Analytical Modeling Method of Electromagnetic Linear Drive Device Combining Magnetic Potential Vector Model and Equivalent Surface Current Model

doi:10.3901/JME.2024.20.261

Abstract

Abstract: A hybrid analytical modeling method for moving coil electromagnetic linear drive device is proposed. The model is used to further improve the electromagnetic field analytical model accuracy of the drive device. The hybrid analytical model combines the magnetic potential model and the equivalent surface current model to research the electromagnetic characteristics of the driving device. Define radial flux density correction coefficient to modify the single magnetic potential vector model. Use electromagnetic field boundary conditions of moving coil electromagnetic linear drive device to establish a more accurate electromagnetic characteristics mathematical model. Finally, obtain the distribution law of magnetic field in the air gap and the electromagnetic force - travel function. The FEM and experimental results show that the hybrid model is more accurate compared with the single magnetic potential model. After modification, the maximum error of thrust solution is reduced from 6.9% to 2.8% and the solution accuracy is improved by 4.1%, which prove the validity of the modified method. The error between the experiment and the analytical results is less than 2.5%, which verifies the correctness and accuracy of the analytical model. This method provides a theoretical basis for the modular design of electromagnetic linear drive device and the sensorless control, and enrich the control method of all-electric integrated drive system.

Key words: electromagnetic linear drive device, hybrid analytical model, magnetic potential vector model, equivalent surface current model

CLC Number:

TM359

LI Bo, JIANG Jinhao, GE Wenqing, WANG Geng, TAN Cao, LU Jiayu. Analytical Modeling Method of Electromagnetic Linear Drive Device Combining Magnetic Potential Vector Model and Equivalent Surface Current Model[J]. Journal of Mechanical Engineering, 2024, 60(20): 261-270.

References

[1] 凌志健，赵文祥，吉敬华. 高推力永磁电磁直线驱动装置及其关键技术综述[J]. 电工技术学报，2020，35(5)：1022-1035. LING Zhijian，ZHAO Wenxiang，JI Jinghua. Overview of high force density permanent magnet linear actuator and its key technology[J]. Transactions of China Electrotechnical Society，2020，35(5)：1022-1035.
[2] 陈前，赵美玲，廖继红，等. 轻量化高效率永磁电机及其控制技术综述[J]. 电气工程学报，2023，18(4)：3-19. CHEN Qian，ZHAO Meiling，LIAO Jihong，et al. Review on lightweight and high efficiency permanent magnet motor and its control techniques[J]. Journal of Electrical Engineering，2023，18(4)：3-19.
[3] 李鑫宇，孙天夫，黄世军，等. 永磁同步电机温度建模与热管理方法综述[J]. 电气工程学报，2023，18(4)：20-34. LI Xinyu，SUN Tianfu，HUANG Shijun，et al. Review and perspectives on thermal management methods for permanent magnet synchronous motors[J]. Journal of Electrical Engineering，2023，18(4)：20-34.
[4] XU Dezhi，YAO Hu，HE Yang，et al. Current loop disturbance suppression for dual three phase permanent magnet synchronous generators based on modified linear active disturbance rejection control[J]. Chinese Journal of Electrical Engineering，2024，10(1)：101-113.
[5] 林程，曹放，梁晟，等. 双电机后驱车辆操纵稳定性分层混杂模型预测控制[J]. 机械工程学报，2019，55(22)：123-130. LIN Cheng，CAO Fang，LIANG Sheng. et al. Yaw stability control of distributed drive electric vehicle based on hierarchical hybrid model predictive control[J]. Journal of Mechanical Engineering，2019，55(22)：123-130.
[6] 张立军，徐杰，孟德建. 基于Preisach模型的永磁同步轮毂电机损耗及温度场建模与分析[J]. 机械工程学报，2019，55(22)：33-40，51. ZHANG Lijun，XU Jie，MENG Dejian. Modeling and analysis of loss and temperature field in permanent magnet synchronous in-wheel motor based on preisach theory[J]. Journal of Mechanical Engineering，2019，55(22)：33-40，51.
[7] 陈吉清，冼浩岚，兰凤崇，等. 开关磁阻电机结构性转矩脉动抑制方法[J]. 机械工程学报，2020，56(20)：106-119. CHEN Jiqing，XIAN Haolan，LAN Fengchong，et al. Structural torque ripple suppression method of switched reluctance motor[J]. Journal of Mechanical Engineering. 2020，56(20)：106-119.
[8] 胡东海，严炎智. 考虑PMSM转子偏心作用的EV动力传动系统非线性扭振特性分析[J]. 机械工程学报，2018，54(22)：128-136. HU Donghai，YAN Yanzhi. Analysis of nonlinear torsional vibration characteristics of EV powertrain considering rotor eccentricity of PMSM[J]. Journal of Mechanical Engineering，2018，54(22)：128-136.
[9] LUO Xuesong，ZHANG Chao，WANG Shaoping，et al. Modeling and analysis of mover gaps in tubular moving-magnet linear oscillating motors[J]. Chinese Journal of Aeronautics，2018，31(5)：927-940.
[10] CHEN X，ZHU Z Q，HOWE D. Modeling and analysis of a tubular oscillating permanent-magnet actuator[J]. IEEE Transactions on Industry Applications，2009，45(6)：1961-1970.
[11] WANG Geng，LYU Zhiqiang，GAO Renjing，et al. Optimization method for a moving‑coil electromagnetic linear actuator using an improved Macaca thibetana behavior-based hierarchical GA-PSO algorithm[J]. Structural and Multidisciplinary Optimization，2022，65(9)：252-269.
[12] Boules N. Prediction of non-load flux density distribution in permanent magnet machines[J]. IEEE Transactions on Industry Applications，1985，IA-21(3)：633-643.
[13] LUO Xuesong，WANG Shaoping，WANG Xingjian，et al. Analytical study of magnetic field considering circumferential mover gaps in tubular linear oscillating motor[C]//201712th IEEE Conference on Industrial Electronics and Applications (ICIEA)，2017：320-325.
[14] HE Ping，JIAO Zongxia，YAN Liang，et al. Analysis of magnet layout in circumferential and axial direction for Halbach PM arrays[C]//Proceedings of 2014 IEEE Chinese Guidance，Navigation and Control Conference. 2014：2013-2018.
[15] Tsai N，Chiang C. Innovative electromagnetic actuator applied for high-frequency reciprocal translation[J]. Electromagnetics，2011，31(1)：45-62.
[16] 周游，石超杰，曲荣海，等. 磁场调制永磁直线电机拓扑研究综述[J]. 中国电机工程学报，2021，41(4)：1469-1484. ZHOU You，SHI Chaojie，QU Ronghai，et al. Overview of flux-modulation linear permanent magnet machines[J]. Proceedings of the CSEE，2021，41(4)：1469-1484.
[17] JI Jinghua，JIANG Weizhi，ZHAO Wenxiang，et al. Investigation of eccentric PM on high-frequency vibration in FSCW PM machine considering force modulation effect[J]. Chinese Journal of Electrical Engineering，2024，10(2)：59-69.
[18] JI Jinghua，LIU Deyou，ZENG Yu，et al. Vibration reduction and torque improvement of integral-slot SPM machines using PM harmonic injection[J]. Chinese Journal of Electrical Engineering，2023，9(4)：41-53.
[19] TAN Cao，LI Bo，LIU Yongteng，et al. Multiphysics methodology for thermal modelling and quantitative analysis of electromagnetic linear actuator[J]. Smart Materials and Structures，2019，28(8)：87001.
[20] 李波. 基于直驱技术的AMT换挡系统设计与性能研究[D]. 南京：南京理工大学，2014. LI Bo. Design and performance research of AMT shift system based on direct-drive technology[D]. Nanjing ：Nanjing University of Science & Technology，2014.
[21] LI Bo，CHANG Siqin，LIN Shusen. Analysis and simulation of gear shift for an AMT based on 2-DOF EMA[C]//IEEE International Conference on Electrical and Control Engineering，Yichang，China，2011：1994-1997.
[22] 谭草，鲁应涛，葛文庆，等. 直驱式永磁直线电机深度模糊滑模-自抗扰控制[J]. 西安交通大学学报，2023，57(1)：1-9. TAN Cao，LU Yingtao，GE Wenqing，et al. Depth fuzzy sliding-mode active disturbance rejection control method of permanent magnet linear motor for direct drive system[J]. Journal of Xi’an Jiaotong Uuniversity，2023，57(1)：1-9.
[23] XU Yunpeng，JI Jinghua，LING Zhijian，et al. Quantitative comparison of modular linear permanent magnet vernier machines with and without partitioned primary[J]. Chinese Journal of Electrical Engineering，2023，9(3)：72-83.
[24] ZHU Xiaoyuan，ZHANG Hui，XI Junqiang，et al. Robust speed synchronization control for clutchless automated manual transmission systems in electric vehicles[J]. Proceedings of the Institution of Mechanical Engineers，Part D：Journal of Automobile Engineering，2015，229(4)：424-436.
[25] 叶杰，黄向东，赵克刚，等. 单摩擦元件纯电动两档变速器换档最优控制[J]. 机械工程学报，2016，52(20)：92-101. YE Jie，HUANG Xiangdong，ZHAO Kegang，et al. Optimal control for gear shift of a pure electric vehicle’s 2-speed transmission with single friction clutch[J]. Journal of Mechanical Engineering，2016，52(20)：92-101.
[26] LI Bo，GE Wenqing，YU Xiao，et al. Innovative design and gearshift control for direct-drive electromagnetic gearshift system equipped with servo synchronizer[J]. Proceedings of the Institution of Mechanical Engineers，Part D：Journal of Automobile Engineering，2019，233(5)：1115-1124.
[27] TAN Cao，REN Haoxin，LI Bo，et al. Design and analysis of a novel cascade control algorithm for braking-by-wire system based on electromagnetic direct-drive valves[J]. Journal of the Franklin Institute，2022，359(16)：8497-8521.