Influence of the Air-gap Length and Semimagnetic Wedges on the Performance of a High-Speed Synchronous Reluctance Motor with an Axially Laminated Anisotropic Rotor

2020 XI International Conference on Electrical Power Drive Systems (ICEPDS) Pub Date : 2020-10-04 DOI:10.1109/ICEPDS47235.2020.9249316

Valerii Aramenko, I. Petrov, J. Nerg, J. Pyrhönen

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Abstract

The impact of the air-gap length and usage of semimagnetic wedges on the performance of a synchronous reluctance motor (SynRM) with an axially laminated anisotropic (ALA) rotor aimed at high-speed applications was studied. The studied ALA rotor is intended to be manufactured by heat treatment of a stack of special magnetic and nonmagnetic materials. A 12 kW, 24000 rpm motor is considered in the study. An increase in the air-gap length can significantly reduce the rotor eddy current losses and stator iron losses. However, because of a lower magnetizing inductance with a larger air gap, the supply current is higher resulting in higher stator winding Joule losses. Along with the air-gap length analysis, the semimagnetic wedges were considered as a way of mitigation of high-order harmonics of the air-gap flux density. Wedges with a high relative permeability allowed to improve the efficiency of the machine. The case with realistic semimagnetic wedges was studied (having standard relative permeability values). Both air-gap length adjustment and semimagnetic wedges can be used to improve the efficiency of an ALASynRM.

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气隙长度和半磁楔对轴向层压各向异性转子高速同步磁阻电机性能的影响

研究了气隙长度和半磁楔的使用对高速轴向层压各向异性转子同步磁阻电动机性能的影响。所研究的ALA转子是打算通过热处理一堆特殊的磁性和非磁性材料来制造的。研究中考虑了一台12千瓦，24000转的电机。增大气隙长度可以显著降低转子涡流损耗和定子铁损耗。然而，由于较低的磁化电感和较大的气隙，供电电流较高，导致较高的定子绕组焦耳损耗。在分析气隙长度的同时，提出了半磁楔作为一种消除气隙磁通密度高次谐波的方法。具有高相对渗透率的楔形可以提高机器的效率。研究了具有实际半磁楔的情况(具有标准的相对渗透率)。气隙长度调节和半磁楔都可以提高ALASynRM的效率。

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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2020 XI International Conference on Electrical Power Drive Systems (ICEPDS)

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