Optimum Design of Distributed Small Section of MCR Based on ANSYS
Yin Zhongdong1, Liu Haipeng1, 2, Wang Shuyao1, Xu Yonghai1, Wan Youwei3
1. State Key Laboratory of Alternate Electrical Power System with Renewable Energy SourcesNorth China Electric Power University Beijing 102206 China; 2. Kunming University of Science and Technology Kunming 650500 China; 3. Anhui Power Transmission and Construction Co. Ltd. Hefei 230022 China
Abstract:Magnetic valve controllable reactor(MCR) has been applied more and more widely. Therefore, improving the various performance indicators of MCR itself becomes the focus of current research. This paper put forward that the single magnetic valve in MCR’s core can be divided into several tandem magnetic valve. This new structure can reduce the edge effect, thereby reducing the MCR’s coil inductance value. Under the same working voltage and control voltage, MCR can output more perceptual reactive current, the overall performance of MCR would be improved. Through theoretical analysis and ANSYS simulation, the optimal effective number of magnetic valve segments and the optimal length values of the iron core between two section of magnetic valve is obtained. The specific experiments demonstrate the validity of the theoretical analysis very well. Under the same working voltage and control voltage, when the magnetic valve section is divided into two sections, the current in the coil than the current in the coil of single magnetic valve increased by 7.4%.
尹忠东, 刘海鹏, 王书瑶, 徐永海, 万有维. 基于ANSYS的MCR分布式小截面优化设计[J]. 电工技术学报, 2015, 30(10): 204-211.
Yin Zhongdong, Liu Haipeng, Wang Shuyao, Xu Yonghai, Wan Youwei. Optimum Design of Distributed Small Section of MCR Based on ANSYS. Transactions of China Electrotechnical Society, 2015, 30(10): 204-211.
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2015, Vol. 30 
