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中国电机工程学报 2015

基于双馈感应风力发电机虚拟惯量和桨距角联合控制的风光柴微电网动态频率控制

DOI: 10.13334/j.0258-8013.pcsee.2015.15.009, PP. 3815-3822

赵晶晶, 吕雪, 符杨, 胡晓光

Keywords: 孤岛运行微电网,动态频率控制,双馈感应风力发电机,虚拟惯量控制,桨距角控制

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Abstract:

微电网孤岛模式下的频率稳定性是微电网安全稳定运行的重要保证。为提高微电网频率动态特性,通过在双馈感应风电机组(doublyfedinductiongenerator,DFIG)中加入虚拟惯量控制环节,增加微电网惯性,释放转子中储存的部分动能为微电网频率提供动态支持;为解决虚拟惯性控制环节加入后转子转速恢复过程中DFIG的有功功率跌落问题,采用桨距角控制,在频率跌落时释放DFIG备用功率,从而弥补转速恢复过程的功率跌落,并减小电网的稳态频率偏差。结合DFIG虚拟惯量特性和桨距角控制,配合柴油机的一次调频功能,有效抑制了负荷变化引起的微电网频率波动。最后在DIgSILENTPowerFactory仿真软件中建立含柴油发电机、光伏电池、DFIG的微电网控制模型,验证了所提策略的有效性。

References

[1]	Peas J A,Moreira C L,Madureira A G．Defining control strategies for microgrids islanded operation[J]．IEEE Transactions on Power Systems,2006,21(2)：916-924．
[2]	王成山,肖朝霞,王守相．微网综合控制与分析[J]．电力系统自动化,2008,32(7)：98-103．Wang Chengshan,Xiao Zhaoxia,Wang Shouxiang．Synthetical control and analysis of microgrid[J]．Automation of Electric Power Systems,2008,32(7)：98-103(in Chinese)．
[3]	黄伟,牛铭．微电网非计划孤网控制策略分析[J]．电力系统自动化,2011,35(9)：42-46．Huang Wei,Niu Ming．Analysis on non-planed isolated control strategy for microgrid[J]．Automation of Electric Power Systems,2011,35(9)：42-46(in Chinese)．
[4]	张明锐,杜志超,黎娜,等．高压微网孤岛运行时频率稳定控制策略研究[J]．中国电机工程学报,2012,32(25)：20-26．Zhang Mingrui,Du Zhichao,Li Na,et al．Control strategies of frequency stability for islanding high-voltage microgrids[J]．Proceedings of the CSEE,2012,32(25)：20-26(in Chinese)．
[5]	Ouddalov A,Chartouni D,Ohler C．Optimizing a battery energy storage system for primary frequency control[J]．IEEE Transactions on Power Systems,2007,22(3)：1259-1266．
[6]	丁明,杨向真,苏建徽．基于虚拟同步发电机思想的微电网逆变电源控制策略[J]．电力系统自动化,2009,33(8)：89-95．Ding Ming,Yang Xiangzhen,Su Jianhui．Control strategies of inverters based on virtual synchronous generator in a microgrid[J]．2009,33(8)：89-95(in Chinese)．
[7]	杜威,姜齐荣,陈蛟瑞．微电网电源的虚拟惯性频率控制策略[J]．电力系统自动化,2011,12(10)：26-30．Du Wei,Jiang Qirong,Chen Jiaorui．Frequency control strategy of distributed generations based on virtual inertia in a microgrid[J]．Automation of Electric Power Systems,2011,12(10)：26-30(in Chinese)．
[8]	曹军,王虹富,邱家驹．变速恒频双馈机组频率控制策略[J]．电力系统自动化,2009,33(13)：79-82．Cao Jun,Wang Hongfu,Qiu Jiaju．Frequency control strategy of variable-speed constant-frequency doubly-fed induction generatorwind turbines[J]．Automation of Electric Power Systems,2009,33(13)：79-82(in Chinese)．
[9]	Vidyanandan K V,Senroy N．Primary frequency regulation by deloaded wind turbines using variable droop[J]．IEEE Transactions on Power Systems,2013,28(2)：837-846．
[10]	李旭光．微电网的建模、仿真、运行特性分析[D]．天津：天津大学,2009．Li Xuguang．Modeling and simulation of micro-grid and operating characteristic analysis[D]．Tianjin：Tianjin University,2009(in Chinese)．
[11]	徐少华,李建林．光储微电网系统孤岛/并网运行控制策略[J]．中国电机工程学报,2013,33(34)：25-33．Xu Shaohua,LI Jianlin．Grid-connected/island operation control strategy for photovoltaic/battery micro-grid[J]．Proceedings of the CSEE,2013,33(34)：25-33(in Chinese)．
[12]	彭喜云,刘瑞叶．变速恒频双馈风力发电机辅助调频系统的研究[J]．电力保护与控制,2011,39(11)：56-61．Peng Xiyun,Liu Ruiye．Research on the frequengcy regulation of aidding system of VSCF double-fed wind generator[J]．Power System Protection and Control,2011,Vol 39,No．11：56-61(in Chinese)．
[13]	Keung Ping-Kwan,Li Pei,Banakar H．Kinetic energy of wind-turbine generators for system frequency support[J]．IEEE Transactions on Power Systems,2009,24(1)：279-287．
[14]	Kayikci M,Milanovic J V．Dynamic contribution of doubly-based wind plants to system frequency disturbances[J]．IEEE Transactions on Power Syetems．2009,24(22)：859-867．
[15]	李和明,张祥宇,王毅,等．基于功率跟踪优化的双馈风电机组虚拟惯性控制技术[J]．中国电机工程学报,2012,32(7)：32-39．Li Heming,Zhang Xiangyu,Wang Yi,et al．Virtual inertia control of dfig-based wind turbines based on the optimal power tracking[J]．Proceedings of the CSEE,2012,32(7)：32-39(in Chinese)．
[16]	Ma H T,Chowdhury B H．Working towards frequency regulation with wind plants：combined control approaches[J]．IET Renewable Power Generation,2010,4(4)：308-316．
[17]	赵晶晶,吕雪,符杨,等．基于可变系数的双馈风机虚拟惯量与超速控制协调的风光柴微电网频率调节技术[J]．电工技术学报,2015,30(9)：59-68．Zhao Jingjing,Lü Xue,Fu Yang,et al．Frequency regulation of wind/photovoltaic/diesel microgrid based on DFIG cooperative strategy with variable coefficients between virtual inertia and over speed control[J]．Transactions of China Eletrotechnical Society,2015,30(9)：59-68(in Chinese)．
[18]	Wang Ye,Delille G,Bayem H．High wind power penetration in isolated power systems-assement of wind inertial and primary frequency response[J]．IEEE Transactions on Power System．2013,28(3)：2412-2420．
[19]	Erlich I,Wilch M,Primary frequency control by wind turbines[C]//2010 IEEE Power and Energy Society General Meeting．Minnesota,USA：IEEE Power & Energy Society,2010：1-8．
[20]	张昭遂,孙元章,李国杰等．超速与变桨协调的双馈风电机组频率控制[J]．电力系统及其自动化,2011,35(17)：20-25．Zhang Zhaosui,Sun Yuanzhang,Li Guojie et al．Frequency regulation by doubly fed induction generator wind turbines based on coordinated overspeed control and pitch control[J]．Automation of electric power systems．2011,35(17)：20-25(in Chinese)．
[21]	刘巨,姚伟,文劲宇,等．大规模风电参与系统频率调整的技术展望[J]．电网技术,2014,38(3)：638-646．Liu Ju,Yao Wei,Wen Jinyu,et al．Prospect of technology for large-scale wind farm participating into power grid frequency regulation[J]．Power System Technology,2014,38(3)：638-646(in Chinese)．
[22]	贺益康,胡家兵,徐烈．并网双馈异步风力发电机运行控制[M]．北京：中国电力出版社,2011：29-30．He Yikang,Hu Jiabing,Xu Lie．Operational control of grid-connected doubly fed induction generator[M]．Beijing：China Electric Power Press,2011：29-30(in Chinese)．
[23]	Attya A B,Hartkopf T．Wind turbine contribution in frequency drop mitigation：modified operation and estimating released supportive energy[J]．IET Renewable Power Generation．2014,8(5)：862-872．
[24]	Piter T,Simon D R,Kailash S．Frequency support by wind power plants in isolated grids with varying generation mix[C]//IEEE Power & Energy Society Transctions．San Diego,USA,2012：1-8．

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