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A Review on Low Voltage Ride-Through Solutions for PMSG Wind Turbine

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Abstract:

The exiting of wind turbines will cause the adverse effect on the power grid and its assembling unit in network voltage drops. So, direct-drive wind power generation system should meet the requirement of the certain ability of low voltage. This paper introduces the influence of wind power system with different structure by voltage drop as well as the disadvantage and advantage on LVRT. The relate regulations based on LVRT are analyzed. The existing LVRT technologies of direct-drive wind power systems are briefly presented. The characteristics of each scheme from the different LVRT technology are analyzed. Moreover, further study of LVRT for PMSG is pointed out.

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Info:

Periodical:

Advanced Materials Research (Volumes 1070-1072)

Pages:

209-215

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1070-1072.209

Citation:

Cite this paper

Online since:

December 2014

Authors:

Mei Zhang*, Hai Qin Xue, Shui Liang Zhou

Keywords:

Direct-Drive Induction Generation, Low Voltage Ride through (LVRT), Reactive Power Support, Wind Power Generation

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© 2015 Trans Tech Publications Ltd. All Rights Reserved

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References

[1] Perdana A, Carlson O, Persson J, Dynamic response of gird-connected wind turbine with doubly-fed induction generator during disturbances[J]. proceeding of Nordic Workshop on Power and Industrial Electronics, 2001(7): 12-14.

Google Scholar

[2] A khmatov V. Variable-speed wind turbines with doubly-fed induction generators: Part IV uninterrupted operation features at gird faults with converter control coordination[J]. Wind Engineering, 2003, 27(6): 529-529.

DOI: 10.1260/030952403773617481

Google Scholar

[3] Zhang Jinping, Wang Ningbo, Ding Kun, Ma Yanhong, Zhou yunshi. Permanent magnet direct-drive wind power system fault crossing technology [A]. 2013. 12 grid and clean energy resources.

Google Scholar

[4] Yao Jun, Liao Yong, Zhuang Kai. Control strategy of LVRT for PMSG in gird fault. Automation of electric power systems, 2009. 6.

Google Scholar

[5] Li Jianlin, Xu shaohua, Direct drive wind power system low voltage through the control strategy. Automation of electric power systems t. 2012. 1.

Google Scholar

[6] Guo Jindong, Li Jianlin, Xu honghua. Variable speed constant frequency wind power grid based on internal model controller [J]. Renewable Energy Resources . 2007, 25 (5).

DOI: 10.1007/978-3-540-75997-3_462

Google Scholar

[7] Meng Qingtian Li Limei etc. study on low voltage ride-though capability for PMSG based on crowbar circuit. Electrical Engineering. 2013. 7.

Google Scholar

[8] Yang Yu-xin, liu view etc. Review of low voltage ride-though technology for direct-drive induction generator based wind energy wind energy conversion system. Electrotechnics Electric. 2012. 6.

Google Scholar

[9] Chen Yaai Liu Jindong etc. Review of low voltage ride-though for Wind power system. Electric Driver. (2013).

Google Scholar

[10] Chen Xingying, Liu Mengjiao, Chan Yuanda. Superconducting energy storage unit in the application of grid type wind power generation system [J]. Proceedings of the csee, 2001 (12).

Google Scholar

[11] Lin Guofu. Study on improve low voltage ride-though of direct-drive wind power system based on Superconducting energy storage. 2013. 5.

Google Scholar

[12] Dong Yunlong. Simulation of static synchronous compensator(STATCOM). Nanjing: southeast university, (2004).

Google Scholar

[13] He Xiongfeng, Ji tonzhou etc. Analysis on low voltage ride-though techniques for wind turbines using doubly-fed induction generator. Chinese society for electrical engineering, 2012, 2012, 11.

DOI: 10.1109/appeec.2012.6307096

Google Scholar

[14] Gu Wei, li xingyuan, etc. Dynamic simulation research Based on the wind stability of the UPFC. 2010. 6.

Google Scholar

[15] Wang Hongfu, Lin guoqingg, etc. By using series brake resistance increase wind power low voltage through technology [J]. Automation of electric power systems, 2008, 32 (18): 81-85.

Google Scholar

[16] Li Jianlin, Hu shujue, Kong Deguo, Xu honghua. Study on low voltage ride through characteristic of full power converter direct-drive wind power system . (2008).

DOI: 10.1109/ipemc.2009.5157770

Google Scholar

[17] Morren J, Pierik J T G , de Haan S W H. Voltage dip ride-through control of direct-drive wind turbines[C]. Universities Power Engineering Conference , 2004(2): 934-938.

Google Scholar

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