基于超级电容储能的直驱海浪发电功率平抑控制策略研究

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摘要直驱海浪发电装置随海浪起伏运动会导致直线发电机输出功率的大范围频繁波动,对电网电能质量造成不良影响,并大大降低了电力电子变换装置的利用率。本文提出一种基于超级电容储能的功率波动平抑策略,通过在海浪发电并网的直流母线上并联由超级电容和双向DC-DC变换器组成的储能单元,实现对永磁直线发电机输出功率的调节,平抑海浪发电功率的波动。本文设计了带储能单元的海浪发电并网系统各部分协调控制策略,在MATLAB/Simulink中搭建了仿真模型,实现了电机侧变流器最大海浪能跟踪、电网侧变流器单位功率因数并网和超级电容单元对海浪发电并网功率波动的平抑,验证了协调控制策略的正确性。

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	康庆
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	黄立培

关键词 ：直驱海浪发电, 永磁直线电机(PMLG), 超级电容, 功率平抑

Abstract：The power generated by wave energy has the problem of variable amplitude and frequency which makes it impossible to connect to power grid directly. The paper presents a wave power generation which connected to grid composed of permanent magnetic linear generator(PMLG), generator side converter, grid side converter, controller and grid. Control strategies basing on back to back converter structure was proposed: vector decoupling control was used to generator side converter aiming at maximum power extraction from wave energy; Grid voltage oriented control is used to grid side converter in order to make the current sinusoidal and realize unit power factor control. Since the DC link voltage has fluctuation using traditional method, a method with power feed forward was proposed to keep the DC link voltage stable and improve the dynamic response of the system. A simulation model was built for the whole system and simulation results verify that the proposed power electronic converter structure and control strategy are feasible and effective.

Key words： keywords：Directly driven wave power generation permanent magnet linear generator(PMLG) supercapacitor(SC) power smoothing

收稿日期: 2012-09-20 出版日期: 2013-12-12

PACS:

TM315

基金资助:国家自然科学基金(51177084,50823001)和台达电力电子科教基金(DREK2011001)资助项目。

作者简介: 康庆女，1985年生，博士研究生，研究方向为永磁电机控制、海浪发电与电力储能。肖曦男，1973年生，博士，副教授，博士生导师，研究方向为交流伺服电机控制、新能源发电与电力储能。

引用本文:

康庆, 肖曦, 聂赞相, 黄立培. 基于超级电容储能的直驱海浪发电功率平抑控制策略研究[J]. 电工技术学报, 2013, 28(1增): 43-49. Kang Qing, Xiao Xi, Nie Zanxiang, Huang Lipei. Power Smoothing in Directly Driven Wave Power Generation System with Supercapacitor as Energy Storage Unit. Transactions of China Electrotechnical Society, 2013, 28(1增): 43-49.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2013/V28/I1增/43

[1] 王兆安, 杨君, 刘进军. 谐波抑制和无功功率补偿[M]. 北京: 机械工业出版社, 1998.
[2] Venturini M. A new sine wave in sine wave out, conversion technique which eliminates reactive elements[C]. Proceedings of the 1980 International Conference on Power System Technology (POWERCONT), 1980: E3_1-E3_15.
[3] Huber L, Borojevic D. Space vector modulated three-phase to three-phase matrix converter with input power factor correction[J]. IEEE Transactions on Industry Applications, 1995, 31(6): 1234-1246.
[4] 马星河, 谭国俊, 方永丽, 等. 矩阵变换器变步长换流策略[J]. 电工技术学报, 2007, 22(9): 93-98.
Ma Xinghe, Tan Guojun, Fang Yongli, et al. Varying- step commutation strategy of matrix converter[J]. Transactions of China Electrotechnical Society, 2007, 22(9): 93-98.
[5] Mcarthur S, Brekken T K A. Ocean wave power data generation for grid integration studies[C]. Proceedings of the IEEE Power and Energy Society General Meeting (PES), 2010: 1-6.
[6] Tedd J, Peter Kofoed J. Measurements of overtopping flow time series on the Wave Dragon, wave energy converter[J]. Renewable Energy, 2009, 34(3): 711- 717.
[7] Folley M, Curran R, Whittaker T. Comparison of LIMPET contra-rotating wells turbine with theoretical and model test predictions[J]. Ocean Engineering, 2006, 33(8-9): 1056-1069.
[8] Polinder H, Damen M E C, Gardner F. Linear PM Generator system for wave energy conversion in the AWS[J]. IEEE Transactions on Energy Conversion, 2004, 19(3): 583-589.
[9] Polinder H, Scuotto M. Wave energy converters and their impact on power systems[C]. Proceedings of the IEEE Power and Energy Society General Meeting (PES), 2005: 1-9.
[10] Henderson R. Design, simulation, and testing of a novel hydraulic power take-off system for the Pelamis wave energy converter[J]. Renewable Energy Marine Energy, 2006, 31(2): 271-283.
[11] Molinas M, et al. Power electronics as grid interface for actively controlled wave energy converters[C]. Proceedings of the 2007 International Conference on Clean Electrical Power(ICCEP), 2007: 188-195.
[12] Sjolte J, Tjensvoll G Molinas M. All-electric wave energy converter connected in array with common DC- link for improved power quality[C]. Proceedings of the 2012 3rd IEEE International Symposium on Power Electionics for Distributed Generation Systems(PEDG), 2012: 431-436.
[13] Li W, et al. Study of a hybrid offshore wind and seashore wave farm connected to a large power grid through a flywheel energy storage system[J]. Proceedings of the IEEE Power and Energy Society General Meeting(PES), 2011: 1-7
[14] Wu F, Zhang X P, Ju P. Application of the battery energy storage in wave energy conversion system[C]. Proceedings of the First International Conference on Sustainable Power Generation and Supply(SUPERGEN), 2009: 1-4.
[15] Murray B, J M G E. Applications of supercapacitor energy storage for a wave[C]. Proc. WTECON 2009: 786-795.
[16] Murray D B, Hayes J G, O'Sullivan D L, et al. Supercapacitor testing for power smoothing in a variable speed offshore wave energy converter[J]. IEEE Journal of Oceanic Engineering, 2012, 37(2): 301-308.
[17] Z Yu Wu, C Yun Hyun.Thrust ripples suppression of permanent magnet linear synchronous motor[J]. IEEE Transactions on Magnetics,2007, 43(6): 2537-2539.
[18] 赵洋, 梁海泉, 张逸成. 电化学超级电容器建模研究现状与展望[J]. 电工技术学报, 2012, (3): 188-195.
Zhao Yang,Liang Haiquan,Zhang Yicheng．Review and expectation of modeling research on electroche- mical supercapacitor[J]. Transactions of China Elec- trotechnical Society, 2012, (3): 188-195.
[19] Rizoug N,Bartholomeus P,Le Moigne P．Modeling and Characterizing Supercapacitors Using an Online Method[J]. IEEE Transactions on Industrial Electronics, 2010, 57(12): 3980-3990.
[20] António F D. Modelling and control of oscillating- body wave energy converters with hydraulic power take-off and gas accumulator[J]. Ocean Engineering, 2007, 34(14-15): 2021-2032.
[21] 毕大强, 葛宝明, 王文亮, 等. 基于钒电池储能系统的风电场并网功率控制[J]. 电力系统自动化, 2010(13): 72-78.
Bi Daqiang, Ge Baoming, Wang Wenliang, et al. VRB energy storage system based power control of grid-connected wind farm[J]. Automation of Electric Power Systems, 2010 (13): 72-78.
[22] Falnes J. Ocean waves and oscillating systems[M]. London: Cambridge University Press, 2002.