EFFICIENCY AND LOSS PREDICTION OF DOUBLE-STATOR PM MACHINES

Chukwuemeka C. Awah, Ogbonnaya I. Okoro, and Edward Chikuni

References

  1. [1] D. Kim, H. Hwang, S. Bae, and C. Lee, Analysis and design of double-stator flux-switching permanent magnet machine using ferrite magnet in hybrid electric vehicles, IEEE Transactions on Magnetics, 52(7), 2016, 8106604.
  2. [2] L. Chong, R. Dutta, M.F. Rahman, and H. Lovatt, Experimental verification of core and magnet losses in a concentrated wound IPM machine with V-shaped magnets used in field weakening applications, Proc. Int. Conf. Electric Machines & Drives (IEMDC), Niagara Falls, ON, 2011, 977–982.
  3. [3] C. Mi, G.R. Slemon, and R. Bonert, Modeling of iron losses of permanent-magnet synchronous motors, IEEE Transactions on Industry Applications, 39(3), 2003, 734–742.
  4. [4] M. Ibrahim and P. Pillay, A hybrid model for improved hysteresis loss prediction in electrical machines, IEEE Transactions on Industry Applications, 50(4), 2014, 2503–2511.
  5. [5] D. Eggers, S. Steentjes, and K. Hameyer, Advanced iron-loss estimation for nonlinear material behavior, IEEE Transactions on Magnetics, 48(11), 2012, 2503–2511.
  6. [6] M. Ibrahim and P. Pillay, Core loss prediction in electrical machine laminations considering skin effect and minor hysteresis loops, IEEE Transactions on Industry Applications, 49(5), 2013, 2061–2068.
  7. [7] S.J. Lee, S.I. Kim, and J.P. Hong, Investigation on core loss according to stator shape in interior permanent magnet synchronous motor, Proc. Int. Conf. Electrical Machines and Systems (ICEMS), Wuhan, 2008, 3158–3161.
  8. [8] T. Fukami, H. Aoki, K. Shima, M. Momiyama, and M. Kawamura, Assessment of core losses in a flux-modulating synchronous machine, IEEE Transactions Industry Applications, 48(2), 2012, 603–611.
  9. [9] K. Yamazaki, M. Kumagai, T. Ikemi, and S. Ohki, “A novel rotor design of interior permanent magnet synchronous motors to cope with both maximum torque and core loss reduction, IEEE Transactions on Industry Applications, 49(6), 2013, 2472–2486.
  10. [10] A.S. Abdel-Khalik, S. Ahmed, and A.M. Massoud, Low space harmonics cancelation in double-layer fractional slot winding using dual multiphase winding, IEEE Transactions on Magnetics, 51(5), 2015, 8104710.
  11. [11] S. Okamoto, N. Denis, Y. Kato, M. Ieki, and K. Fujisaki, Core loss reduction of an interior permanent-magnet synchronous motor using amorphous stator core, IEEE Transactions Industry Applications, 52(3), 2016, 2261–2268.
  12. [12] G. Choi and T.M. Jahns, Reduction of eddy-current losses in fractional-slot concentrated-winding synchronous PM machines, IEEE Transactions on Magnetics, 52(7), 2016, 8105904.
  13. [13] Y. Kawase, T. Yamaguchi, S. Sano, M. Igata, K. Ida, and A. Yamagiwa, 3-D eddy current analysis in a silicon steel sheet of an interior permanent magnet motor, IEEE Transactions on Magnetics, 39(3), 2003, 1448–1451.
  14. [14] K. Yamazaki and Y. Fukushima, Effect of eddy-current loss reduction by magnet segmentation in synchronous motors with concentrated windings, IEEE Transactions on Industry Applications, 47(2), 2011, 779–788.
  15. [15] S.Y. Oh, S.Y. Cho, J.H. Han, et al., Design of IPMSM rotor shape for magnet eddy-current loss reduction, IEEE Transactions on Magnetics, 50(2), 2014, 7020804.
  16. [16] M.M. Koo, J.Y. Choi, K. Hong, and K. Lee, Comparative analysis of eddy-current loss in permanent magnet synchronous machine considering PM shape and skew effect using 3-D FEA, IEEE Transactions on Magnetics, 51(11), 2015, 6301104.
  17. [17] A.S. Nagorny, N.V. Dravid, R.H. Jansen, and B.H. Kenny, Design aspects of a high speed permanent magnet synchronous motor/generator for flywheel applications, Proc. Int. Conf. Electric Machines & Drives (IEMDC), San Antonio, TX, 2005, 635–641.
  18. [18] T. Ishikawa, Y. Sato, and N. Kurita, Performance of novel permanent magnet synchronous machines made of soft magnetic composite core, IEEE Transactions on Magnetics, 50(11), 2014, 8105304.

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