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基于生物控制算法的波浪发电系统控制策略 被引量:1

Control Strategy of Wave Energy Conversion System Based on Biological Intelligent Control Algorithm
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摘要 针对直驱式波浪发电系统输出功率以及经过PWM整流得到的直流电压波动较大问题,基于睾丸性激素反馈调节原理,设计了一种基于生物智能控制算法的控制器,对直驱式波浪发电系统结构及直驱式波浪发电PWM整流器和逆变器控制策略进行了阐述。Matlab/Simulink仿真结果表明,基于生物智能控制算法的新型控制器较传统PI控制器响应速度快、超调量小、稳定性好。 Aiming at the output power of direct-drive wave energy conversion(DDWEC)system and the problem of larger direct voltage fluctuation obtained by pulse-width modulation(PWM)rectification,this paper designed a kind of controller based on the biological intelligent control algorithm according to the feedback modulation principle of testosterone release,and expounded the DDWEC system structure and the control strategy of PWM rectification and inverter.The simulation results of Simulink in Matlab show that the new type controller based on the biological intelligent control algorithm has faster response speed,smaller overshoot and better stability than the traditional proportion integration(PI)controller.
作者 郁正纲 付明 王琛 黄磊 陈珉烁 YU Zheng-gang;FU Ming;WANG Chen;HUANG Lei;CHEN Min-shuo(State Grid Lianyungang Power Supply Company, Lianyungang 222002, China;State Grid Nari Technology Co.,Ltd, Nanjing 210061, China;Southeast University, Nanjing 210096, China)
机构地区 国网连云港供电公司 国电南瑞科技股份有限公司 东南大学
出处 《电工电气》 2018年第3期18-21,53,共5页 Electrotechnics Electric
基金 江苏省电力公司2016年科技项目(5210D0150512)
关键词 直驱式波浪发电 睾丸性激素反馈调节原理 生物智能控制 direct-drive wave energy conversion system feedback modulation principle of testosterone release biological intelligent control
分类号 TM351 [电气工程—电机]
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  • 1刘宝,丁永生.一种基于睾丸素分泌调节原理的双层结构控制器[J].上海交通大学学报,2006,40(5):822-824. 被引量:13
  • 2陶果,邓琦,邱阿瑞,范航宇.永磁直线波力发电机的磁场分析与参数计算[J].清华大学学报(自然科学版),2007,47(1):1-4. 被引量:11
  • 3Ding Y S, Ren L H, Fuzzy self-tuning immune feedback controller for tissue hyperthermia [C]//Prrceedings of the Ninth IEEE International Conference on Fuzzy System (FUZZ-IEEE 2000) . Hilton Palacio del Rio, San Antonio, Texas, USA: Institute of Electrical and Electronics Engineers Inc, 2000:534-538.
  • 4I.iu B, Ding Y S. An intelligent controller based on primary secondary responding mechanism of immunesystem [[C]//Proceedings of 7th International Conference on Computational Intelligence and Natural Computing. Salt Lake City, UTAH, USA; X-CD Technologies, 2005: 467-470.
  • 5Farhy I. S. Modeling of oscillations of endocrine networks with feedback[J]. Methods Enzymol, 2004,384:54-81.
  • 6Keenan D M, Licinio J, Veldhuis J D. A feedback-controlled ensemble model of the stress responsive hypothalamo-pituitary-adrenal axis[J]. PNAS, 2001, 98(7):4098-4033.
  • 7Bedard R. Feasibility of using Wavewatch III for days-ahead output forecasting for grid connected wave energy projects in Washington and Oregon, Electr. Power Res. Inst. (EPRI), PaloAlto[EB/OL][2008-02-29]. http: //oceanenergy.epri.com/attachments/wave/reports/Wave_F orecasting Final Reoort.pdf.
  • 8Leijon M, Waters R, Rahm M. Catch the wave to electricity[J]. IEEE Power Energy Magnetics, 2009, 7(1): 50-54.
  • 9Thorpe T W, Picken M J. Wave energy devices and the marine environment[J], lEE Proceedings-A, 1993, 140(1): 63-70.
  • 10Ran L, Mueller MA, Ng C, et al. Power conversion and control for a linear direct drive permanent magnet generator for wave energy[J]. IET Renewable Power Generation, 2011, 5(1): 1-9.

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电工电气
2018年 第3期

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