磁悬浮轴承转子热弯曲振动特性研究

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摘要为了研究磁悬浮轴承-转子系统中由于轴颈铁损集中而出现的热弯曲振动现象，本文根据磁悬浮轴承的工作原理，总结出热弯曲振动的变化规律，并利用Bertotti铁损分离模型得到转子轴颈处的铁损耗，以铁损耗作为热源，结合磁悬浮轴承的支承特性，建立转子热-结构耦合振动方程，求解得到热弯曲振动响应。同时，为了研究转子工作时热弯曲振动的变化过程，使用一种迭代计算的方法，不断更新计算条件，反复迭代计算，直到振动收敛或发散，由此判断热弯曲振动对系统的影响。计算结果表明：转子旋转频率对整体温升影响显著，轴颈温差主要取决于振幅，温度最高点位置及热弯曲方向与振动位移方向有关，并决定着振动的变化。

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	金超武
	董岳
	苏浩
	徐园平
	周瑾
	闫旭

关键词 ：磁悬浮轴承, 热弯曲振动, 电磁损耗

Abstract：The thermal-bow vibration induced by the concentration of the iron loss in active magnetic bearing (AMB) supported rotor was studied. The changing principle of the thermal-bow vibration was studied according to the working principle of the AMB. The iron loss obtained by Bertotii’s separation theory was set as the heat source, and combing the support characteristics of AMBs, the thermal-structural vibration equation was established to obtain the thermal-bow vibration. In addition, an iterative calculation method was employed to upgrade the calculation conditions and obtain the vibration response until the vibration converges or diverges. The calculation results show that the overall temperature of the rotor is strongly related to the rotation frequency. The temperature difference at journal circumference is mainly decided by the vibration amplitude. The location of the hot spot and the thermal bow direction are related to the vibration direction, and they determine the changing of the vibration.

Key words： active magnetic bearing thermal bow vibration electromagnetic loss

收稿日期: 2020-10-14 出版日期: 2022-02-28

引用本文:

金超武，董岳，苏浩，徐园平，周瑾，闫旭. 磁悬浮轴承转子热弯曲振动特性研究[J]. 振动与冲击, 2022, 41(4): 36-47.
JIN Chaowu，DONG Yue，SU Hao，XU Yuanping，ZHOU Jin，YAN Xu. Characteristics of thermal-bow vibration in an active magnetic bearing supported rotor. JOURNAL OF VIBRATION AND SHOCK, 2022, 41(4): 36-47.

链接本文:

http://jvs.sjtu.edu.cn/CN/ 或 http://jvs.sjtu.edu.cn/CN/Y2022/V41/I4/36

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