磁轴承复合位移传感设计与实验研究

doi:10.19595/j.cnki.1000-6753.tces.201050

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摘要针对传统磁轴承位移传感器结构复杂、适装性差、存在检测位置与执行器错位,而位移自传感方法鲁棒性、实用性差等问题,该文提出一种基于探测线圈的磁轴承位移检测方法,通过在磁轴承磁极上布置探测线圈可实现定转子相对位移测量。首先,建立等效电路模型,并通过Simulink仿真,证明模型正确性;其次,提出差动检测方案,并通过半桥检测电路将相对位移变化转换为电桥输出电压变化,提高了位移检测灵敏度与线性度;最后,在搭建的试验平台上对该传感器进行静态性能测试,当定转子相对位移在±0.3mm范围内变化时,位移检测灵敏度为1.2mV/μm,位移检测分辨率约为7μm,验证了基于探测线圈磁轴承定转子相对位移检测的可行性。该方法结构简单、鲁棒性好,为实现紧凑可靠的磁轴承位移测量奠定了基础。

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关键词 ：磁轴承, 位移测量, 传感器, 探测线圈

Abstract：In order to solve the problems of traditional magnetic bearing displacement sensor with complex structure, poor adaptability, misplacement between detection position and actuator, and poor robustness and practicability of self-sensing method, this paper presents a novel approach for radial displacement detection in magnetic bearing system based on the detection coil. By arranging detection coils around teeth of a magnetic bearing, relative displacement along radial direction between stator and rotor can be achieved. Theory model of the proposed method is built and verified through Simulink simulation. A differential detection scheme is present to improve sensitivity and linearity, and displacement is achieved by detecting the output voltage of the half-bridge detection circuit. Static performance of the proposed method is tested on a platform. And, when the displacement is in the range of -0.3mm to 0.3mm, sensitivity and resolution are 1.2mV/μm and 7μm, respectively, showing the feasibility of displacement detection of the proposed method. The method is simple and robust, and lays a foundation for the realization of compact and reliable magnetic bearing displacement detection.

Key words： Magnetic bearing displacement measurement sensor detection coil

收稿日期: 2020-08-19

PACS:

TM722.7

基金资助:国家自然科学基金资助项目（51707201, 51690181, 51825703）

通讯作者: 苏振中男,1989年生,副研究员,硕士生导师, 研究方向为磁悬浮技术、电力集成技术。E-mail：suayst@163.com

作者简介: 李志男,1998年生,硕士研究生,研究方向为磁轴承技术。E-mail：673551353@qq.com

引用本文:

李志, 苏振中, 胡靖华, 李文印. 磁轴承复合位移传感设计与实验研究[J]. 电工技术学报, 2021, 36(7): 1425-1433. Li Zhi, Su Zhenzhong, Hu Jinghua, Li Wenyin. Design and Experimental Research of Magnetic Bearing Compound Displacement Sensor. Transactions of China Electrotechnical Society, 2021, 36(7): 1425-1433.

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