Year 2021,
Volume: 17 Issue: 4, 429 - 436, 29.12.2021
Tuğberk Özmen
,
Nevzat Onat
References
- Duan, G., Wang, H., Guo, H., Gu, G. 2010. Direct drive permanent magnet wind generator design and electromagnetic field finite element analysis. IEEE transactions on applied superconductivity; 20(3): 1883-1887.
- He, Y., Zhao, W., Tang, H., Ji, J. 2020. Auxiliary teeth design to reduce short-circuit current in permanent magnet generators. CES Transactions on Electrical Machines and Systems; 4(3): 198-205.
- Chan, T. F., Wang, W., Lai, L. L. 2010. Permanent-magnet synchronous generator supplying an isolated load. IEEE Transactions on Magnetics; 46(8): 3353-3356.
- Tapia, J. A., Pyrhonen, J., Puranen, J., Lindh, P., Nyman, S. 2012. Optimal design of large permanent magnet synchronous generators. IEEE Transactions on Magnetics; 49(1): 642-650.
- Jang, S. M., Seo, H. J., Park, Y. S., Park, H. I., Choi, J. Y. 2012. Design and electromagnetic field characteristic analysis of 1.5 kW small scale wind power generator for substitution of Nd-Fe-B to ferrite permanent magnet. IEEE Transactions on Magnetics; 48(11): 2933-2936.
- Fang, H., Wang, D. 2016. A novel design method of permanent magnet synchronous generator from perspective of permanent magnet material saving. IEEE Transactions on Energy Conversion; 32(1): 48-54.
- Ishikawa, T., Amada, S., Segawa, K., Kurita, N. 2017. Proposal of a radial-and axial-flux permanent-magnet synchronous generator. IEEE Transactions on Magnetics; 53(6): 1-4.
- Kumar, R. R., Singh, S. K., Srivastava, R. K., Saket, R. K. 2020. Dynamic reluctance air gap modeling and experimental evaluation of electromagnetic characteristics of five-phase permanent magnet synchronous generator for wind power application. Ain Shams Engineering Journal; 11(2): 377-387.
- Cano, L., Arribas, L., Cruz, I. 2004. 1.5 kW permanent magnets synchronous generator experimental bench test. Department of Renewable Energie, CIEMAT.
- Advanced Energy, Permanent magnet generator performance testing, Report, January 23, 2014.
Comparative Performance Analysis of Surface Mounted Permanent Magnet Synchronous Generators
Year 2021,
Volume: 17 Issue: 4, 429 - 436, 29.12.2021
Tuğberk Özmen
,
Nevzat Onat
Abstract
One of the generator types used in producing electrical energy is permanent magnet synchronous generator (PMSG). In this study, a surface located permanent magnet synchronous machine with a 1.5 kW inner rotor was used as a reference generator. The finite element analysis of this generator was conducted via Maxwell Rmxprt software. As a result, phase current and voltages waveforms were measured at a rated load. The characteristics of the PMSG under loaded and unloaded working conditions were examined through the measurements on the experimental setup designed in Electrical Machines Laboratory at the Faculty of Engineering of Manisa Celal Bayar University. The values obtained from the open-circuit tests were compared with the simulation and manufacturer's catalog data. This paper also contrasted line voltages measured and simulated at 450 rpm as rated speed.
References
- Duan, G., Wang, H., Guo, H., Gu, G. 2010. Direct drive permanent magnet wind generator design and electromagnetic field finite element analysis. IEEE transactions on applied superconductivity; 20(3): 1883-1887.
- He, Y., Zhao, W., Tang, H., Ji, J. 2020. Auxiliary teeth design to reduce short-circuit current in permanent magnet generators. CES Transactions on Electrical Machines and Systems; 4(3): 198-205.
- Chan, T. F., Wang, W., Lai, L. L. 2010. Permanent-magnet synchronous generator supplying an isolated load. IEEE Transactions on Magnetics; 46(8): 3353-3356.
- Tapia, J. A., Pyrhonen, J., Puranen, J., Lindh, P., Nyman, S. 2012. Optimal design of large permanent magnet synchronous generators. IEEE Transactions on Magnetics; 49(1): 642-650.
- Jang, S. M., Seo, H. J., Park, Y. S., Park, H. I., Choi, J. Y. 2012. Design and electromagnetic field characteristic analysis of 1.5 kW small scale wind power generator for substitution of Nd-Fe-B to ferrite permanent magnet. IEEE Transactions on Magnetics; 48(11): 2933-2936.
- Fang, H., Wang, D. 2016. A novel design method of permanent magnet synchronous generator from perspective of permanent magnet material saving. IEEE Transactions on Energy Conversion; 32(1): 48-54.
- Ishikawa, T., Amada, S., Segawa, K., Kurita, N. 2017. Proposal of a radial-and axial-flux permanent-magnet synchronous generator. IEEE Transactions on Magnetics; 53(6): 1-4.
- Kumar, R. R., Singh, S. K., Srivastava, R. K., Saket, R. K. 2020. Dynamic reluctance air gap modeling and experimental evaluation of electromagnetic characteristics of five-phase permanent magnet synchronous generator for wind power application. Ain Shams Engineering Journal; 11(2): 377-387.
- Cano, L., Arribas, L., Cruz, I. 2004. 1.5 kW permanent magnets synchronous generator experimental bench test. Department of Renewable Energie, CIEMAT.
- Advanced Energy, Permanent magnet generator performance testing, Report, January 23, 2014.