非磁饱和偏置下自传感主动电磁轴承的转子位移协同估计

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摘要基于电磁轴承差动控制模式,首次提出一种转子位移的协同估计策略。在非饱和偏置磁通的条件下,相对磁极必有一个处于非饱和状态。通过对控制电流的极性判断来动态追踪没有饱和的磁极,始终采用未饱和磁极端所估计得到的转子位移作为系统反馈。论述了非饱和偏置磁通的基本原理,并给出了非饱和最大偏置电流的实验测量方法。在四自由度电磁轴承系统平台上,对提出的相对磁极协同位移估计策略进行了静态悬浮饱和实验以及动态悬浮旋转实验。实验结果证明,使用该策略的自传感电磁轴承系统具有更强的抗磁饱和能力,同时也间接地提高了电磁轴承系统抵抗外力扰动的能力,增强了系统的稳定性。

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	唐明
	祝长生
	于洁

关键词 ：自传感, 主动电磁轴承, 非饱和偏置, 协同位移估计

Abstract：A strategy of cooperative position estimation is proposed based on the differential control mode of active magnetic bearings(AMBs). Given unsaturated magnetic bias, one of the opposing pole pairs must be unsaturated. The unsaturated poles could be tracked by the control current polarity. The position estimation from the unsaturated poles is always chosen as system feedback. Basic theory of unsaturated magnetic bias is discussed and the experimental method of measuring the maximum value of unsaturated current bias is presented. This cooperative position estimation is tested in the 4-DOF AMBs system. Static and dynamic suspension experiments are held to prove the feasibility of this method. Experimental results show that, the self-sensing AMBs system using this strategy exhibits stronger rejection to magnetic saturation. And this strategy proves the performance of force disturbance and increases system stability.

Key words： Self-sensing active magnetic bearings unsaturated magnetic bias cooperative position estimation

收稿日期: 2013-02-06 出版日期: 2014-11-05

PACS:

TM315

基金资助:国家自然科学基金(10772160) 和浙江省科技厅公益技术应用研究 (2011C21021) 资助项目

作者简介: 唐明男,1986年生,博士研究生,研究方向为电磁轴承的无位置传感器运行。祝长生男,1963年生,教授,博士生导师,研究方向为主动电磁轴承转子动力学、高速电机、飞轮储能等。

引用本文:

唐明, 祝长生, 于洁. 非磁饱和偏置下自传感主动电磁轴承的转子位移协同估计[J]. 电工技术学报, 2014, 29(5): 205-212. Tang Ming, Zhu Changsheng, Yu Jie. Cooperative Rotor Position Estimation of Active Magnetic Bearings with Unsaturated Magnetic Bias. Transactions of China Electrotechnical Society, 2014, 29(5): 205-212.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2014/V29/I5/205

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