Vibration Performance of a Three-Phase Asynchronous Motor With Air-Gap Eccentricity

2019 Prognostics and System Health Management Conference (PHM-Qingdao) Pub Date : 2019-10-01 DOI:10.1109/phm-qingdao46334.2019.8943067

Shen Chen, Xiong Xin, Zheng Shaoshuai, Xu Gang-hui

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Abstract

In this paper, the vibration performances of a three-phase asynchronous motor with air-gap eccentricity were studied The governing equations of the eccentric rotor-bearing system was established by considering the nonlinear bearing contact forces and the unbalanced magnetic pull (UMP) acting on the rotor. The UMP was calculated at the axial position of the supporting bearings, by integrating the total air gap distribution along the axial and circumferential direction. The air gap distribution can be deduced from the stator, rotor MMF harmonics and their related harmonics. By substituting the UMP into the governing equations, numerical responses of the rotor-bearing system under air-gap eccentricity can be simulated. Results show that the shaft orbits at both two ends of the shaft reside on their eccentric positions, i.e., the orbits of two shaft ends with symmetric angular eccentricity have the opposite phase direction. Besides, in the power spectrum of the simulated acceleration, the second harmonic component turns out to be notable compared with the fundamental frequency

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气隙偏心三相异步电动机的振动特性

研究了具有气隙偏心的三相异步电动机的振动特性，考虑了转子的非线性接触力和转子的不平衡磁拉力，建立了偏心转子-轴承系统的控制方程。通过积分沿轴向和周向的总气隙分布，在支撑轴承的轴向位置计算UMP。气隙分布可以由定子、转子的毫米波谐波及其相关谐波推导出来。通过将UMP代入控制方程，可以模拟气隙偏心作用下转子-轴承系统的数值响应。结果表明:轴两端的轴轨均处于偏心位置，即角偏心率对称的两端轴轨相位方向相反。此外，在模拟加速度的功率谱中，与基频相比，二次谐波分量显著

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2019 Prognostics and System Health Management Conference (PHM-Qingdao)

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