考虑磁致伸缩效应的永磁同步电机磁-机械耦合模型

微特电机 ›› 2020, Vol. 48 ›› Issue (6): 5-8.

考虑磁致伸缩效应的永磁同步电机磁-机械耦合模型

夏林, 于慎波, 窦汝桐, 夏鹏澎

沈阳工业大学机械工程学院,沈阳 110870

收稿日期:2019-12-16 出版日期:2020-06-28 发布日期:2020-06-22
作者简介:夏林(1995—),男,硕士研究生,研究方向为磁致伸缩效应对永磁同步电机振动噪声的影响。

Magnet-Mechanical Coupling Model of PMSM Considering Magnetostrictive Effect

XIA Lin, YU Shen-bo, DOU Ru-tong, XIA Peng-peng

College of Mechanical Engineering, Shenyang University of Technology,Shenyang 110870,China

Received:2019-12-16 Online:2020-06-28 Published:2020-06-22

摘要/Abstract

摘要： 在永磁同步电机振动噪声的计算过程中,需考虑磁致伸缩效应的影响。建立了考虑磁致伸缩效应的定子铁心磁-机耦合模型,解析计算了电磁力密度及磁致伸缩力密度。数值计算了定子振动位移、振动速度和声压分布。所得结果与定子铁心在电磁力单独作用下的振动噪声响应进行了对比。在考虑磁致伸缩效应时,定子齿径向力密度幅值比电磁力单独作用时增加了13.1%,定子铁心的变形量比电磁力单独作用时变形量增加了13.4%,声压级也明显增加。对比表明,磁致伸缩效应对于电机振动噪声有重要贡献。在低噪声永磁同步电机的研发设计阶段,不能忽略磁致伸缩效应的影响。

关键词: 永磁同步电机, 磁致伸缩效应, 磁-机械耦合, 有限元分析, 振动噪声

Abstract: The effect of magnetostriction must be considered in the calculation of vibration and noise of PMSM. The magnetomechanical coupling model of stator core considering magnetostrictive effect was established, and the electromagnetic force density and magnetostrictive force density were calculated analytically. The stator vibration displacement, vibration velocity and sound pressure distribution were calculated. The results were compared with the vibration and noise response of stator core under the electromagnetic force alone. When considering the magnetostriction effect, the radial force density amplitude of stator teeth increased by 13.1% compared with that under the electromagnetic force alone, the deformation of stator core increased by 13.4% compared with that under the electromagnetic force alone, and the sound pressure level also increased significantly. It shows that magnetostrictive effect has an important contribution to the vibration and noise of motor. Therefore, the effect of magnetostriction cannot be ignored in the research and design stage of low noise permanent magnet synchronous motor.

Key words: permanent magnet synchronous motor (PMSM), magnetostrictive effect, magnetic-mechanical coupling, finite element analysis, vibration and noise

中图分类号:

TM351

夏林, 于慎波, 窦汝桐, 夏鹏澎. 考虑磁致伸缩效应的永磁同步电机磁-机械耦合模型[J]. 微特电机, 2020, 48(6): 5-8.

XIA Lin, YU Shen-bo, DOU Ru-tong, XIA Peng-peng. Magnet-Mechanical Coupling Model of PMSM Considering Magnetostrictive Effect[J]. Small & Special Electrical Machines, 2020, 48(6): 5-8.

参考文献

[1] 祝丽花,杨庆新,闫格荣,等.考虑磁致伸缩效应电力变压器振动噪声的研究[J].电机技术学报,2013,28(4):1-7.
[2] 李广.变频电机电磁噪声分析及改进[J].电机与控制应用,2009,36(4):55－57.
[3] OSAMA M,CALVET T,MCCONNELL R. A model for magnetostriction in coupled nonlinear finite element magneto-elastic problems in electrical machines[C]//IEEE International Electric Machines and Drive Conference. Seattle:IEEE,1999:728-735.
[4] BELAHCEN A. Vibration of rotating electrical machines due to magnetomechanical coupling and magnetostriction[J]. IEEE Transactions on Magnetics,2006,42(4):971-974.
[5] MOHAMMED O A, LIU S, ABED N. Study of the inverse magnetostriction effect on machine deformation[C]//2004 Proceedings of SoutheastCon.IEEE, 2004: 433-436.
[6] MOHAMMED O A, CALVERT T, PETERSEN L, et al. Transient modeling of coupled magnetoelastic problems in electric machines[C]//Power Engineering Society Summer Meeting, IEEE, 2002: 281-287.
[7] SASAKI T, IMAMURA M, SUGIYAMA Y. Magnetization processes and magnetostriction in powermagnetic amorphous alloy sheets[J]. IEEE Translation Journal on Magnetics in Japan,1985, 1(2): 226-227.
[8] 张艳丽,孙小光,谢德馨,等.无取向电工钢片磁致伸缩特性测量与模拟[J].电工技术学报,2013,28(11):176-181.
[9] 韩雪岩,张哲,吴胜男,等.磁致伸缩对变频器供电永磁电机振动噪声影响[J].电机与控制学报,2015,19(4):1-6.
[10] 韩雪岩,张哲,吴胜男,等.考虑磁致伸缩效应永磁电机的振动噪声研究[J].电工电能新技术,2015,34(1):28－34.
[11] 吴胜男. 非晶合金永磁电机电磁振动噪声研究 [D]. 沈阳:沈阳工业大学, 2011.
[12] BELAHCEN A, FONTEYN K, HANNUKAINEN A,et al.On numerical modeling of coupled magnetoelastic problem[C]//Proceedings of 21st Nordic Seminar on Computational Mechanics. Trondheim, Norway, 2008:203-206.
[13] 刘现伟,耿跃华.不同磁致伸缩方程下永磁电机应力、应变的研究[J].微特电机,2017,45(6):25-28.
[14] 杨浩东. 永磁同步电机电磁振动分析[D]. 杭州:浙江大学, 2011.

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