风电叶片除冰技术的研究进展

摘要/Abstract

摘要： 风能作为替代世界传统能源的清洁能源之一,近几年来已在我国发展迅猛。我国已建或规划建设的风场,大多处在高山及边疆区域,风电机组必然面临覆冰的考验。风电叶片覆冰严重影响风电叶片的气动性能、载荷和功率输出。本文概括阐述了叶片表面覆冰起因、覆冰区域及覆冰危害,并概括讨论了各种除冰方法。

关键词: 风电叶片, 除冰技术, 研究进展

Abstract: Wind energy is a renewable power source that produces no known significant atmospheric pollution. Wind turbines are increasingly erected for the next years. Inland sites and especially sites in mountainous areas and frontier regions, turbines will be affected by ice during standstill and operation. Ice at low temperatures will cause severe effects on the aerodynamics and thus, on the loads and the power output of the turbine. In the following sections the formation of the ice, Ice accretion profile and the problems due to icing are discussed. Beside, This paper summaries and discusses technical solutions on the systems which can be used for the cold climate conditions.

Key words: wind turbine blades, de-icing technology, research and development

中图分类号:

TB332

王伟, 侯学杰, 管晓颖, 黎华. 风电叶片除冰技术的研究进展[J]. 复合材料科学与工程, 2014, 0(1): 90-93.

WANG Wei, HOU Xue-jie, GUAN Xiao-ying, LI-hua. RESEARCH AND DEVELOPMENT ON DE-ICING TECHNOLOGY OF WIND TURBINE BLADE[J]. COMPOSITES SCIENCE AND ENGINEERING, 2014, 0(1): 90-93.

参考文献

[1] 李超, 沈凤亚, 余国城. 兆瓦级风力发电机机舱罩强度分析与设计[J].玻璃钢/复合材料, 2012,(3):3-6.
[2] 钱建华, 刘坐镇, 周润陪, 柏孝达. 大型风力发电叶片专用高性能树脂[J].玻璃钢/复合材料, 2012,(3):70-74.
[3] 李晓拓, 祝颖丹, 彦春, 范欣愉. 风力机叶片气动弹性剪裁研究进展[J].玻璃钢/复合材料, 2012,(2):67-71.
[4] Andersson L O, Golander C G, Persson S. Ice adhesion to rubber materials[J]. J. Adhes. Sci. Technol, 1994,(8):117-132.
[5] Ayeres J, Simendinger W H, Balik C M. Characterization of titanium alkoxide sol-gel systems designed for anti-icing coatings: II. Mass loss kinetics. [J]. J.Coat. Technol.Res, 2007b,(4):473-481.
[6] 许志海, 贾志东, 关志成, 李智宁, 韦晓星, 王黎明. 输电线路绝缘子湿增长覆冰特性及除冰涂料试验研究[J].高电压技术, 2011,(3):562-569.
[7] 洪海华, 刘伟光, 艾剑波, 徐伟荣. 直升机的防除冰系统[J]. 直升机技术, 2010,(1):52-56.
[8] 丛树枫, 喻露如. 聚氨酯涂料[M]. 北京:化学工业出版社,2003.
[9] 印水嘉, 奚正楷, 李大珍. 物理化学简明教程[M]. 北京:高等教育出版社,2000.
[10] Bose N. Icing on a small horizontal-axis wind turbinepart I: glazeice profiles [J]. Journal of wind Engineering and Industrial Aerodynamics, 1992,(45): 75-85.
[11] Bose N. Icing on a small horizontal-axis wind turbinepart II: three dimensional ice and wet snow formations [J]. Journal of Wind Engineering and Industrial Aerodynamics, 1992,(45):87-96.
[12] Dalili N, Edrisy A, Carriveau R. A review of surface engineering issues critical to wind turbine performance[J]. Renewable and Sustainable Energy Reviews, 2009,(13):428-438.
[13] 邓晓湖, 卢绪祥, 李录平, 李海波. 水平轴风力机叶片翼型结冰的数值模拟[J]. 能源技术, 2010,(5):266-271.
[14] Jasinski W J, Noe S C, Selig M C, Bragg M B. Wind turbine performance under icing conditions [J]. Trans ASME J Sol Energy Eng, 1998,(120):60-65.
[15] Antikainen P, Peuranen S. Ice loads case study [R]. In: Proceedings of BOREAS V conference; 2000.
[16] Tammelin B, Cavaliere M, Holttinen H, Morgan C, Seifert H, Santti K. Unattainable Wind energy production in cold climate (WECO) (Photo courtesy of Kranz) [R]. Publishable report, 1996-1998.
[17] David Cole Magnuson. Method and system fordeicing wind turbine rotor blades with induced torque[P]. US: 6890152, 2012.10.23.
[18] Y·原口. 用于给风轮机的叶片除冰的方法、风轮机及其使用[P]. 中国: 101821500 A, 2010.09.01.
[19] R. 库马, V. M. 希雷马斯, D. 萨卡拉朱,K. V. 劳, N. R. 纳达姆帕. 利用于对风力涡轮机转子叶片进行清洁和除冰的方法和装置[P]. 中国: 2010,10208585, 2010. 12. 22.
[20] 谭海辉, 李录平, 靳攀科, 李芒芒. 风力机叶片超声波除冰理论与方法[J]. 中国电机工程学报, 2010,(35)112-117.
[21] Talhaug L, Vindteknik K, Ronsten G, Horbaty R, Baring-Gould I, Lacroix A, et al. Wind energy projects in cold climates. 1st ed. Executive Committee of the International Energy Agency Program for Research and Development on Wind Energy Conversion Systems; 2005, 1-36.
[22] Jasinski W J, Noe S C, Selig M C, Bragg MB. Wind turbine performance under icing conditions [J]. Trans ASME J Sol Energy Eng. 1998(120): 60-65.
[23] Homola MC. Wind energy in BSR: impacts and causes of icing on wind turbines[J]. For Interreg IIIB Project partners, 2005(3): 1-15.
[24] SEIFERT H. Technical Requirements for Rotor Blades Operating in Cold Climates[C]. German Wind Energy Institute, 1996.
[25] D·L·勒米. 厄用于除去翼型或转子叶片上的冰的方法和装置[P]. 中国: 1727673 A, 2006.2.1.
[26] 张自国, 孙如林, 田野, 田卫国, 姜兆民, 高凤羽, 庄岳兴. 防止结冰的风力发电机组风轮叶片[P].中国:ZL 200920000676.5, 2009.
[27] 代海涛, 叶凡. 一种风力发电机组叶片除冰抗冰系统[P]. 中国: 202181995 U, 2012.04.04.
[28] 何玉林, 杨豆思, 王磊, 侯海波, 杜静, 谢双义. 大型风力发电机叶片除冰方法[P]. 中国: 102003353A, 2011.04.06.
[29] Maissan J F. Wind power development in sub-Arctic conditions with severe rime icing[C]. In: Circumpolar climate change summit and exposition; 2001.
[30] 胡志标. 一种防结冰涂料及其制备方法[P]. 中国: 102585635 A (审查中).
[31] 潘煜怡, 陈月珍, 张伟丽. 改性聚硅氧烷面漆的发展现状[J]. 涂料技术与文摘, 2010, (04): 23-26.
[32] 李谌, 乔波, 侯一斌, 姚其胜, 陆企亭. 一种适用于风电叶片的除冰、耐磨涂层[P]. 中国: 102031057A, 2011.04.27.
[33] 王智和, 丁鹤雁, 任静. 涂料用含硅丙烯酸树脂的研究进展[J]. 有机硅材料, 2001,(04):29-33.
[34] 郭智臣. 海洋化工研究院成功研制憎水型除冰涂料[J]. 化学推进剂与高分子材料, 2008(2)36.
[35] Shigeo Kimura The effect of anti-icing on the adhesion force of ice accretion on a wind turbine blade[J]. BOREAS VI, 2003, (4): 9-11.