Abstract
In the existing permanent magnet motor drive system, the vibration and noise problems caused by motor and driver are more and more obvious and complex. Among them, the radial electromagnetic force fluctuation problem of permanent magnet synchronous motor (PMSM) stator is the most important cause of vibration and noise. The radial electromagnetic force fluctuation of PMSM stator is the main source of vibration and noise. In order to lay a solid foundation for studying the distribution of vibration and noise, the radial electromagnetic force of 12 slot 14 pole PMSM is calculated by combining Maxwell stress method and Lorentz force method. Based on the Maxwell platform, a solution model is established to analyze the radial electromagnetic force of motor in time and space. The time–space analysis diagram of radial electromagnetic force in no-load section and load section is given; it is helpful to avoid resonance point and realize low-noise design of motor.
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References
Wang X, He X, Gao P (2019) Research on electromagnetic vibration noise reduction method of V-type magnetic steel rotor permanent magnet motor for electric vehicle. Chin J Electr Eng 39(16):4919–4926
Chen Y, Zhu Z, Ying S (1987) Motor noise analysis and control. Zhejiang University Press, Zhejiang
Jianbo S, Qionghua Z, Jin H (2005) Stator vibration mode analysis of switched reluctance motor. Chin J Electr Eng 22:151–155
Lee S, Hong J, Hwang S et al (2009) Optimal design for noise reduction in interior permanent-magnet motor. IEEE Trans Ind Appl 45(6):1954–1960
Jing L, Huang Z, Chen J, Qu R (2020) An asymmetric pole coaxial magnetic gear with unequal Halbach arrays and spoke structure. IEEE Trans Appl Supercond 30(4):520–525
Jing L, Huang Z, Chen J, Qu R (2020) Design, analysis and realization of a hybrid-excited magnetic gear during overload. IEEE Trans Ind Appl Supercond 30(4):1345–1351
Lee S-K, Kang G-H, Hur J (2012) Finite element computation of magnetic vibration sources in 100 kW two fractional-slot interior permanent magnet machines for ship. IEEE Trans Magn 48(2):867–870
Shuguang Z, Lin Fu, Qing S, Yi Ma, Qinwen T (2014) Analysis of the influence of pole slot coordination and winding layers on the vibration of permanent magnet synchronous motors. Vib Shock 33(13):130–134
Islam R, Husain I (2010) Analytical model for predicting noise and vibration in permanent-magnet synchronous motors. IEEE Trans Ind Appl 46(6):1346–2353
Islam MS, Islam R (2014) Tomy sebastian. noise and vibration characteristics of permanent-magnet synchronous motors using electromagnetic and structural analyses. IEEE Trans Ind Appl 50(5):3214–3222
Zhu ZQ, Howe D, Bolte E, Ackermann B (2002) Instantaneous magnetic field distribution in brushless permanent magnet DC motors. I. Open-circuit field. IEEE Trans Magn 29(1):143–151
Shuguang Z, Liu Xiaoxuan Yu, Xudong MW, Guohui Z (2017) Numerical prediction and analysis of electromagnetic vibration of permanent magnet synchronous motors. Trans China Electrotech Soc 32(1):159–167
Ping Y, Dai Ying HS et al (2012) Evaluation of electromagnetic noise of permanent magnet synchronous motor for vehicle based on finite element method. Motor Control Appl 39(9):33–59
Fakam M, Hecquet M, Lanfranchi V (2014) Design and magnetic noise reduction of the surface permanent magnet synchronous machine. In: 2014 ninth international conference on ecological vehicles and renewable energies (EVER)
Lefevre Y, Davat B (1989) Determination of synchronous motor vibrations due to electromagnetic force harmonics. IEEE Trans Magn 25(4):2974–2976
Torregrossa D, Peyraut F, Fahimi B et al (2011) Multiphysics finite-element modeling for vibration and acoustic analysis of permanent magnet synchronous machine. IEEE Trans Energy Convers 26(2):490–500
Ko H-S, Kim K-J (2004) Characterization of noise and vibration sources in interior permanent-magnet brushless DC motors. IEEE Trans Magn 40(6):3482–3489
Houjia H, Quanfeng L, Yufa X (2019) Research on the natural frequency of stator of permanent magnet synchronous motor based on inite element method. Electr Mach Control Appl 46(4):1–6
Ichikawa S, Tomita M, Doki S et al (2006) Sensorless control of permanent-magnet synchronous motors using online parameter identification based on system identification theory. Electr Eng 53(2):363–372
Acknowledgements
This work was supported by the National Natural Science Foundation of China (no. 51775543), the Key Research and Development Project of Xuzhou (no. KC17014), and a project funded by the Priority Academic Program Development (PAPD) of Jiangsu Higher Education Institutions.
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Yang, Z., Li, W., Gou, Y. et al. Research on Radial Force of Permanent Magnet Synchronous Motor Based on Maxwell. J. Electr. Eng. Technol. 15, 2601–2608 (2020). https://doi.org/10.1007/s42835-020-00511-9
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DOI: https://doi.org/10.1007/s42835-020-00511-9