直驱式波浪发电用全超导初级励磁直线发电机的设计与分析

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摘要初级永磁直线电机具有次级结构简单的特点,十分适用于直驱式波浪发电。基于广泛应用于波浪发电的游标混合电机和磁通切换直线电机,本文提出一种采用超导绕组的初级励磁直线发电机,该电机的性能的得到大幅提高。通过超导绕组和多齿结构的设计可提高电机的磁场能量并克服易去磁和高定位力等游标直线电机的缺点。首先,介绍了电机的基本结构和工作原理,给出了电机超导励磁绕组和电枢绕组的设计结构,并完成了超导绕组的直流导电性能测试和交流损失计算。然后,通过二维有限元法,对电机的空载特性进行仿真分析,并与相应的游标混合电机和磁通切换直线电机进行了对比。另外,对电机的负载特性进行了仿真,并将其带载能力与磁通切换直线电机进行了对比。最后,采用一台磁通切换永磁直线电机验证了对其带载能力的有限元分析结果。所有结果表明,全超导初级励磁直线发电机相对其它两类电机具有其独特的优势。

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	黄磊
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	余海涛
	施智祥
	仲伟波

关键词 ：直线发电机, 全超导, 初级励磁, 设计, 有限元分析

Abstract：Primary permanent magnet linear generators have advantage of simple structure of secondary, which is suitable for the application of wave energy conversion. Based on the vernier hybrid machines(VHMs), widely used for direct drive wave energy converters, and flux-switching permanent magnet linear machines(FSPMLMs), this paper proposes a novel tubular fully-superconducting primary-excitation linear generator(FSPELG), which can effectively improve the performance of this kind of generators. MgB₂ type windings and multi-tooth structure are used in the generator to increase the magnetic energy and overcome the disadvantages of easily irreversible demagnetization and high cogging force of the VHMs and FSPMLMs. Firstly, the operation principle and structure of the generator are introduced. Based on the MgB₂ wire, produced and measured in the laboratory, the structure of DC superconducting filed windings and AC superconducting armature windings used for the generator are designed, and AC losses of AC windings are calculated. Secondly, by using the finite element method, the no-load performances of the generator are analyzed and compared with ones of a VHM and a FSPMLM. In addition, the on-load performance of the proposed generator is obtained by finite element analysis(FEA). Lastly, a prototype of the linear flux-switching generator is used to verify the correctness of FEA results. All the results validate the proposed generator has better performance than its counterparts.

Key words： Linear generator fully-superconducting primary-excitation design finite element analysis

收稿日期: 2014-08-20 出版日期: 2015-04-14

PACS:

TM359.4

基金资助:国家自然科学基金（51407027）和江苏省自然科学基金（BK20130613）资助项目

作者简介: 黄磊男,1980年生,讲师,研究方向为直线电机设计与优化及控制系统研究。胡敏强男,1961年生,教授,博士生导师,研究方向为微特电机及其控制,海洋能发电新技术研究。

引用本文:

黄磊,胡敏强,余海涛,施智祥,仲伟波. 直驱式波浪发电用全超导初级励磁直线发电机的设计与分析[J]. 电工技术学报, 2015, 30(2): 80-86. Huang Lei,Hu Minqiang,Yu Haitao,Shi Zhixiang,Zhong Weibo. Design and Analysis of a Fully-Superconducting Primary-Excitation Linear Generator for Direct-Driven Wave Energy Generation. Transactions of China Electrotechnical Society, 2015, 30(2): 80-86.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2015/V30/I2/80

[1] 游亚戈, 李伟, 刘伟民, 等. 海洋能发电技术的发展现状与前景[J]. 电力系统自动化, 2010, 34(14): 1-12. You Yage, Li Wei, Liu Weimin, et al. Development status and perspective of marine energy conversion systems[J]. Automation of Electric Power Systems, 2010, 34(14): 1-12.
[2] Vining J, Lipo T A, Venkataramanan G. Experimental evaluation of a doubly-fed linear generator for ocean wave energy applications[C]. IEEE Energy Conversion Congress and Exposition: Energy Conversion Innovation for a Clean Energy Future, 2011: 4115-4122.
[3] Prudell J, Stoddard M, Amon E, et al. A permanent- magnet tubular linear generator for ocean wave energy conversion[J]. IEEE Transactions on Industry Applications, 2010, 46(6): 2392-2400.
[4] Vining J, Lipo T A, Venkataramanan G. Design and optimization of a novel hybrid transverse longitudinal flux, wound-field linear machine for ocean wave energy conversion[C]. IEEE Energy Conversion Congress and Exposition, 2009 : 3726-3733.
[5] Brooking P R M, Mueller M A. Power conditioning of the output from a linear vernier hybrid permanent magnet generator for use in direct drive wave energy converters[J]. IEE Proc. -Gener. Transm. Distrib. , 2005, 152(5): 673- 681.
[6] 杜怿, 程明, 邹国棠. 初级永磁型游标直线电机设计与静态特性分析[J]. 电工技术学报, 2012, 27(11): 22-30. Du Yi, Cheng Ming, Zou Guotang. Design and analysis of a new linear primary permanent magnet vernier machine[J]. Transactions of China Electrotech- nical Society, 2012, 27(11): 22-30.
[7] Mueller M A, Wallace R. Enabling science and technology for marine renewable energy[J]. Energy Policy, 2008, 36(12): 4376-4382.
[8] Polinder H, Mueller M A, Scuotto M, et al. Linear generator systems for wave energy conversion[C]. Proceedings of the 7th European Wave and Tidal Energy Conference, 2007.
[9] Keysan O, Mueller M A. A linear superconducting generator for wave energy converters[C]. 6th IET International Conference on Power Electronics, Machines and Drives(PEMD 2012), Bristol, UK, 2012.
[10] Fukui Satoshi, Ogawa Jun, Sato Takao, et al. Study of 10MW class wind turbine synchronous generators with hts field windings[J]. IEEE Transactions on Applied Superconductivity, 2011, 21(3): 1151-1154.
[11] 陈彪, 顾国彪. 高温超导电机转子冷却技术的研究[J]. 电工技术学报, 2011, 26(10): 143-151. Chen Biao, Gu Guobiao. Cooling technology of rotor of high temperature superconducting electrical machines [J]. Transactions of China Electrotechnical Society, 2011, 26(10): 143-151.
[12] Qu Ronghai, Liu Yingzhen, Wang Jin. Review of superconducting generator topologies for direct-drive wind turbines[J]. IEEE Transactions on Applied Superconductivity, 2013, 23(3): 5201108.
[13] Kajikawa K, Osaka R, Kuga H, et al. Proposal of new structure of MgB2 wires with low AC loss for stator windings of fully superconducting motors located in iron core slots[J]. Phys. C, 2011, 471(21/22): 1470- 1473.
[14] Keysan O, Mueller M A. Superconducting generators for renewable energy applications[C]. Proc. IET Conf. RPG, 2011: 1-6.
[15] 闻海虎. 新型超导体二硼化镁(MgB 2 )基础研究及其应用展望[J]. 物理, 2003, 32(5): 325-326. Wen Haihu. The new superconductor MgB 2 and its application[J]. Physics, 2003, 32(5): 325-326.
[16] Terao Y, Sekino M, Ohsaki H. Electromagnetic design of 10MW class fully superconducting wind turbine generators[J]. IEEE Transactions on Applied Superconductivity, 2012, 22(3): 5201904.
[17] Huang Lei, Yu Haitao, Hu Minqiang, et al. A novel flux-switching permanent-magnet linear generator for wave energy extraction application[J]. IEEE Transac- tions on Magnetics, 201147(5): 1034-1037.
[18] Kajikawa Kazuhiro, Hayashi Toshihiro, Yoshida Ryoji, et al. Numerical evaluation of AC losses in HTS wires with 2D FEM formulated by self magnetic field[J]. IEEE Transactions on Applied Supercon- ductivity, 2013, 13(2): 3630-3633.