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| A Coupling Compensation Strategy for Slip Frequency and Stator Resistance of Induction Motor Considering the Stability near Zero Speed |
| Zhong Zhihong, Fang Xiaochun, Wang Xiaofan, Yang Zhongping, Lin Fei |
| College of Electrical Engineering Beijing Jiaotong University Beijing 100044 China |
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Abstract In indirect vector control, the compensation of slip frequency and stator resistance is very important for high precision control. In the existing researches, the stability of compensation of slip frequency and stator resistance at low speed area is rarely discussed, and the research of coupling relationship between them is not deep enough. In this paper, the coupling relationship between the slip frequency and the stator resistance on the flux linkage is analyzed in depth, and the decoupling conditions of the slip frequency and the stator resistance and the convergence conditions are given. In addition, a new coupling compensation strategy of slip frequency and stator resistance is designed by using the second stability theorem of lyapunov. Based on the 5.5kW motor towing platform, this paper carried out experimental verification on the compensation method proposed in this paper, and proved the consistency of this method and theoretical analysis.
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Received: 28 June 2018
Published: 05 March 2020
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2020, Vol. 35 
