Characteristic Analysis of High-Speed PMSG According to Winding Distribution
-
2018-12-13 https://doi.org/10.14419/ijet.v7i4.39.25579 -
High-speed PMSG, electromagnetic performance, winding distribution, equivalent circuit method, generating characteristic. -
Abstract
Background/Objectives: In this study, we investigate the distribution of windings with optimum performance from the performance analysis according to the winding distribution of a high-speed permanent magnet synchronous generator (PMSG).
Methods/Statistical analysis: Electromagnetic parameters of the high-speed PMSG are derived using the finite element analysis. The relationship between the winding coefficient and the electromagnetic parameter is defined, and the change in the parameters, according to the winding distribution, is confirmed. The generating characteristics analysis is performed using the equivalent circuit method (ECM), and the efficiency characteristics are analyzed from the ECM and the loss analysis.
Findings: This paper presents the influence of winding distribution on the electromagnetic performance of high-speed PMSGs. The factors affecting the performance of the PMSG are back electromotive force (EMF), inductance, and resistance. As regards low-speed PMSGs, back EMF and resistance generally have a large effect on performance. However, as regards a high-speed PMSG, the reactance increases as the operating frequency increases. Therefore, inductance, as well as back EMF and resistance, are the main factors affecting performance. We propose a method to select the optimal winding distribution based on the investigation of the influence of the winding distribution on the electromagnetic performance using the ECM considering loss characteristics.
Improvements/Applications: Based on the analysis results, it is possible to use winding distribution as a design point in both the initial and optimum designs of the high-speed PMSG.
Â
Â
-
References
[1] Uehara, A., Pratap, A., Goya, T., Senjyu, T., Yona, A., Urasaki, N., & Funabashi, T. (2011). A coordinated control method to smooth wind power fluctuations of a PMSG-based WECS. IEEE Transactions on energy conversion, 26(2), 550-558.
[2] Hong, D. K., Joo, D., Woo, B. C., Jeong, Y. H., & Koo, D. H. (2013). Investigations on a super high speed motor-generator for microturbine applications using amorphous core. IEEE Transactions on Magnetics, 49(7), 4072-4075.
[3] Li, W., Zhang, X., Cheng, S., & Cao, J. (2013). Thermal optimization for a HSPMG used for distributed generation systems. IEEE Transactions on Industrial Electronics, 60(2), 474-482.
[4] Rahman, M. A., Chiba, A., & Fukao, T. (2004, June). Super high speed electrical machines-summary. In Power Engineering Society General Meeting, 2004. IEEE (pp. 1272-1275). IEEE.
[5] Binder, A., Schneider, T., & Klohr, M. (2006). Fixation of buried and surface-mounted magnets in high-speed permanent-magnet synchronous machines. IEEE Transactions on Industry Applications, 42(4), 1031-1037.
[6] Zhou, F., Shen, J., Fei, W., & Lin, R. (2006). Study of retaining sleeve and conductive shield and their influence on rotor loss in high-speed PM BLDC motors. IEEE transactions on magnetics, 42(10), 3398-3400.
[7] Chan, T. F., Lai, L. L., & Yan, L. T. (2004). Performance of a three-phase AC generator with inset NdFeB permanent-magnet rotor. IEEE transactions on energy conversion, 19(1), 88-94.
[8] Krishnan, R. (2017). Permanent magnet synchronous and brushless DC motor drives. CRC press.
[9] Hanselman, D. C. (2012). Brushless motors: magnetic design, performance, and control of brushless dc and permanent magnet synchronous motors. E-Man Press LLC.
[10] Gieras, J. F. (2002). Permanent magnet motor technology: design and applications. CRC press.
-
Downloads
-
How to Cite
Shin, K.-H., Yoon, I.-J., Nah, J., & Choi, J.-Y. (2018). Characteristic Analysis of High-Speed PMSG According to Winding Distribution. International Journal of Engineering & Technology, 7(4.39), 681-685. https://doi.org/10.14419/ijet.v7i4.39.25579Received date: 2019-01-09
Accepted date: 2019-01-09
Published date: 2018-12-13