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变频柜在风电机组塔底工作的散热研究 被引量:4

Study of Heat Dissipation of Frequency Converter of Wind Turbine Tower Bottom
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摘要 针对目前风电行业中较常见的变频柜等电气元件下置的方案,进行了优势分析和缺点比较。以质量、动量和能量守恒定律以及标准湍流模型为建模理论基础,通过CFD流体软件的计算,对塔筒底部变频柜工作环境的速度场和温度场进行了数值分析。通过分析结果可以得出,加装了轴流风机进行强制通风换热的塔简底部空间的温度环境能够满足变频柜等各个电气部件正常工作的要求,同时,结合结构设计和布局中的不合理之处,提出建议改进。本文提出的塔底空间风冷散热方案的计算,不仅对风电机组结构布局的合理性有着重要意义,对风电机组机舱内及各个散热部件的计算也具有一定的借鉴价值。 For the current wind power industry, the more common converter cabinet and other electrical components under the program, the advantages of analysis and comparison of shortcomings. Based on the law of mass, momentum and energy conservation and the standard turbulence model, the velocity field and temperature field of the working environment of the converter cabinet at the bottom of the tower are analyzed by CFD fluid software. Through the analysis of the results can be obtained, the installation of axial fan for forced ventilation heat transfer tower bottom space temperature environment to meet the frequency cabinet and other electrical components of the normal work requirements, combined with structural design and layout of the unreasonable To make suggestions for improvement. The calculation of air cooling and cooling scheme in the bottom of the tower is not only important for the rationality of the wind turbine structure, but also has some reference value for the calculation of the heat dissipation parts in the engine room.
作者 陈明 陈永军 李力森 Chen Ming;Chen Yongjun;Li Lisen(Sinovel Wind Group Co., Ltd. Beijing 100086 China)
出处 《电气工程学报》 2018年第5期33-39,共7页 Journal of Electrical Engineering
基金 上海市科学技术委员会项目“深远海上风电机组设计开发及运维相关技术研究”(16DZ1203505)
关键词 塔筒底部 风电机组 变频柜 温度场 Tower bottom wind turbine frequency converter temperature field
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  • 1李炜.水力计算手册[M].2版.北京:中国水利水电出版社,2006.
  • 2邢国清.流体力学泵与风机[M].2版.北京:中国电力出版社,2009.
  • 3杨思祥,李国杰,阮思烨,董健.应用于DFIG风电场的VSC-HVDC控制策略[J].电力系统自动化,2007,31(19):64-67. 被引量:49
  • 4Chen Z, Blaabjerg F. Wind farm-a power source in future power systems [J]. Renewable and Sustainable Energy Reviews, 2009, 13 (6) 1288-1300.
  • 5Shi G, Wu G, Cai X, et al. Coordinated control of multi-terminal VSC-HVDC transmission for large offshore wind farms [C]. Power Electronics and Motion Control Conference, Harbin, China, 1EEE, 2012: 1278-1282.
  • 6Cespedes M, Sun J. Renewable instability involving grid-par energy systems allel inverters [C]. Applied Power Electronics Conference and Exposition, Washington DC, USA, IEEE 2009: 1971-1977.
  • 7Liu H, Sun J. Voltage stability and control of offshore wind farms with AC collection and HVDC transmission [J]. IEEE Journal of Emerging and Selected Topics in Power Electronics, 2014, 2 (4) 1181-1189.
  • 8Mei F, Pal B. Modal analysis of grid-connected doubly fed induction generators [J]. IEEE Transactions on Energy Conversion, 2007, 22 (3) : 728-736.
  • 9Turner R, Walton S, Duke R. Stability and bandwidth implications of digitally controlled grid- connected parallel inverters [J]. IEEE Transactions on Industrial Electronics, 2010, 57 (11) : 3685- 3694.
  • 10HU T, TANG R Y, LI Y, et al. Themml analysis and calculation of permanent magnet wimt generators[J]. Transactions of China Eleetroteelmical Society, 2013, 28 ( 3 ) : 122-126. DOI : 10. 3969/j. issn. 1000.6753. 2013.03. 017.

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