Effect of grid-connected wind turbine generators on power system transient stability

Effect of grid-connected wind turbine generators on power system transient stability

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internalnotes [1]. S. Mathew and G.S. Philip, Advances in Wind Energy Conversion Technology, Heidelberg, Germany, Springer, 2011. [2]. Global wind report, Annual market update 2013, Global wind energy council (GWEC), April, 2014. [3]. P. Kundur, J. Paserba, V. Ajjarapu, G. Andersson, A. Bose et al., “Definition and classification of power system stability,” IEEE Transaction Power System, Vol. 19, No, 2, pp. 1387–1401, 2004. [4]. J. Tamura, T. Yamajaki, M. Ueno, Y. Matsumura and S. Kimoto, “Transient stability simulation of power system including wind generator by PSCAD/EMTDC,” IEEE Porto Power Tech. Proceeding, Vol. 4, 2001. [5]. E. S. Abdin and W. Xu “Control design and dynamic performance analysis of a wind turbine induction generator unit”, IEEE Transaction Energy Conversion, Vol. 15, No. 1, pp. 91, 2000. [6]. I. Zubia, X. Ostolaza, G. Tapia, A. Tapia and J.R Saenz, “Electrical fault simulation and dynamic response of a wind farm,” Proc. IASTED International Conference on Power and Energy System, pp. 595, 2001. [7]. J. Tamura, T. Yamazaki, R. Takahashi, S. Yonaga, H. Kubo, et al. “Analysis of transient stability of wind generators,” Conference Record of International Conference Electrical Machines, No.148, 2002. [8]. S.M. Muyeen, Md. Hasan Ali, R. Takahashi, T. Murata and J. Tamura, “Transient stability enhancement of wind generator by a new logical pitch controller,” IEEJ Transaction on Power Energy, pp. 742–752, Vol. 126, No. B(8), 2006. [9]. I. Erlich , F. Shewarega , S. Engelhardt , J. Kretschmann , J. Fortmann and F. Koch “Effect of wind turbine output current during faults on grid voltage and the transient stability of wind parks”, IEEE Proceedings of Power Engineering Society General Meeting, pp. 1-8, 2009. [10]. D. Gautam, V. Vittal, and T. Harbour, “Impact of Increased Penetration of DFIG-Based Wind Turbine Generators on Transient and Small Signal Stability of Power Systems”, IEEE Transactions on power systems, Vol. 24, No. 3, August, 2009. [11]. S. Heier, Grid Integration Of Wind Energy Conversion Systems, John Wiley & Sons Ltd, 2nd ed., Chichester, UK, 2006. [12]. T. Ackerman, Wind Power in Power Systems, John Wiley & Sons Ltd, 1 st ed., Chichester, UK, 2005. [13]. L. R. Chang-Chien, W. T. Lin, Y.C. Yin, “Enhancing frequency response control by DFIGs in the high wind penetrated power systems”, IEEE Transaction Power System Vol. 26, pp. 710–718, 2011. [14]. C. Luo, H. Bankar, B. Shen, B.T. Ooi, “Strategies to smooth wind power fluctuations of wind turbine generator”, IEEE Transaction Energy Conversion, Vol. 22, pp. 341–349, 2007. [15]. J. Morren, J. Pierik, S.W.H. de Haan, “Inertial response of variable speed wind turbines.” Electrical Power System Research, Vol. 76, pp. 980–987, 2006. [16]. H. Bankar, C. Luo, B.T. Ooi, “Steady-state stability analysis of doubly-fed induction generators under decoupled P-Q control”, IEE Proceeding of Electrical Power Application, Vol. 153, pp. 300–306, 2006. [17]. L. R. Chang-Chien, Y.C. Yin, “Strategies for operating wind power in a similar manner of conventional power plant”, IEEE Transaction Energy Conversion, Vol. 24, pp. 926– 934, 2009. [18]. B. Boukhezzar, L. Lupu, H. Siguerdidjane, M. Hand,“Multivariable control strategy for variable speed, variable pitch wind turbines”,Renewable Energy vol. 32 pp. 1273–1287, 2007. [19]. Y. Xia, K. H. Ahmed, and B.W. Williams, “Wind Turbine Power Coefficient Analysis of a New Maximum Power Point Tracking Technique,” IEEE Transaction on Industrial Electronics, Vol. 60, No. 3, pp. 1122 – 1132, 2013. [20]. Electranix Corporation, “Feasibility Study Regarding Integration of The Læsø Syd 160 MW Wind Farm Using Vsc Transmission,” http://electranix.com/publication/feasibilitystudy/ Accessed on, 15/8/ 2014.
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spelling 12739 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=12739 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal image/jpeg inches 96 96 norman 51 51 1424 769 1424x769 2016-01-18 10:51:04 7046-01-FH02-FSTK-16-04976.jpg UniSZA Private Access Effect of grid-connected wind turbine generators on power system transient stability International Journal on Electrical Engineering and Informatics A huge number of wind turbine generators will be integrated into the existing power systems in the near future because it has been identified as one of the most promising field of energy industry. Wind turbines are required to remain connected to the grid during a fault condition so as to support constant power supply. It is therefore necessary to investigate the impact of wind turbine generators on the stability of power systems. This paper presents a comparative study of available wind generator types and examines the effect of penetration level on the power system. Simulations have been performed to compare and demonstrate the transient behavior of a typical 5-machine 22- bus system with and without wind power integration. The simulation results reveal that the transient behavior of wind generators has significant effect on the overall stability of power systems and the increase in penetration level may induce the instability into the systems. 7 4 School of Electrical Engineering and Informatics School of Electrical Engineering and Informatics 644-654 [1]. S. Mathew and G.S. Philip, Advances in Wind Energy Conversion Technology, Heidelberg, Germany, Springer, 2011. [2]. Global wind report, Annual market update 2013, Global wind energy council (GWEC), April, 2014. [3]. P. Kundur, J. Paserba, V. Ajjarapu, G. Andersson, A. Bose et al., “Definition and classification of power system stability,” IEEE Transaction Power System, Vol. 19, No, 2, pp. 1387–1401, 2004. [4]. J. Tamura, T. Yamajaki, M. Ueno, Y. Matsumura and S. Kimoto, “Transient stability simulation of power system including wind generator by PSCAD/EMTDC,” IEEE Porto Power Tech. Proceeding, Vol. 4, 2001. [5]. E. S. Abdin and W. Xu “Control design and dynamic performance analysis of a wind turbine induction generator unit”, IEEE Transaction Energy Conversion, Vol. 15, No. 1, pp. 91, 2000. [6]. I. Zubia, X. Ostolaza, G. Tapia, A. Tapia and J.R Saenz, “Electrical fault simulation and dynamic response of a wind farm,” Proc. IASTED International Conference on Power and Energy System, pp. 595, 2001. [7]. J. Tamura, T. Yamazaki, R. Takahashi, S. Yonaga, H. Kubo, et al. “Analysis of transient stability of wind generators,” Conference Record of International Conference Electrical Machines, No.148, 2002. [8]. S.M. Muyeen, Md. Hasan Ali, R. Takahashi, T. Murata and J. Tamura, “Transient stability enhancement of wind generator by a new logical pitch controller,” IEEJ Transaction on Power Energy, pp. 742–752, Vol. 126, No. B(8), 2006. [9]. I. Erlich , F. Shewarega , S. Engelhardt , J. Kretschmann , J. Fortmann and F. Koch “Effect of wind turbine output current during faults on grid voltage and the transient stability of wind parks”, IEEE Proceedings of Power Engineering Society General Meeting, pp. 1-8, 2009. [10]. D. Gautam, V. Vittal, and T. Harbour, “Impact of Increased Penetration of DFIG-Based Wind Turbine Generators on Transient and Small Signal Stability of Power Systems”, IEEE Transactions on power systems, Vol. 24, No. 3, August, 2009. [11]. S. Heier, Grid Integration Of Wind Energy Conversion Systems, John Wiley & Sons Ltd, 2nd ed., Chichester, UK, 2006. [12]. T. Ackerman, Wind Power in Power Systems, John Wiley & Sons Ltd, 1 st ed., Chichester, UK, 2005. [13]. L. R. Chang-Chien, W. T. Lin, Y.C. Yin, “Enhancing frequency response control by DFIGs in the high wind penetrated power systems”, IEEE Transaction Power System Vol. 26, pp. 710–718, 2011. [14]. C. Luo, H. Bankar, B. Shen, B.T. Ooi, “Strategies to smooth wind power fluctuations of wind turbine generator”, IEEE Transaction Energy Conversion, Vol. 22, pp. 341–349, 2007. [15]. J. Morren, J. Pierik, S.W.H. de Haan, “Inertial response of variable speed wind turbines.” Electrical Power System Research, Vol. 76, pp. 980–987, 2006. [16]. H. Bankar, C. Luo, B.T. Ooi, “Steady-state stability analysis of doubly-fed induction generators under decoupled P-Q control”, IEE Proceeding of Electrical Power Application, Vol. 153, pp. 300–306, 2006. [17]. L. R. Chang-Chien, Y.C. Yin, “Strategies for operating wind power in a similar manner of conventional power plant”, IEEE Transaction Energy Conversion, Vol. 24, pp. 926– 934, 2009. [18]. B. Boukhezzar, L. Lupu, H. Siguerdidjane, M. Hand,“Multivariable control strategy for variable speed, variable pitch wind turbines”,Renewable Energy vol. 32 pp. 1273–1287, 2007. [19]. Y. Xia, K. H. Ahmed, and B.W. Williams, “Wind Turbine Power Coefficient Analysis of a New Maximum Power Point Tracking Technique,” IEEE Transaction on Industrial Electronics, Vol. 60, No. 3, pp. 1122 – 1132, 2013. [20]. Electranix Corporation, “Feasibility Study Regarding Integration of The Læsø Syd 160 MW Wind Farm Using Vsc Transmission,” http://electranix.com/publication/feasibilitystudy/ Accessed on, 15/8/ 2014.
spellingShingle Effect of grid-connected wind turbine generators on power system transient stability
summary A huge number of wind turbine generators will be integrated into the existing power systems in the near future because it has been identified as one of the most promising field of energy industry. Wind turbines are required to remain connected to the grid during a fault condition so as to support constant power supply. It is therefore necessary to investigate the impact of wind turbine generators on the stability of power systems. This paper presents a comparative study of available wind generator types and examines the effect of penetration level on the power system. Simulations have been performed to compare and demonstrate the transient behavior of a typical 5-machine 22- bus system with and without wind power integration. The simulation results reveal that the transient behavior of wind generators has significant effect on the overall stability of power systems and the increase in penetration level may induce the instability into the systems.
title Effect of grid-connected wind turbine generators on power system transient stability
title_full Effect of grid-connected wind turbine generators on power system transient stability
title_fullStr Effect of grid-connected wind turbine generators on power system transient stability
title_full_unstemmed Effect of grid-connected wind turbine generators on power system transient stability
title_short Effect of grid-connected wind turbine generators on power system transient stability
title_sort effect of grid-connected wind turbine generators on power system transient stability

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