航空电动反推力装置用永磁同步电机热分析

微特电机 ›› 2020, Vol. 48 ›› Issue (9): 13-17.

航空电动反推力装置用永磁同步电机热分析

孙桂林¹, 赵勇², 蒋佳楠³, 袁瑞林¹, 赵群弼⁴, 宋受俊¹, 刘卫国¹

1.西北工业大学自动化学院,西安 710072;
2.中航机载系统有限公司,北京 100621;
3.诺丁汉大学工程学院,诺丁汉 NG7 2RD;
4.陕西航空电气有限责任公司,西安 710000

收稿日期:2020-06-08 出版日期:2020-09-28 发布日期:2020-09-21
基金资助:
陕西省重点研发计划项目(2018GY-185)航空电动反推力装置用永磁同步电机热分析

Thermal Analysis of Permanent Magnet Synchronous Motor for Aero Electric Thrust Reverser

SUN Gui-lin¹, ZHAO Yong², JIANG Jia-nan³, YUAN Rui-lin¹, ZHAO Qun-bi⁴, SONG Shou-jun¹, LIU Wei-guo¹

1. School of Automation, Northwestern Polytechnical University, Xi’an 710072, China;
2. China Avionics System Co.,Ltd.,Beijing 100621, China;
3. Faculty of Engineering, University of Nottingham, Nottingham NG7 2RD, UK;
4. AVIC Shaanxi Aero Electric Co.,Ltd., Xi’an 710000, China

Received:2020-06-08 Online:2020-09-28 Published:2020-09-21

摘要/Abstract

摘要： 以航空发动机电动反推力装置为应用背景,针对高功率密度与有限散热条件,对所设计的双通道表贴式以及单通道内嵌式永磁同步电机进行了详细的热分析。给出了两款电机的电磁设计方案,分析了电机各类损耗计算方法,得到了稳定工作和起动状态下的电机总损耗。考虑温升余量,以起动状态作为最恶劣工况,将损耗计算结果换算成电机各部分损耗的体密度,利用ANSYS Fluent的有限元分析得到各部分的温度分布。建立了两款电机的热网络模型,通过路算方式得到了各部分的温度,并与有限元分析结果进行了对比。

关键词: 电动反推力装置, 永磁同步电机, 热分析, 有限元分析, 热网络模型

Abstract: In the background of aero-engine electric reverse thrust equipment, considering the high power density and limited cooling conditions, the thermal analysis of the designed dual-channel surface-mounted and single-channel interior permanent magnet synchronous motor was carried out in detail. The electromagnetic design schemes of the two types of motors were given, the calculation methods for several kinds of losses were analyzed, and the total losses of the motor under stable operation and starting state were obtained. Considering the temperature rise margin, the starting state was taken as the worst working condition. The loss calculation results were converted into the bulk loss density of each part, and finite element analysis was used to get the temperature distribution with ANSYS Fluent. The thermal network models of the two types of motor were established. The temperature of each part is obtained by the way of circuit calculation, and compared with the results from the finite element analysis.

Key words: electric thrust reverser, permanent magnet synchronous motor, thermal analysis, finite element analysis, thermal network model

中图分类号:

孙桂林, 赵勇, 蒋佳楠, 袁瑞林, 赵群弼, 宋受俊, 刘卫国. 航空电动反推力装置用永磁同步电机热分析[J]. 微特电机, 2020, 48(9): 13-17.

SUN Gui-lin, ZHAO Yong, JIANG Jia-nan, YUAN Rui-lin, ZHAO Qun-bi, SONG Shou-jun, LIU Wei-guo. Thermal Analysis of Permanent Magnet Synchronous Motor for Aero Electric Thrust Reverser[J]. Small & Special Electrical Machines, 2020, 48(9): 13-17.

参考文献

[1] TAN D. Transportation electrification: challenges and opportunities [J]. IEEE Power Electronics Magazine, 2016,3(2): 50-52.
[2] SHAMSI P, MCDONOUGH M, FAHIMI B. Wide-bandgap semiconductor technology: its impact on the electrification of the transportation industry [J]. IEEE Electrification Magazine, 2013, 1(2): 59-63.
[3] YOUSSEF M Z, WORONOWICZ K, ADITYA K, et al. Design and development of an efficient multilevel DC/AC traction inverter for railway transportation electrification [J]. IEEE Transactions on Power Electronics, 31(4): 3036-3042.
[4] SARLIOGLU B, MORRIS C T. More electric aircraft: review, challenges, and opportunities for commercial transport aircraft [J]. IEEE Transactions on Transportation Electrification, 2015, 1(1): 54-64.
[5] ZHANG Z, GENG W, LIU Y, et al. Feasibility of a new ironless-stator axial flux permanent magnet machine for aircraft electric propulsion application [J]. CES Transactions on Electrical Machines and Systems, 2019, 3(1): 30-38.
[6] GAO F, ZHENG X, BOZHKO S, et al. Modal analysis of a PMSG-based DC electrical power system in the more electric aircraft using eigenvalues sensitivity [J]. IEEE Transactions on Transportation Electrification, 2015, 1(1): 65-76.
[7] CAO W, MECROW B C, ATKINSON G J, et al. Overview of electric motor technologies used for more electric aircraft (MEA) [J]. IEEE Transactions on Industrial Electronics, 2012, 59(9): 3523-3531.
[8] LUKIC M, HEBALA A, GIANGRANDE P, et al. State of the art of electric taxiing systems [C]// IEEE International Conference on Electrical Systems for Aircraft, Railway, Ship Propulsion and Road Vehicles & International Transportation Electrification Conference (ESARS-ITEC), 2018:1-6.
[9] LIU C, WANG Z, WANG J, et al. 3D numerical simulation of clamshell thrust reverser with flap Deployed while landing [C]// 3rd International Symposium on Systems and Control in Aeronautics and Astronautics,2010:153-157.
[10] BENLAMINE R, HAMITI T, VANGRAEFSCHEPE F. Electromagnetic, structural and thermal analyses of high-speed PM machines for aircraft application [C]// XIII International Conference on Electrical Machines (ICEM), 2018:212-217.
[11] MADONNA V, GIANGRANDE P, GERADA C, et al. Thermal analysis of fault-tolerant electrical machines for more electric aircraft applications [J]. The Journal of Engineering, 2018(13): 461-467.
[12] YU G, LI D, CHEN Z, et al. Blended wing body thrust reverser cascade feasibility evaluation through CFD [J]. IEEE Access, 2019(7): 155184-155193.

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