Design of permanent magnet synchronous machine for micro-hybrid electric vehicle operation

• Autorzy: Štumberger B. , Hadžiselimović M.

Warianty tytułu

PL

Projekt maszyny synchronicznej z magnesami trwa!ymi dla mikrohybrydowego pojazdu elektrycznego

• Języki publikacji: EN

Abstrakty

EN

The paper presents characteristics of a permanent magnet synchronous machine designed for micro-hybrid electric vehicle operation. Appropriate design of interior permanent magnet machine with 36 stator slots and 8 stator poles for operation in motor and generator operation mode was investigated. Finite element analysis is employed in order to determine the machine performance.

PL

W artykule zaprezentowano charakterystyki działania maszyny synchronicznej z magnesami trwałymi zaprojektowanej dla mikrohybrydowego pojazdu elektrycznego, Przebadano projekt wętrza, wspomnianej wyżej, maszyny z 36 żlobkami stojana i 8 biegunami w stojanie. Model komputerowy został oparty o metodę elementów skończonych.

Słowa kluczowe

EN

synchronous machine; permanent magnets; micro-hybrid electric vehicle

PL

maszyna synchroniczna; trwały magnes; mikrohybrydowy pojazd elektryczny

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2011
• Tom: R. 87, nr 12b
• Strony: 157--160
• Opis fizyczny: Bibliogr. 16 poz., rys., tab., wykr.

Twórcy

autor

Štumberger B.

• University of Maribor, Faculty of Energy Technology

autor

Hadžiselimović M.

• University of Maribor, Faculty of Energy Technology
• University of Maribor, Faculty of Electrical Engineering and Computer Science

Bibliografia

• 1. M. Barcaro et al., Performance evaluation of an integrated starter alternator using an interior permanent magnet machine, IET Electr. Power Appl., 4 (2010), 539-546.
• 2. L. Alberti et al., IPM machine drive design and tests for an integrated starter alternator application, IEEE Transactions on Industry Applications, 46 (2010), 993-1001.
• 3. L. Chedot et al., Integrated starter generator: The need for an optimal design and control approach. Application to a permanent magnet machine, IEEE Transactions on Industry Applications, 43 (2007), 551-559.
• 4. J. G. Seo et al., Rotor-design strategy of IPMSM for 42 V integrated starter generator, IEEE Transactions on Magnetics, 46 (2010), 2458-2461.
• 5. J. Legranger et al., Combination of finite element and analytical models in the optimal multidomain design of the machines: application to an interior permanent magnet starter generator, IEEE Transactions on Industry Applications 46 (2010), 232- 239.
• 6. C. Feng et al., The performance research of starter-generator based on reluctance torque used in HEV, IEEE Transactions on Magnetics”, 45 (2009), 635-638.
• 7. S. Chen et al., Design and testing of a belt-driven induction starter-generator, IEEE Transactions on Industry Applications 38 (2002), 1525-1533
• 8. K. Chwastek, Estimation method for the Jiles-Atherton model parameters-a review, Przeglad Electrotechniczny, (2008), 145- 148
• 9. J. Szczyglowski et al., Improvement of the prediction of the loss of magnetic material, Przeglad Electrotechniczny,(2010), 45-47
• 10. M. Kuczmann, Measurement and simulation of vector hysteresis, Przeglad Electrotechniczny, (2011), 103-106
• 11. M. Kuczmann, Vector Preisach hysteresis modelling: Measurement, identification and application, Physica BCondesed Matter, 406 (2011), 1403-1409
• 12. B. Štumberger et al., Power and cooling capability of synchronous generator with interior permanent magnets: laboratory verification of machine characteristics, Przeglad Electrotechniczny, 3 (2011), 183-186.
• 13.B. Štumberger et al., Determination of the adequate split ratio for high-efficiency permanent magnet synchronous motors with surface mounted magnets and concentrated non-overlapping windings , Przeglad Electrotechniczny, 3 (2011), 187-189.
• 14. B. Štumberger at al., Analysis of iron loss in interior permanent magnet synchronous motor over a wide range of constant output power operation, IEEE Transactions on Magnetics, 36 (2000), 1846-1849
• 15. B. Štumberger et al., Design and finite-element analysis of interior permanent magnet synchronous motor with flux barriers, IEEE Transactions on Magnetics, 44 (2008), 4389- 4392.
• 16. B. Štumberger et al., Accuracy of iron loss calculation in electrical machines by using different iron loss models, Journal of Magnetism and Magnetic Materials, 2003, (254/255), 269- 271.