Bo Liu, Yan Zhang, Na Yang, and Dakang Zhu
[1] A. Larsson, Flicker emission of wind turbines caused during continuous operation, IEEE Transactions on Energy Conversion, 17(1), 2002, 114–118. [2] T. Petru & T. Thiringer, Modeling of wind turbines for power system studies, IEEE Transactions on Power System, 17(4), 2002, 1132–1139. [3] C.S. Demoulias & P. Dokopoulos, Electrical transients of wind turbine in a small power grid, IEEE Transactions on Energy Conversion, 11(3), 1996, 636–642. [4] T. Thiringer, Power quality measurements performed on a low voltage grid equipped with two wind turbines, IEEE Transactions on Energy Conversion, 11(3), 1996, 601–606. [5] D.J. Trudnowski, A. Gentile, J.M. Khan, & E.M. Petritz, Fixed speed wind generator and wind park modeling for transient stability studies, IEEE Transactions on Power Systems, 19(4), 2004, 1911–1917.Figure 6. Eigenvalues of different distances between wind farm and PCC.Figure 7. The diagram of approximate error in different smooth factor conditions. perform the small signal stability forecast. The approximate error and forecast error can be shown in Figs 7 and 8. (sf is smooth factor.) Figures 7 and 8 show that the smaller smooth factor, the better the capability of approximate and forecast. The computing time is 0.85 s, but the calculation time of eigenvalue analysis is 2.85 s by MATLAB. It demonstrates that the classification using GRNN analysis is faster than using eigenvalue analysis after the training, because the GRNN analysis does not require building the matrix and calculating eigenvalues for each operating condition. 6. Conclusions The model of the wind generator with the flexibility of its shaft is built, and the eigenvalues, frequencies, damping 211 [6] J.G. Slootweg, S.W.H. de Haan, H. Polinder, & W.L. Kling, General model for representing variable speed wind turbines in power system dynamics simulations, IEEE Transactions on Power Systems, 18(1), 2003, 145–151. [7] C. Jose & F. Andres Elias, A linear dynamic model for asynchronous wind turbines with mechanical fluctuations, IEEE Transactions on Power Systems, 17(3), 2002, 681–687. [8] C. Yong-ning, W. Wei-sheng, & D. Hui-zhu, Impact of large scale wind farm integration on power system transient stability, Automation of Electric Power Systems, 30(5), 2007, 10–14. [9] A.M. Azmy et al., Impact of distributed generation on the stability of electrical power systems. Power Engineering Society General Meeting 2005, San Francisco, 2005, 1056–1063. [10] T. Hong, W. Jun-ling, & C. Shuang-xi, Modeling and simulation for small signal stability analysis of power system containing wind farm, Power System Technology, 28(1), 2004, 38–41. [11] P. Kundur, Power system stability and control. (China Electrical Power Publish, 2002). [12] J. Wiik, J.O. Gjerde, T. Gjengedal et al., Steady state power system issues wind farms, IEEE Power Engineering Society Winter Meeting, 2002, 366–371. [13] B.C. Lesieutre, P.W. Sauer, & A. PaiM, Development and comparative study of induction machine based dynamic P , Q load models. IEEE Transactions on Power Systems, 10(1), 1995, 182–191. [14] D.F. Specht, A general regression neural network, IEEE Transaction on Neural Network, 6(2), 1991, 568–576.Yan Zhang was born in China, 1958. She received her Ph.D. degree in power system in Shanghai Jiaotong University. Currently she is a Professor and Head of the School of Electronic, Information and Electrical Engineering at Shanghai Jiaotong University. Her research interests include power system planning, reliability and distribution system automation. Na Yang was born in China, 1983. She received her master’s degree in power system in Shanghai Jiaotong University. She is currently pursuing the related work of power system in AnHui Electric Power Co., Ltd.
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