4. OPAL-RT TECHNOLOGIES in Brief
Established in 1997
Strong R&D with 20% of turnover
reinvested
Large and diversified customer base
One-stop-shop for model-based
engineering simulators
Power Electronics
Power Systems
Automotive
Aerospace
Educational
Rapid Control Prototyping (RCP)
Hardware in the Loop (HIL)
MATLAB/Simulink Integration
6. What is electro-mechanical transient
stability phenomenon?
• Electro-mechanical
• Transient Stability
• Large Power Grids
• Real-time
7. What is ePHASORsim?
Real-time transient stability simulator
• Large-scale power systems
• Transmission, distribution and generation
Phasor domain solution
• Nominal frequency
• Positive sequence (transmission system)
• 3-phase (distribution system)
• Time step in the range of few milliseconds
8. What is ePHASORsim?
Real-time transient stability simulator
• Large-scale power systems
• Transmission, distribution and generation
Phasor domain solution
• Nominal frequency
• Positive sequence (transmission system)
• 3-phase (distribution system)
• Time step in the range of few milliseconds
10. What you can achieve with
ePHASORsim?
• Operator training simulator
• Test SCADA systems
• UDM simulation
• Cyber security
• Prediction
11. What are the existing tools? What is
ePHASORsim’s added-value?
Offline Phasor Tools
time-step: millisecond
PSS/e
ETAP
EUROSTAG
CYME
Real-time EMT Tools
time-step: microsecond
eMEGAsim
HYPERSIM
…
ePHASORsim
12. Case #2: we performed a simulation of about 10,000 nods with 2,500 generators, close to 5000 controllers, and 18,000 other components, such as loads and
transmission line. For that size of grid, we obtained simulation performance between events, between fold or switching events, of 3.28 million seconds of real
computation time for a 10 millisecond simulated time which places us well within the real-time range for such a large network. During the occurrence of a
fault or a switching of event the extra calculations required to maintain the state of network brings us to a computational time of 7.4 milliseconds, still well
within the 10 milliseconds of simulated time and therefore, we maintain real-time capacity even during switching events.
Real-time performance
Case 1 Case 2 Case 3
Number of
components
Buses 4992 9984 19968
Generators 1280 2560 5120
Controllers 2304 4610 9216
Others 9144 18368 36820
Computation
time (ms)
Normal 1.62 3.28 6.68
Disturbance 3.49 7.43 16.61
Overruns NO NO YES
Simulation time: 10s, time-step: 10ms
Number of CPU cores: 1
13. ePHASORsim library
Models
Generator, Voltage source
Load (ZIP)
Transmission line
Excitation system
Power System Stabilizer
Turbine-Governor
Transformer (with Tap-Changer)
Reactor
Capacitor banks
External Simulink Blocks (UDM)
External SPS Controller Blocks
Events and Actions
Balanced and unbalanced faults
Open-connector conditions
Transmission line trip
Generator outage
Faults on transmission line section
Load shedding/restoration
Tap-changer adjustment
AVR adjustment
Reclosing commands
Loss of excitation
…
14. Open & scalable hardware platform
Integrated with a chassis equipped with FPGA and I/Os
Interfaced with multiple communication protocols
The entire simulation
runs with one of our
target communicating
with your whole
computer so the
simulation can be
performed on your
desktop and accessing
remotely our chassis.
ePHASORsim also
integrates with a host of
test automation and
visualization platforms
such as our own product
TestDrive which allows
you to implement
realistic control panels
in Labview™ and
connect directly to
signals being read from
or sent to our simulator.
To obtain the biggest benefit from
ePHASORsim, you can count on our
open and scalable hardware platform
which allows you to integrate the
simulations that are being performed
with ePHASORsim together with
many communication protocols and
analog IO’s that you encounter in our
hardware products such as the
OP5600 series, 0P7000 series and so
on.
15. Test automation & visualisation
platform
ScopeView to record, display and
analyze results
TestDrive to implement
realistic control panels
Python for script and test
automation
21. Partnership with ETAP
Objectives
• End-to-end solution that includes simulation of protection devices, PMUs, wide-area
monitoring etc. with ETAP’s what-if analysis and resource optimization software
• Reduced limits on complexity that can be simulated fast and very viable faster-than-real-time
predictive simulations
• Higher simulation fidelity
• Reduce risk and cost for implementing intelligent grid solutions
Implementation
• Integration of ETAP environment/tools with OPAL-RT’s simulation platform
• Work with customers/partners to fine-tune integrated solution
• Deploy end-to-end solution
22. Partnership with ETAP
Objectives
• End-to-end solution that includes simulation of protection devices, PMUs, wide-area
monitoring etc. with ETAP’s what-if analysis and resource optimization software
• Reduced limits on complexity that can be simulated fast and very viable faster-than-real-time
predictive simulations
• Higher simulation fidelity
• Reduce risk and cost for implementing intelligent grid solutions
Implementation
• Integration of ETAP environment/tools with OPAL-RT’s simulation platform
• Work with customers/partners to fine-tune integrated solution
• Deploy end-to-end solution
23. REAL TIME DYNAMICS MONITORING
SYSTEM (RTDMS®)
A SynchroPhasor based software system
(platform + applications)
for real time wide area visualization, situational
awareness, monitoring and analysis
of the power system
® Electric Power Group. Built upon GRID-3P platform, U.S. Patent 7,233,843. All
rights reserved
Wide Area Situational Awareness and Visualization
24. The RTDMS Platform
APPLICATIONSDATA SOURCES
Data Filters
Format Translation
Parsing
Communication
Validation
Archiving
Alarm Processing
Event Detection
Data Quality
Analytics
Interfaces
Computation
ICCP
DataExchange
Web Services
PHASOR
Data
F-NET
DATA
GIS
Weather
Traffic
Real Time
Wide Area
Monitoring
Root Cause &
Event Analysis
Reports
25. Key RTDMS Applications
1. Wide Area Situational Awareness (Dashboard)
2. Automated Event Analyzer
3. Phase Angle and Grid Stress Monitoring
4. Voltage Stability Monitoring
5. Angular Stability Analysis & Monitoring
6. Flow Gate and Inter-area Power Transfer
7. Frequency Stability Monitoring
8. Oscillation Stability Analysis & Monitoring
9. Oscillation Detection
10. Intelligent Alarms
11. RTDMS Daily Reports / Summary Reports/ Online Reports
26. Phase Angle and Grid Stress Monitoring
• Dynamic phase angle view highlights system stress between PMUs
at key locations
27. Oscillation Stability Analysis & Monitoring
• Detects oscillations of interest based on event analysis and system
characteristics in each interconnection
• Monitors modal frequency, energy, damping, mode shape in real-time
Modal frequency
Damping %
Energy Level
28. EPG
RTDMS
Platform
Opal-RT
ePHASORSim
Simulation
Real Time Operator Interactions with
Phasor Simulations
Real Time Wide Area Situational Awareness
Phase Angle Differences
Voltage and Angle Sensitivities
Frequency Stability Monitoring
Monitoring Oscillations, Damping
Oscillation Detection
Islanding Detection
Intelligent Alarms
EPG Phasor Simulation Method - Overview
29. Case Study – Pacific Southwest Blackout
Simulation of a real event
Event occurred on Sep 8, 2011 and took about 12-minutes
Simulation Created Based on Sequence of Events in NERC/FERC
report
• Outage of Hassayampa-North Gila line
• Outage of IID transformers
• Load drop in IID and CFE
• Loss of CFE and IID generation
• Separation of SDGE at San Onofre Nuclear Gen. Station
(SONGS)
Simulation results match the event
Simulation developed to validate event and train operators
30. Results from Simulation
Results from NERC/FERC report Results match
very well
Pacific Southwest Blackout
Comparison of South of SONGS currents
31. Upcoming Events …
Montreal June 9 – 12
realtime@opal-rt.com
Register online now:
http://www.opal-rt.com/realtime2014/