Performance Comparison of Consequent-Pole and Homopolar Consequent-Pole Bearingless Motors for Low Speed Applications

2021 IEEE Energy Conversion Congress and Exposition (ECCE) Pub Date : 2021-10-10 DOI:10.1109/ECCE47101.2021.9594970

H. Sugimoto, Miyabi Terashima

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Abstract

This paper presents performance comparisons of a consequent-pole (CP) and a homopolar consequent-pole (HCP) bearingless motors. Radial directions are actively positioned, and axial and tilting directions are passively stabilized with a disk-shaped rotor. In the CP and HCP bearingless machines, the radial suspension force is generated by a two-pole suspension winding. However, the radial suspension force characteristics are considerably different in the two machines. The radial suspension force of the HCP is generated when a two-pole suspension flux is superimposed on a homopolar flux by thrust permanent magnets. In contrast, the CP bearingless motor requires $p \pm 2$-pole suspension fluxes modulated by the salient-pole rotor core to generate the radial suspension force with a p-pole rotor permanent magnet flux. As a result, the force error angle of the HCP bearingless motor is significantly low compared with the CP bearingless motor. A prototype machine of the HCP bearingless motor is fabricated and tested. In the experiment, it is demonstrated that stable magnetic suspension and rotation are achieved at 1000 r/min.

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低速应用中结果极与同极结果极无轴承电机的性能比较

本文介绍了结果极(CP)和同极结果极(HCP)无轴承电机的性能比较。径向主动定位，轴向和倾斜方向被动稳定与圆盘形转子。在CP和HCP无轴承机床中，径向悬架力由两极悬架绕组产生。然而，径向悬架力特性在两种机器中有很大不同。通过推力永磁体将两极悬浮磁通叠加在同极磁通上，产生HCP的径向悬浮力。CP无轴承电机需要p极转子磁芯调制p极悬浮磁通，以p极转子永磁通产生径向悬浮力。因此，与CP无轴承电机相比，HCP无轴承电机的力误差角明显较低。制作了HCP无轴承电机样机并进行了试验。实验证明，在1000 r/min的转速下，可以实现稳定的悬浮和旋转。

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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2021 IEEE Energy Conversion Congress and Exposition (ECCE)

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