Power System Stability and Control Course
Transcript of Power System Stability and Control Course
![Page 1: Power System Stability and Control Course](https://reader030.fdocuments.in/reader030/viewer/2022021713/620b7b2590f96b07d76845f5/html5/thumbnails/1.jpg)
Power System Stability and Control Course
This course will provide a comprehensive overview of power system stability and control problems. This includes the basic concepts, physical aspects of the phenomena, methods of analysis, examples of inci-dents of system instability, challenges to the secure operation of present-day power systems, and com-prehensive approach to enhancing system security.
The book Power System Stability and Con-trol by Prabha Kundur, McGraw-Hill, Inc., 1994 will be used as reference for the course.
Lecturer Dr. Prabha S. Kundur
Dr. Prabha S. Kundur has over 40 years of experi-ence in the electric power industry. He has performed extensive international consulting related to power system planning and design, and has delivered technical courses for utilities, manufacturers and universities around the world. Dr. Kundur is the author of the book Power System Stabil-ity and Control (McGraw-Hill, 1994), which is a standard modern refer-ence for the subject.
Literature
Book ”Power System Stabil-ity and Control” by Dr. Kundur and other material will be provided to each participant.
Power System Stability and Control Courseby Dr. Prabha S. Kundur
July 1-4, 2014 in Kgs. Lyngby
Course Organizer
Technical University of DenmarkCenter for Electric Power and EnergyElektrovej, Bygning 3252800 Kgs. Lyngby Associate Professor Qiuwei WuTelephone: +45 4525 3529
Registration
Preferably no later than May 31st, 2014 by con-tacting Associate Professor Qiuwei Wue-mail: [email protected]
Hotels and travel information
A list of hotels and travel information will be provided during registration.
Course location
Technical University of DenmarkMeeting Room S1, Building 101AAnker Engelunds Vej 1 DK-2800 Kgs. LyngbyDenmark
Fee
The fee is 19500 DKK excl. VAT for participants from the industry. PhD students get a 50% dis-count. The fee includes all the material pro-vided, coffee and lunch for the four days.
ETCS
Points 4 ETCS
![Page 2: Power System Stability and Control Course](https://reader030.fdocuments.in/reader030/viewer/2022021713/620b7b2590f96b07d76845f5/html5/thumbnails/2.jpg)
Day 11. Introduction to Power System Stability
• Definitionandclassificationofpowersystemstability• Briefdescriptionofeachcategoryofsystemstability• Conceptualrelationshipbetweenpowersystem
stability, security and reliability• Traditionalapproachpowersystemsecurity
assessment• Challengestosecureoperationofprsent-day
power systems
2. Review of Equipment Characteristics and Modelling
• Synchronousmachines:theoryandmodel-ling, machine parameters, saturation model-ling, synchronous machine representation in stability studies, reactive capability limits.
• Excitationsystems:elementsofanexcitation system, types of excitation systems, control and protective functions, modelling.
• Primemoversandgoverningsystems:hydraulicturbinesand governing systems, steam turbines and governing systems, gas turbines and combined-cycle units.
• Generatingunittestingandmodelvalidation:test procedures, current industry practices.
• ACTransmission:performanceequationsandparameters,surge impedance loading, voltage-power characteristics, reactive power requirements, loadability characteristics, factors influencing transfer of active and reactive power.
• Powersystemloads:basicmodellingconcepts,staticanddynamic models, acquisition of load model parameters.
3. Control of Active Power and Frequency
• Fundamentalsoffrequencycontrol• Compositeregulatingcharacteristicsofpowersystems• Automaticgenerationcontrol• Under-frequencyloadshedding
Day 24. Control of Reactive Power and Voltage
• Controlobjectives• Productionandabsorptionofreactivepower• Methodsofvoltagecontrol• Principlesofreactivecompensa-
tion in transmission systems• Staticanddynamiccompensators• Coordinatedcontrolofreactivepowerandvoltage
5. Transient (angle) Stability
• Anelementaryviewofthetransientstabilityproblem• Simulationofpowersystemdynamicresponse• Numericalintegrationmethods• Performanceofprotectiverelaying• CaseStudies• Transientstabilityenhancement• Examplesofmajorsystemblack-
outs due to transient instability
Day 36. Small-Signal (angle) Stability
• Natureanddescriptionofsmall-signalstability (SSS) problems
• Methodsofanalysis;modalanalysisapproach• Characteristicsoflocal-plantmodeand
inter-area mode oscillations • Casestudies• SSSenhancement• Examplesofmajorsystemdisturbancesdueto
small-signal instability
7. Subsynchronous Oscillations
• Steamturbinegeneratortorsionalcharacteristics• Torsionalinteractionwithpowersystemcontrols:
PSS, HVDC converter controls• Subsynchronousresonance• Impactofnetwork-switchingdisturbances
8. Voltage Stability
• Descriptionofthephenomenon• Factorsinfluencingvoltagestability• Methodsofanalysis• Typicalscenariosofshort-termvoltageinstability
and long-term voltage instability • Preventionofvoltageinstability• Casestudies• Examplesofmajorsystemdisturbancesdueto
voltage instability
Day 49. Frequency Stability
• Natureanddescriptionoffrequencystabilityproblems• Examplesofsystemdisturbanes
caused by frequency instability• Analysisoffrequencystabilityproblems• Casestudies• Mitigationoffrequencystabilityproblems.
10. Wind Turbine Generators
• Windturbinecharacteristics• Typesofwindturbinegeneratortechnologies• Protectionsystems• Impactonpowersystemdynamicperformance
11. Major Power Grid Blackouts in 2003
• Descriptionofevents• Causesofblackouts• Lessonslearned
12. Comprehensive Approach to Power System Security
• Applicationofrobustpowersystemcontrols• Defenseplanagainstextremecontingencies• Restorationplans• On-linesecurityassessment• Reliabilitymanagementsystem• Wide-areamonitoringandcontrol• Widespreaduseofdistributedgeneration