Sensorless start-up of traction switched reluctance motors of the railway rolling stock

• Autorzy: Tchavychalov M.

Warianty tytułu

RU

Ездатчиковый пуск тяговых вентильно-индукторных электрических машин подвижного состава железных дорог

• Języki publikacji: EN

Abstrakty

EN

The problem of SRM sensorless start is described. The new algorithm of traction switched reluctance motor sensorless start-up in a course is adduced. Results of physical modeling of the described method are given.

RU

Описана проблема бездатчикового пуска ВИД. Приведен новый алгоритм бездатчикового пуска тягового вентильно-индукторного двигателя. Даны результаты физического моделирования описанного алгоритма.

Słowa kluczowe

EN

switched reluctance motor; sensorless control; start-up in a course

PL

sterowanie bezczujnikowe; start-up w trakcie

• Wydawca: Wydawnictwo Politechniki Śląskiej
• Czasopismo: Transport Problems
• Rocznik: 2013
• Tom: T. 8, z. 2
• Strony: 121--127
• Opis fizyczny: Bibliogr. 13 poz.

Twórcy

autor

Tchavychalov M.

• Rostov State University of Transport Communication 2 Rostovskogo Strelkovogo Polka Narodnogo Opolcheniya sq., Rostov-on-Don, 344038, Russia

Bibliografia

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• 2. Krishnan R. Switched reluctance motor drives: modeling, simulation, analysis, design, and applications. CRC Press. 2001. 416 p.
• 3. Acarnley, P.P. & Hill, R.J. & Hooper, C.W. Detection of rotor position in stepping and switched reluctance motors by monitoring of current waveforms. IEEE Transactions. 1985. Vol. 32. No. 3. P. 215-222.
• 4. Husain, I. Indirect rotor-position estimation techniques for switched reluctance motors: a review. Electromotion. 1996. Vol. 3. No. 2. P. 94-102.
• 5. Lyons, J. & MacMinn, S. & Preston, M. Flux/Current methods for SRM rotor position estimation. In: IEEE-IAS Conf. Rec. 1991. P. 482-487.
• 6. Acarnley, P. & Hill, R. & Hooper, C. Detection of rotor position in stepping and switched reluctance motors by monitoring of current waveforms. IEEE Trans. Industrial Electronics. 1985. No 3. P. 215-222.
• 7. Panda, S. & Amaratunga, G. Analysis of the waveform detection technique for indirect rotor position sensing of switched reluctance motor drives. IEEE Trans. on Energy Conversion. 1991. No 3. P. 476-483.
• 8. Lumsdaine, A. & Lang, J. State observers for variable-reluctance motors. IEEE Trans. Industrial Electronics. 1990. No. 2. P. 133-142.
• 9. Fedigan, S.J. & Cole, C.P. A variable-speed sensorless drive system for switched reluctance motors. Application Report. SPRA600. Texas Instruments. 1999. 35 p. Available at: http://www.ti.com/lit/an/spra600/spra600.pdf
• 10. Visinka, R. 3-Phase Switched Reluctance (SR) Sensorless Motor Control Using a 56F80x, 56F8100 or 56F8300 Device. Design of a Motor Control Application. Freescale Semiconductor. Application Note. 2005. AN1932. Rev. 2. Available at: http://www.freescale. com/files/ product/doc/AN1932.pdf
• 11. Kireev, A.V. Combined method of tractional switched reluctance electric drive control without rotor position sensor. University’s news. Electromechanics. 2010. No. 1. P. 32-38.
• 12. Lopez, G.G. & Kjaer, P.C. & Miller, T.J.E. A new sensorless method for switched reluctance motor drives. IEEE Transaction on Industry Applications. 1998. No. 4. P. 832-840.
• 13. Lopez, G.G. & Kjaer, P.C. & Miller, T.J.E. High-grade position estimation for SRM drives using fluxlinkage/current correction model. IEEE Transactions on Industry Applications. 1999. Vol. 35. No. 4. P. 859-869.