Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Lew D, Piwko R, Project Managers. Western wind and solar integration study. Subcontract report NREL/SR-550-47434, Prepared for NREL by GE Energy, May 2010
Vittal V, McCalley JD, Ajjarapu V, Shanbhag U (2009) Impact of increased DFIG wind penetration on power systems and markets. PSERC final report, Aug 2009
Kundur P, Paserba J, Ajjarapu V, Andersson G, Bose A, Canizares C, Hatziargyriou N, Hill D, Stankovic A, Taylor C, Van Cutsem T, Vittal V (2004) Definition and classification of power system stability, IEEE/CIGRE joint task force on stability terms and definitions report. IEEE Trans Power Sys 19(3):1387–1401
Anderson PM, Fouad AA (2003) Power system control and stability, 2nd edn. Wiley Interscience, Piscataway
Sanchez Gasca JJ, Miller NW, Price WW (2004) A modal analysis of a two-area system with significant wind power penetration. Proceedings of the 2004 IEEE PES power systems conference and exposition, pp 1148–1152
Slootweg JG, Kling WL (2003) The impact of large scale wind power generation on power system oscillations. Electr Power Sys Res 67(1):9–20
Fernandez RD, Mantz RJ, Battaiotto PE (2007) Impact of wind farms on power system—an eigenvalue analysis approach. Renew Energy 32(10):1676–1688
Xu F, Zhang XP, Godfrey K, Ju P (2007) Small-signal stability analysis and optimal control of a wind turbine with doubly fed induction generator. Proceedings of the 2007 IET generation, transmission & distribution, pp 751–760
Mendonca A, Lopes JAP (2005) Impact of large scale wind power integration on small-signal stability. Proceedings of the 2005 international conference on future power systems, pp 1–5
Mei F, Pal B (2007) Modal analysis of grid connected doubly fed induction generators. IEEE Trans Energy Convers 22(3):728–736
Faddeev DK, Faddeeva VN (1963) Computational methods of linear algebra. W. H. Freeman and Company, San Francisco and London
Van Ness JE, Boyle JM, Imad FP (1965) Sensitivities of large, multiple—loop control systems. IEEE Trans Autom Control 10(3):308–315
Smed T (1993) Feasible eigenvalue sensitivity for large power systems. IEEE Trans Power Sys 8(2):555–561
Ma J, Dong ZY, Zhang P (2006) Eigenvalue sensitivity analysis for dynamic power system. Proceedings of the 2006 international conference on power system technology, pp 1–7
Gautam D, Vittal V, Harbour T (2009) Impact of increased penetration of DFIG based wind turbine generators on transient and Small-signal stability of power systems. IEEE Trans Power Sys 24(3):1426–1434
Gautam D (2010) Impact of increased penetration of DFIG based wind turbine generator on rotor angle stability of power systems. Ph.D. Dissertation, Arizona State University
Kayikci M, Milanovic JV (2008) Assessing transient response of DFIG—based wind plants—the influence of model simplifications and parameters. IEEE Trans Power Sys 23(2):545–554
Nunes MVA, Lopes JAP, Zurn HH, Bezerra UH, Almeida RG (2004) Influence of the variable-speed wind generators in transient stability margin of the conventional generators integrated in electrical grids. IEEE Trans Energy Convers 19(4):692–701
Muljadi E, Butterfield CP, Parsons B, Ellis A (2008) Effect of variable speed wind turbine generator on stability of a weak grid. IEEE Trans Power Sys 22(1):29–35
Vittal E, O’Malley M, Keane A (2012) Rotor angle stability with high penetrations of wind generation. IEEE Trans Power Sys. 27(1):353–362
Hansen AD, Michalke G (2007) Fault ride-through capability of DFIG wind turbines. Renew Energy 32:1594–1610
Lund T, Sorensen P, Eek J (2007) Reactive power capability of a wind turbine with doubly fed induction generator. Wind Energy 10:379–394
Konopinski RJ, Vijayan P, Ajjarapu V (2009) Extended reactive capability of DFIG wind parks for enhanced system performance. IEEE Trans Power Sys 24(3):1346–1355
Vittal E, O’Malley M, Keane A (2010) A steady-state voltage stability analysis of power systems with high penetrations of wind. IEEE Trans Power Sys 25(1):433–442
Kayikci M, Milanovic JV (2007) Reactive power control strategies for DFIG-based plants. IEEE Trans Energy Convers 22(2):389–396
Tapia G, Tapia A, Ostolazam JX (2007) Proportional-integral regulator-based approach to wind farm reactive power management for secondary voltage control. IEEE Trans Energy Convers 22(2):488–498
Cartwright P, Holdsworth L, Ekanayake JB, Jenkins N (2004) Co-ordinated voltage control strategy for a doubly-fed induction generator (DFIG)-based wind farm. Proc Inst Electr Eng Gen Transm Distrib 151(4):495–502
Cigré Report 328 (2007) Modeling and dynamic behavior of wind generation as it relates to power system control and dynamic performance. Working group C4.601
Kundur P (1993) Power system stability and control. McGraw Hill, Inc, New York
Lalor G, Mullane A, O’Malley M (2005) Frequency control and wind turbine technologies. IEEE Trans Power Sys 20(4):1905–1913
Morren J, Haan SWH, Kling WL, Ferreira JA (2006) Wind turbines emulating inertia and supporting primary frequency control. IEEE Trans Power Sys 21(1):433–434
Ramtharan G, Ekanayake JB, Jenkins N (2007) Frequency support from doubly fed induction generator wind turbines. IET Renew Power Gen 1(1):3–9
Miller N, Clark K, Delmerico R, Cardinal M (2009) WindinertiaTM: inertial response option for GE wind turbine generators. Presented at the 2009 IEEE power engineering society general meeting
Gautam D, Goel L, Ayyanar R, Vittal V, Harbour T (2011) Control strategy to mitigate the impact of reduced inertia due to doubly fed induction generators on large power systems. IEEE Trans Power Sys 26(1):214–224
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Copyright information
© 2013 Springer Science+Business Media New York
About this chapter
Cite this chapter
Vittal, V., Ayyanar, R. (2013). Impact of Increased Penetration of DFIG Wind Generators on System Dynamic Performance . In: Grid Integration and Dynamic Impact of Wind Energy. Power Electronics and Power Systems. Springer, New York, NY. https://doi.org/10.1007/978-1-4419-9323-6_6
Download citation
DOI: https://doi.org/10.1007/978-1-4419-9323-6_6
Published:
Publisher Name: Springer, New York, NY
Print ISBN: 978-1-4419-9322-9
Online ISBN: 978-1-4419-9323-6
eBook Packages: EngineeringEngineering (R0)