Analysis of a Novel Mechanically Adjusted Variable Flux Permanent Magnet Homopolar Inductor Machine with Rotating Magnetic Poles for Flywheel Energy Storage System

Qing Li;Mingcheng Lyu;Jiangtao Yang;Shoudao Huang
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Abstract

Permanent magnet homopolar inductor machine (PMHIM) has attracted much attention in the field of flywheel energy storage system (FESS) due to its merits of simple structure, brushless excitation, and rotor flywheel integration. However, the air-gap flux generated by the PM cannot be adjusted, which would cause large electromagnetic losses in the standby operation state of FESS. To solve this problem, a novel mechanically adjusted variable flux permanent magnet homopolar inductor machine with rotating magnetic poles (RMP-PMHIM) is proposed in this paper. The permanent magnet poles are rotated by an auxiliary rotating device and the purpose of changing the air-gap flux is achieved. First, the structure and operation principle of the proposed RMP-PMHIM are explained. Second, the flux weakening principle of the RMP-PMHIM is analyzed and the equivalent magnetic circuit models under different flux weakening states are built. Third, the parameters of the PM and its fixed structure are optimized to obtain the good electromagnetic performance. Fourth, the electromagnetic performance, including the air-gap flux density, back-EMF, flux weakening ability, loss, etc. of the proposed RMP-PMHIM are investigated and compared. Compared with the non-rotating state of the PM of RPM-PMHIM, the air-gap flux density amplitude can be weakened by 99.95% when the PM rotation angle is 90 degrees, and the no-load core loss can be suppressed by 99.98%, which shows that the proposed RPM-PMHIM is a good candidate for the application of FESS.
一种用于飞轮储能系统的新型机械可调变磁通永磁单极感应电机的分析
永磁单极感应电机(PMHIM)以其结构简单、无刷励磁、转子-飞轮一体化等优点,在飞轮储能系统(FESS)领域备受关注。然而,PM产生的气隙通量无法调节,这将在FESS的备用运行状态下造成较大的电磁损耗。为了解决这一问题,本文提出了一种新型的旋转磁极机械调节变磁通永磁单极电感器(RMP-PMHIM)。永磁极通过辅助旋转装置旋转,达到改变气隙磁通量的目的。首先,介绍了所提出的RMP-PMHIM的结构和工作原理。其次,分析了RMP-PMHIM的弱磁原理,建立了不同弱磁状态下的等效磁路模型。第三,对PM及其固定结构的参数进行了优化,以获得良好的电磁性能。第四,研究并比较了所提出的RMP-PMHIM的电磁性能,包括气隙磁通密度、反电势、磁通削弱能力、损耗等。与PM的非旋转状态相比,当PM旋转角度为90度时,气隙磁通密度振幅可以减弱99.95%,空载铁心损耗可以抑制99.98%,这表明所提出的RPM-PMHIM是应用FESS的良好候选者。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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