0 0 / 1 1 0 V (U )
U o n = 1 0 0 /1 1 0 V ( U o )
Io n = 1 / 5 A ( Io )
9 5 0 9
A B B T r a n s m i t O yN e t w o r k P a r t n e r
F E E D E R T E R M IN A L R E F 5 4 1A B B N e t w o r k P a r t n e r
U a u x = 8 0 . . .2 6 5 V d c / a c
fn = 5 0 H z
In = 1 /5 A ( I)
1 M R S x x x x x x
9 8 1 5 0U n = 1 0 0 / 1 1 0 V (U )
U o n = 1 0 0 /1 1 0 V ( U o )
Io n = 1 / 5 A ( Io )
9 5 0 9
Substation N
S800 I/O
Serial links to AVR
Serial Links to Emergency Diesel Generator
Serial links to Governor
A B B T r a n s m i t O yN e t w o r k P a r t n e r
F E E D E R T E R M IN A L R E F 5 4 1A B B N e t w o r k P a r t n e r
U a u x = 8 0 . . .2 6 5 V d c / a c
fn = 5 0 H z
In = 1 /5 A ( I)
1 M R S x x x x x x
9 8 1 5 0U n = 1 0 0 / 1 1 0 V (U )
U o n = 1 0 0 /1 1 0 V ( U o )
Io n = 1 / 5 A ( Io )
9 5 0 9
A B B T r a n s m i t O yN e t w o r k P a r t n e r
F E E D E R T E R M IN A L R E F 5 4 1A B B N e t w o r k P a r t n e r
U a u x = 8 0 . . .2 6 5 V d c / a c
fn = 5 0 H z
In = 1 /5 A ( I)
1 M R S x x x x x x
9 8 1 5 0U n = 1 0 0 / 1 1 0 V (U )
U o n = 1 0 0 /1 1 0 V ( U o )
Io n = 1 / 5 A ( Io )
9 5 0 9
ACS 601
TCP/IP Network
X-terminals(Process DCS)
Power EMS System Overview
ControlIT
Substation 2Substation 1 Substation Z
OperateIT EngineeringIT
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Functionality Power EMS
Load Shedding Active and Reactive Power Control Supervision, Control and Data Acquisition (SCADA) Mode Control Re-Acceleration / Re-Starting Synchronisation
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Load Shedding
Functionality Power EMS
?
Without Load SheddingWith Load Shedding
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Load Shedding: The types
Fast Load Shedding on Loss of Power Resources Load Shedding on Frequency Drop Slow Load Shedding on Overload Slow Load Shedding for Peak Shaving Manual Load Shedding
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Power EMS Load Shedding: Keywords
Fast Exact Flexible Co-ordinated Deterministic Security and Reliability Accurate Event Logging Operator Guidance Independent Back-up System
Display Load Shedding Control
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Display Load Shedding Islands
Display Load Shedding Overview
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Functionality Power EMS
Load Shedding Active and Reactive Power Control
MinimumExcitation
Rotor Instability Line
OperatingMinimum
Turbine Maximum
P
Q-LagQ-Lead
Maximum Excitation(Rotor Heating)
MVA-circle(Stator Heating)
MinimumPF-Leading
MinimumPF-lagging
Display Generator Capability Diagram
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Display Calculated Control Margins
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P
Q-LagQ-Lead
Active and Reactive Power Control
Active Power Sharing: Efficient Power Generation
Power Exchange optimization (Power Demand Control)
Avoid component overloading
Spinning reserve optimization
Standby optimization
Reactive Power Sharing: Achieve stable operation
Power Factor optimization
Display Generator Capability DiagramOverview of the control mode of the turbine/generator unit
Overview of the control mode of the turbine
Overview of the control mode of the generator
Overview of the measurements and the setpoints
Overview of the operation of the network
Working point of the turbine and the generator
10 Dynamic keys for operator control
Setpoint to the turbine and the generator
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Display Grid Capability Diagram
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Display Maximum Demand Monitoring
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Display Monitoring Tie-line
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Display Mark V Vibration
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Display Mark V Gas Turbine Generator Overview
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Functionality Power EMS
Load Shedding Active and Reactive Power Control Mode Control
for Generators for Turbines for Transformers for Switchboards
Mode Control
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Functionality Power EMS
Load Shedding Active and Reactive Power Control Mode Control Supervision, Control and Data Acquisition
Clearly Structured Presentation Controls - Select Before Execute Status Indications Consistency Analysis Time Tagged Events (1 ms resolution) Alarmhandling, Reports, Trends Supervision and Self Diagnostics Single Window concept
Supervision, Control and Data Acquisition
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Integration with supervisory systems
Plant Information Systems - MIS Regional Dispatch Centres Power Generation Co-ordination Centres Energy Trading Utility Management Systems Process DCS
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Integration with subordinated systems
Satellite Time Receiver (GPS) Alarm annunciators SF-6 Density Monitoring Units Motor Control Centres Battery Chargers Meteorological Stations Diesel Generators Generator- and turbine controller Protection and Control Units
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A B B T r a n s m i t O yN e t w o r k P a r t n e r
F E E D E R T E R M IN A L R E F 5 4 1A B B N e t w o r k P a r t n e r
U a ux = 80 . . .2 65 Vd c / ac
fn = 5 0 H z
In = 1 /5 A ( I)
1 M R S xx x x x x
9 8 1 5 0U n = 1 0 0 /1 1 0 V (U )
U o n = 1 0 0 /1 1 0 V (U o )
Io n = 1 / 5 A ( Io )
9 5 0 9
CB SPRING READY
CB TRUCK OUT
TEMPERATURE HIGH
SF 6 GAS DENSITY
LOADSHEDDED
Measured Values
IL1 Amps 800IL2 Amps 803IL3 Amps 801Io 0Iob 0U12 kV 20U23 kV 20U31 kV 20U1 kV 11.5U2 kV 11.5U3 kV 11.5Uo - Volts 0
Use Up and Down to scroll view
Events
NOC3Low: E399-07-06 18:34:23:230
NOC3Low: E299-07-06 14:25:52:720
CB-HCU2: Opened99-07-06 14:02:48:430
Use C-button to clear Events
Measuring of U,I,E, calculation of P & Q
Monitoring & Control Interlockings Alarm annunciation Event Time Tagging Disturbance Recording Local storage of trip-events
Serial communication to Power EMS
Integrated Protection & Control Units
Protection
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Functionality Power EMS
Load Shedding Active and Reactive Power Control Mode Control Supervision, Control and Data Acquisition (SCADA) Re-Acceleration / Re-Starting
Re-Starting
Triggered by Load Shedding or Undervoltage Individual motors Priority per motor Max. allowed time delay per motor Network configuration check Network restoration
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Functionality Power EMS
Load Shedding Active and Reactive Power Control Mode Control Supervision, Control and Data Acquisition (SCADA) Re-Acceleration / Re-Starting Synchronisation
Automatic Synchronisation after boiler trip Automatic Synchronisation initiated by operator Semi Automatic Synchronisation Manual Synchronisation
Synchronisation
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Display Synchronisation
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Display Synchronisation
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Functionality Power EMS
Load Shedding Active and Reactive Power Control Mode Control Supervision, Control and Data Acquisition (SCADA) Re-Starting Synchronisation Circuitbreaker Control Transformer Control Motor Control Generator Control Network Configuration Determination
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References
HAR, refinery in Greece
Shell Pernis refinery in the Netherlands
Shell BLNG in Brunei
Shell PDO in Oman
Hoogovens, steel-industry in the Netherlands
ThaiOil, ThaiLube, RRC refineries in Thailand
La Roche, CHP in UK
Petrobras: REPAR, REDUC, RLAM refineries in Brazil
Reliance: Hazira, Jamnagar & Haldia refineries in India
AFPC, Omar refinery in Syria
MLNG Satu, Dua & Tiga in Malaysia
StatOil Gullfaks & BP Amoco Valhall in Norway
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The total accumulated switched-off shortcurrents by a circuitbreaker or
the number of generator starts are a trigger for maintenanceNo need for big oversizing of primary equipment
In case of a shortage of electrical power, secure the available power to critical loads by
switching off the none important loads according to dynamic load tables
Optimizing the stability of the operation of the electrical generation- and distribution
network of an industryLimiting electrical import during peak time
and decreasing peak base chargeMaintaining a good Power Factor
The Human Machine Interfaces for all the electrical sub-systems can be integrated in
the Energy Management SystemSerial interfaces with protection & control units avoid spaghetti wiring & cable ducts
Power Control, Standby Optimization, n+1 Criteria, SCADA, etc. are performed by
the system and not anymore by the operators
A B B T r a n s m i t O yN e t w o r k P a r t n e r
F E E D E R T E R M IN A L R E F 5 4 1A B B N e t w o r k P a r t n e r
U a ux = 80 . . .2 65 Vd c / ac
fn = 5 0 H z
In = 1 /5 A ( I)
1 M R S xx x x x x
9 8 1 5 0U n = 1 0 0 /1 1 0 V (U )
U o n = 1 0 0 /1 1 0 V (U o )
Io n = 1 / 5 A ( Io )
9 5 0 9
And thus ABB Power EMS helps you to: Avoiding black-outs (up to 500 kUSD / hour)
Power Control including voltage control, frequency control, sharing power among generators and tie-line(s).
High Speed Consistency Load Shedding (< 100 ms.)
Decreasing electricity costs Peak-shaving Re-active Power Control & Sharing
? Minimizing operational costs Decreased number of operators Event driven maintenance Single Window concept
Lower investment costs Minimized cabling and engineerings Optimised network design