Suspension Characteristic Analysis of Hybrid Single Winding Bearingless Switched Reluctance Motor

被引：0

作者：

Yuan Y. ^{[1
]}

Sun Y. ^{[1
]}

Ding S. ^{[1
]}

Yang F. ^{[1
]}

机构：

[1] School of Electrical and Information Engineering, Jiangsu University, Jiangsu Province, Zhenjiang

来源：

Zhongguo Dianji Gongcheng Xuebao/Proceedings of the Chinese Society of Electrical Engineering | 2023年 / 43卷 / 02期

基金：

中国国家自然科学基金;

关键词：

bearingless switched reluctance motor (BSRM); control strategy; finite element analysis; flywheel battery; single-winding;

D O I：

10.13334/j.0258-8013.pcsee.211886

中图分类号：

学科分类号：

摘要：

Single winding bearingless switched reluctance motor (SWBSRM) with the advantage of high integration can realize two operation modes: full power torque operation and torque/suspension operation. However, it has limited output range of suspension force. A hybrid SWBSRM (HSWBSRM) is proposed by integrating the modular SWBSRM and the DC magnetic bearing. The suspension force density of the supporting system is further increased, and the power consumption of disturbance resistant suspension is reduced by means of wide and narrow tooth design, permanent magnet bias, and other technical means. The structure and operation principle of HSWBSRM are clarified, and the design constraints are revealed. A 3D finite element analysis model is built based on the parameters of the typical experimental prototype, and in-depth analysis is conducted focusing on the biased suspension characteristic, adjustable suspension characteristic, and cooperative suspension characteristic. Based on the analysis of the coupling characteristics of the system, the control strategy is proposed, and the control system is constructed, thereby verifying the feasibility of the prototype operation mechanism. ©2023 Chin.Soc.for Elec.Eng.

引用

页码：789 / 797

页数：8

共 26 条

[1] CORREA G, MUNOZ P, FALAGUERRA T, Performance comparison of conventional ， hybrid ，hydrogen and electric urban buses using well to wheel analysis[J], Energy, 141, pp. 537-549, (2017)
[2] WILBERFORCE T, EL-HASSAN Z, KHATIB F N, Developments of electric cars and fuel cell hydrogen electric cars[J], International Journal of Hydrogen Energy, 42, 40, pp. 25695-25734, (2017)
[3] Jinwu GAO, Meng LI, Yunfeng HU, Challenges and developments of automotive fuel cell hybrid power system and control[J], Science China Information Sciences, 62, 5, (2019)
[4] Kuo J K, Hsieh H K．, Research of flywheel system energy harvesting technology for fuel cell hybrid vehicles[J], Fuel Cells, 13, 6, pp. 1234-1241, (2013)
[5] Long DI, YOON S Y, A platform for analysis and control design：emulation of energy storage flywheels on a rotor-AMB test rig[J], Mechatronics, 33, pp. 146-160, (2016)
[6] ZHANG Weiyu, YANG Hengkun, ZHU Huangqiu, Key technologies and technical bottleneck analysis of flywheel battery systems for electric vehicle[J], Proceedings of the CSEE, 38, 18, pp. 5568-5581, (2018)
[7] RONG Hai, ZHOU Kai, MAO Feilong, Suppression of imbalance vibrations in magnetically suspended spindles based on zero-bias current control[J], Journal of Tsinghua University ： Science & Technology, 59, 8, pp. 683-688, (2019)
[8] ZHENG Shiqiang, CHEN Cheng, LIU Gang, Nutation phase margin tracking compensation control for high-speed magnetically suspended rotor, Journal of Mechanical Engineering, 54, 17, pp. 100-107, (2018)
[9] ZHANG Weiyu, Huangqiu ZHU, Control system design for a five-degree-of-freedom electrospindle supported with AC hybrid magnetic bearings[J], IEEE/ASME Transactions on Mechatronics, 20, 5, pp. 2525-2537, (2015)
[10] YANG Hongjin, XIE Zhenyu, ZHAO Jing, Co- simulation analysis of dynamic characteristics of flywheel battery for vehicle[J], System Simulation Technology, 10, 2, pp. 130-139, (2014)

← 1 2 3 →