Experimental Verification of Passive Axial Electrodynamic Suspension in a Bearingless Motor

IF 7.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Open Journal of Industry Applications Pub Date : 2023-01-18 DOI:10.1109/OJIA.2023.3236984
GUILHERME CAVALCANTE RUBIO;VISHNU C. HOTHUR KOMAL;YUSUKE FUJII;AKIRA CHIBA
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Abstract

This article investigates a bearingless motor with passive electrodynamic axial suspension. The axial suspension force is generated by a specific coil configuration called a figure-eight coil. Radial directions and tilting angles are stabilized by passive permanent magnet bearings. Since axial electrodynamic force increases with rotational speed, it must overcome a certain minimum threshold speed to compensate for the rotor weight and the unstable axial force caused by the permanent magnet bearing. Theoretical equations are derived for the braking torque caused by the suspension current and for the steady-state axial equilibrium position at constant rotational speed. A method based on the braking torque equation is proposed for correcting the mismatch between the magnetic center of the bearingless motor and the middle point of the axial clearance. This method sets the middle point between upper and lower touchdown positions in the same place where the motor current is minimum during passive axial suspension. Axial suspension is confirmed in the experiment with a noncontact laser sensor.
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无轴承电机被动轴向电动悬架的实验验证
本文研究了一种采用被动电动轴向悬挂的无轴承电机。轴向悬挂力是由一种称为八字形线圈的特定线圈配置产生的。径向和倾斜角由无源永磁轴承稳定。由于轴向电动力随着转速的增加而增加,因此必须克服一定的最小阈值速度来补偿转子重量和永磁轴承引起的不稳定轴向力。推导了悬架电流引起的制动力矩和恒定转速下稳态轴向平衡位置的理论方程。提出了一种基于制动力矩方程的无轴承电机磁心与轴向间隙中点不匹配的校正方法。该方法将上下触地位置之间的中点设置在被动轴向悬架期间电机电流最小的相同位置。在非接触式激光传感器的实验中确认了轴向悬挂。
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