永磁体形状对可变磁通记忆电机调磁参数影响

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摘要采用有限元方法对不同永磁体截面形状的可变磁通记忆电机空载和直轴去磁磁场分布进行了分析, 详细描述了转子内的旁路磁通和零磁通密度区域的变化情况。在此基础上, 研究了永磁体形状改变对每极最大气隙磁通、气隙磁通密度、永磁体中心线上的磁通密度以及最大去磁安匝数等调磁参数的影响。结果表明合理选择永磁体形状可以显著提高永磁体的利用率；永磁体形状系数小于约0.6时, 容易实现对永磁体有效去磁, 而永磁体截面形状接近矩形时则应该将整个永磁体工作点去磁到拐点以下才能保证去磁效果。该成果有助于此类电机的合理设计和控制。

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	刘恒川
	林鹤云
	郭健
	黄学良

关键词 ：可变磁通, 记忆电机, 永磁体形状, 零磁通密度

Abstract：In this paper, the magnetic field distributions of a variable flux memory motor (VFMM) with different rotor permanent magnet (PM) cross section shapes under no-load and d-axis demagnetization are analyzed by finite element method. A detailed description on the changes of bypass flux and zero flux density area in the rotor is given. The influence of PM cross section shape on the field-control parameters of VFMM, such as the maximum air gap flux per pole, the air gap flux density, the maximum demagnetizing ampere-turns, and the flux density on the centerline of PM are numerically investigated. It is found that the utilization ratio of PM can be considerably improved by choosing a reasonable PM section shape. When the PM cross section shape coefficient is less than 0.6, the demagnetization effect of PM can be guaranteed easily. When the PM shape approaches rectangular, to ensure the validity of PM demagnetization, the working point of PM should be demagnetized below the knee point. The conclusions obtained by this paper will be helpful to the design and control of VFMM.

Key words： Variable flux memory motor permanent magnet shape zero flux density

收稿日期: 2007-11-14 出版日期: 2014-02-11

PACS:

TM351

基金资助:国家自然科学基金(50677007)和江苏省青蓝工程基金资助项目

作者简介: 刘恒川男, 1972年生, 博士研究生, 研究方向为特种电机设计。林鹤云男, 1965年生, 博士, 教授, 博士生导师, 研究方向为电机电器、电机电磁场等。

引用本文:

刘恒川, 林鹤云, 郭健, 黄学良. 永磁体形状对可变磁通记忆电机调磁参数影响[J]. 电工技术学报, 2009, 24(2): 14-19. Liu Hengchuan, Lin Heyun, Guo Jian, Huang Xueliang. Influence of Permanent Magnet Cross Section Shape on Field-Control Parameters of Variable Flux Memory Motor. Transactions of China Electrotechnical Society, 2009, 24(2): 14-19.

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http://dgjsxb.ces-transaction.com/CN/Y2009/V24/I2/14

[1] Ostovic V. Memory motors[J]. IEEE Industry Applications Magazine, 2003, 99(1): 52-61.
[2] Ostovic V. Memory motors-a new class of controllable flux PM machines for a true wide speed operation[C]. Thirty-Sixth IAS Annual Meeting, Chicago, USA, 2001(4): 2577-2584.
[3] 孙建忠, 白凤仙. 新概念永磁电机——记忆电机的设计研究[J]. 大电机技术, 2004, 3: 9-12.
[4] Jang Y J, Lee J H, Kim J C. Permanent magnet demagnetization characteristics analysis of a variable flux memory motor using coupled preisach modeling and FEM[C]. IEEE International Magnetics Conference, Digest Record of Conference, 2005: 735-736.
[5] Lim H B, Kim Y H, Lee M M. Permanent magnet demagnetization characteristics analysis of a variable flux memory motor using coupled preisach modeling and FEM[C]. IEEE Electric Machines and Drives Conference, 2007, 1: 647-651.
[6] 陈益广, 王颖, 沈勇环, 等. 宽调速可控磁通永磁同步电机磁路设计和有限元分析[J]. 中国电机工程学报, 2005, 25(20): 157-161.
[7] Chen Yiguang, Pan Wei, Shen Yonghuan, et al. Magnetic field analysis of interior composite-rotor controllable-flux permanent magnet synchronous machine[J]. Transactions of Tianjin University, 2006, 12(5): 330-334.
[8] 陈益广, 王颖, 沈勇环. 内置混合式转子可控磁通永磁同步电机——记忆电机[J]. 微电机, 2005, 38(1): 12-15.
[9] Chen Yiguang, Pan Wei, Shen Yonghuan, et al. Interior composite-rotor controllable-flux PMSM- memory motor[C]. The Eighth International Electrical Machines and Systems Conference, Nanjing, China, 2005, 1: 446-449.
[10] Chen S, Binns K J. Finite element analysis of the magnetic field in rare-earth permanent magnet systems with consideration of temperature[J]. IEEE Transactions on Magnetics, 1992, 28(2): 1303-1306.
[11] 唐任远, 等. 现代永磁电机理论与设计[M]. 北京:机械工业出版社, 2001.
[12] Gu Q S. Field computation of permanent magnets with knee points[J]. IEEE Proceedings, 1989, 136(6): 275-279.