Sensorless control of a synchronous reluctance motor by finite elements model results

2017 IEEE International Symposium on Sensorless Control for Electrical Drives (SLED) Pub Date : 2017-09-01 DOI:10.1109/SLED.2017.8078424

M. Tursini, M. Villani, G. Fabri, Simone Paolini, A. Credo, A. Fioravanti

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引用次数: 12

Abstract

This paper concerns the development of a sensorless controller for synchronous reluctance motors based on finite elements model results. A hybrid solution is used, which includes an adaptive observer for not-zero speed operation and signal injection for standstill. The observer detects the flux linkages components in the two-phase stationary reference frame by the voltage model integration and closed loop correction feedback. This last is provided by a non-linear model of the rotor-fixed frame flux components achieved by finite elements computations. The rotor speed and position are identified by a phase-locked-loop algorithm. To improve the observer performance, the mechanical model is considered, which accounts for the finite elements mapping of the motor torque. The study is applied to a prototype of synchronous reluctance motor with flux barriers rotor, designed to have the same stator core of a commercial three-phase 3kW induction motor. Both realistic simulations (accounting for the non-linear machine behavior) and experimental test are presented, showing the performance of the proposed solution.

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同步磁阻电机无传感器控制的有限元模型研究结果

本文讨论了基于有限元模型结果的同步磁阻电动机无传感器控制器的研制。采用了一种混合解决方案，其中包括非零速度运行的自适应观测器和静止状态的信号注入。观测器通过电压模型积分和闭环校正反馈检测两相静止参照系中的磁链分量。最后通过有限元计算得到转子固定架磁链分量的非线性模型。采用锁相环算法识别转子的转速和位置。为了提高观测器的性能，考虑了考虑电机转矩有限元映射的力学模型。该研究应用于具有磁通屏障转子的同步磁阻电机原型，该原型设计具有与商用三相3kW感应电机相同的定子铁芯。给出了实际仿真(考虑到非线性机器行为)和实验测试，证明了所提出的解决方案的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 IEEE International Symposium on Sensorless Control for Electrical Drives (SLED)

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