Electric machines

Revision as of 16:34, 17 July 2013 by Ruth V. Sabariego (talk | contribs) (Additional information)

Revision as of 16:34, 17 July 2013 by Ruth V. Sabariego (talk | contribs) (Additional information)

2D models of electric machines: permanent magnet and wound field synchronous machines, induction machines, switched reluctance machine.

Download model archive (machines.zip)
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Additional information

The example contains:

  • pmsm.pro and pmsm_cbmag.pro: an eight-pole permanent magnet synchronous machine from GRUCAD, Universidade Federal de Santa Catarina, Brazil (the geometry of pmsm is a simplified version of pmsm_cbmag)[1][2][3]
  • lomonova.pro: an eight-pole permanent magnet machine [4]
  • wfsm_4p.pro: a four-pole wound field synchronous machine [5]
  • t30.pro: induction motor with solid rotor [6]
  • im_3kw.pro: induction machine [7][8][9]
  • im.pro: a four-pole induction machine [10]

References

  1. M. V. Ferreira da Luz, P. Dular, N. Sadowski, C. Geuzaine, and J. P. A. Bastos, "Analysis of a Permanent Magnet Generator With Dual Formulations Using Periodicity Conditions and Moving Band", IEEE Trans. Mag., Vol 38, No. 2, pp. 961-964, 2002.
  2. J. Gyselinck, N. Sadowski, P. Dular, M. V. Ferreira da Luz, J. P. A. Bastos, and W. Legros, "Harmonic Balance Finite Element Modelling of a Permanent-Magnet Synchronous Machine", Proceedings of CBMag 2002.
  3. J. Gyselinck, P. Dular, L. Vandevelde and J. Melkebeek, A.M. Oliveira and P. Kuo-Peng, "Two-dimensional harmonic balance finite element modelling of electrical machines taking motion into account", COMPEL, Vol. 22, No. 4, pp. 1021-1036, 2003.
  4. E.A. Lomonova, E. Kazmin, Y. Tang, J.J.H. Paulides, "In-wheel PM Motor: Compromise between High Power Density and Extended Speed Capability", COMPEL: The International Journal for Computation and Mathematics in Electrical and Electronic Engineering, Vol. 30, No. 1, pp. 98-116, 2011.
  5. J. Gyselinck, L. Vandevelde, J. Melkebeek, W. Legros, "Steady-State Finite Element Analysis of a Salient-Pole Synchronous Machine in the Frequency Domain", Proceedings Electrimacs 2002, Montréal, Canada, August 18-21, 6 p.
  6. International TEAM Workshop Problem 30a - Induction Motor Analyses, Kent Davey
  7. J. Gyselinck, "Twee Dimensionale Dynamische Eindige-Elementenmodellering van Statische en Roterende Elektromagnetische Energieomzetters", Doktoraatsthesis, Universiteit Gent, 2000.
  8. J. Gyselinck, L. Vandevelde, J. Melkebeek, "Multi-slice modeling of electrical machines with skewed slots - The skew discretization error”, IEEE Trans. Magn., vol. 37, pp. 3233–3237, 2002.
  9. J. Gyselinck, L. Vandevelde, P. Dular, C. Geuzaine, W. Legros, "A General Method for the Frequency Domain FE Modeling of Rotating Electromagnetic Devices", IEEE Trans. Magn., Vol. 39, No. 3, May 2003.
  10. S. Guérard, J. Gyselinck, and J. Lecomte-Beckers,"Finite element modelling of an asynchronous motor with one broken rotor bar, comparison with the data recorded on a prototype and material aspects", Bulletin Scientifique de l'AIM, Vol.1, pp. 13-22, 2005. Prix Melchior Salier 2004 du meilleur travail de fin d'études section électromécanique-énergétique.

Models developed by R. Sabariego, J. Gyselinck and C. Geuzaine. This work was funded in part by the Walloon Region (WBGreen No 1217703 FEDO, WIST3 No 1017086 ONELAB) and by the Belgian Science Policy (IAP P7/02). Copyright (c) 2012-2015 ULg-ULB.