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FACTS Planning Studies

  • Bjarne R. AndersenEmail author
  • Dennis Woodford
  • Geoff Love
Living reference work entry
  • 5 Downloads
Part of the CIGRE Green Books book series (CIGREGB)

Abstract

The ongoing planning studies performed by Transmission System Operators may identify potential issues, such as breaches of grid codes and planning criteria. These breaches will require mitigation to achieve compliance, requiring changes to the voltage and/or power flows in the network, as appropriate. In addition to the conventional measures such as changes to existing lines, addition of lines, generation, etc., FACTS controllers may offer short-term or permanent solutions, which may be easier to implement and or more economic than the conventional solution. The need for FACTS controllers may also be identified by developers of wind or solar power plants, as the best/most economical way to achieve compliance with grid code requirements.

新皇冠体育appThis chapter describes the network studies that are necessary to define the characteristics of the FACTS controller(s) that could provide the technical solution to the identified issue. The chapter also describes the studies that need to be performed, if a cost-benefit analysis shows that the FACTS controller is an attractive solution. An overview of the models used for these studies is provided. These additional studies are required to provide the information for the technical specification of the FACTS controller and include rating requirements, speed of response, fault ride-through requirements, harmonic impedance, background harmonic data, and harmonic limits. An overview of the models used for these studies is provided.

References

  1. Anderson, P.M., Farmer, R.G.: Series Compensation of Power Systems. PBLSH! Inc, Encinitas (1996)
  2. Anderson, P.M., Fouad, A.A.: Power System Control and Stability. IEEE Press, Piscataway (1993)
  3. CIGRE: Green Book on Overhead Lines. Springer, Paris (2017)
  4. CIGRE JTF 36.05.02/14.03.03: AC system modelling for AC filter design – an overview of impedance modelling, Electra 164, Feb 1996
  5. CIGRE CC02: Guide for Assessing the Network Harmonic Impedance, Electra 167, Aug 1996
  6. CIGRE TB 051: Load flow control in high voltage power systems, Jan 1996
  7. CIGRE TB 139: Guide to the specification and design evaluation of ac filters for facts controllers, Apr 1999
  8. CIGRE TB 145: Modeling of power electronics equipment (FACTS) in load flow and stability programs: a representation guide for power system planning and analysis, 1999
  9. CIGRE TB 301: Congestion management in liberalized market environment, Aug 2006
  10. CIGRE TB 310: Coordinated voltage control in transmission networks, Feb 2007
  11. CIGRE TB 504: Voltage and VAr support in system operation, Aug 2012
  12. CIGRE TB 553: Special Aspects of AC Filter Design for HVDC Systems, 2013
  13. CIGRE TB 563: Modelling and Simulation Studies to be Performed During the Lifecycle of HVDC Systems, 2013
  14. CIGRE TB 700: Challenge in the Control Centre (EMS) due to Distributed Generation and Renewables, 2017
  15. CIGRE TB 766: Network modelling for harmonic studies, 2019
  16. IEEE Electrification Magazine: vol. 3, number 4, Dec 2015
  17. IEEE: 1031, IEEE Guide for the Functional Specification of Transmission Static Var Compensators, 2011
  18. IEEE-1052: IEEE Guide for Specification of Transmission Static Synchronous Compensator (STATCOM) Systems, 2018
  19. IEC TR 62001-1:2016, High-voltage direct current (HVDC) systems – Guidance to the specification and design evaluation of AC filters – Part 1: Overview
  20. IEC TR 62001-2:2016, High-voltage direct current (HVDC) systems – Guidance to the specification and design evaluation of AC filters – Part 2: Performance
  21. IEC TR 62001-3:2016, High-voltage direct current (HVDC) systems – Guidance to the specification and design evaluation of AC filters – Part 3: Modelling
  22. IEC TR 62001-4:2016, High-voltage direct current (HVDC) systems – Guidance to the specification and design evaluation of AC filters – Part 4: Equipment
  23. Irwin G., Amarasinghe, C., Krocker, N., Woodford, D.: Parallel processing and hybrid simulation for HVDCNSC PSCAD studies, AC and DC Power Transmission (ACDC 2012), 10th IET International Conference on AC and DC Power Transmission, 2012
  24. Krause, P.C., Wasynczuk, O., Sudhoff, S.D.: Analysis of Electric Machinery. IEEE Press, Piscataway (1995)
  25. Kundur, P.: Excitation Systems, Chapter 8. In: Power System Stability and Control. McGraw Hill, Inc. New York (1994). ISBN 0-047-035958-X
  26. Ohtsuki, H., Yokoyama, A., Sekine, Y.: Reverse action of on-load tap changer in association with voltage collapse. IEEE Power Eng. Rev. 11(2), (1991)
  27. Park, R.H.: “Two-reaction theory of synchronous machines: generalized method of analysis – part I” (PDF). Trans. AIEE. 48, 716–730 (1929). Retrieved 13 Dec 2012
  28. Price, P.R.: Geomagnetically induced current effects on transformers. IEEE Trans. Power Del. 17(4), 1002–1008 (2002)
  29. Western Electricity Coordinating Council (WECC) Modeling and Validation Work Group: Composite load model for dynamic simulations, Report 1.0, June 2012

Copyright information

© Springer Nature Switzerland AG 2019 2020

Authors and Affiliations

  • Bjarne R. Andersen
    • 1
    Email author
  • Dennis Woodford
    • 2
  • Geoff Love
    • 3
  1. 1.Andersen Power Electronic Solutions LtdBexhill on SeaUK
  2. 2.Electranix CorporationWinnipegCanada
  3. 3.PSC ConsultingDublinIreland

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