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Post-fault operation of FOC-controlled 5-phase induction machine with hysteresis and PI+SVM current control

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PL
Praca w przypadku awarii 5-fazowej maszyny indukcyjnej z wykorzystaniem histerezowych oraz liniowych PI+SVM regulatorów prądu
Języki publikacji
EN
Abstrakty
EN
The paper presents a post-fault operation of 5-phase induction machine supplied from 2-level, 5-leg power converter. Presented simulation results consider an open-phase fault operation without fault-tolerant control. Thus this work compares torque and speed ripples in this faulted condition for Field Oriented Control (FOC) system with nonlinear hysteresis current controller (HCC) and linear PI + Space Vector Modulator (PI+SVM), respectively.
PL
Artykuł prezentuje pracę 5-fazowej maszyny indukcyjnej w przypadku awarii spowodowanej przerwą w jednej z faz. Przedstawione wyniki symulacyjne dotyczą zachowania się algorytmu sterowania wektorowego zorientowanego względem strumienia wirnika dla dwóch różnych metod regulacji prądu. Pierwsza z nich wykorzystuje metodę histerezową, druga natomiast liniową regulację prądów w wirującym układzie współrzędnych oraz modulator wektorowy SVM.
Rocznik
Strony
144--148
Opis fizyczny
Bibliogr. 19 poz., rys., tab.
Twórcy
autor
  • Politechnika Warszawska, Instytut Sterowania i Elektroniki Przemysłowej, ul. Koszykowa 75a, 00-662 Warszawa
Bibliografia
  • [1] Wang H., Liserre M., and Blaabjerg F., Toward Reliable Power Electronics: Challenges, Design Tools, and Opportunities, IEEE Ind. Electron. Mag., vol. 7, (Jun. 2013), no. 2, pp. 17–26
  • [2] Lezana P., Pou J., Meynard T. A., Rodriguez J., Ceballos S. and Richardeau F., Survey on Fault Operation on Multilevel Inverters, Ind. Electron. IEEE Trans., vol. 57, (2010), no. 7, pp. 2207–2218.
  • [3] Rajashekara K., Power Electronics for More Electric Aircraft, in Power Electronics for Renewable Energy Systems, Wiley, (2014), pp. 365–385.
  • [4] Lyding P., Faulstich S. and Kuhn P., “Establishing a Common Data Base for Turbine Failures,” (2009), Fraunhofer Institute for Wind Energy and Energy System Technology (IWES).
  • [5] Song Y. and Wang B., Analysis and Experimental Verification of a Fault-Tolerant HEV Powertrain, IEEE Trans. Power Electron., vol. 28, (2013), no. 12, pp. 5854–5864.
  • [6] Burzanowska H., Sario P., Stulz C. and Joerg P., Redundant Drive with Direct Torque Control (DTC) and dual-star synchronous machine, simulations and verification, Power Electronics and Applications, 2007 European Conference on (2007), pp. 1–10.
  • [7] Che H. S., Duran M. J., Levi E., Jones M., Hew W.-P. and Rahim N. A., Postfault Operation of an Asymmetrical Six-Phase Induction Machine With Single and Two Isolated Neutral Points, IEEE Trans. Power Electron., vol. 29, (Oct. 2014), no. 10, pp. 5406–5416.
  • [8] Jacobina C. B., Freitas I. S., Oliveira T. M., da Silva E. R. C. and Lima A. M. N., Fault tolerant control of five-phase AC motor drive, in 2004 IEEE 35th Annual Power Electronics Specialists Conference (IEEE Cat. No.04CH37551), (2004), vol. 5, pp. 3486–3492.
  • [9] Tani A., Mengoni M., Zarri L., Serra G. and Member S., Control of Multiphase Induction Motors With an Odd Number of Phases Under Open-Circuit Phase Faults, IEEE Trans. on Power Electronics, vol. 27, (2012), no. 2, pp. 565–577.
  • [10] Parsa L.,Toliyat H. A. and Member S.,Fault-Tolerant Interior-Permanent-Magnet Machines for Hybrid Electric Vehicle Applications, IEEE Trans. on Vehicular Technology ,vol. 56, (2007), no. 4, pp. 1546–1552.
  • [11] Salehifar M., Arashloo R. S., Moreno-Equilaz J. M., Sala V., and Romeral L., Fault Detection and Fault Tolerant Operation of a Five Phase PM Motor Drive Using Adaptive Model Identification Approach, IEEE J. Emerg. Sel. Top. Power Electron., vol. 2, (Jun. 2014), no. 2, pp. 212–223.
  • [12] Levi E., Multiphase AC machines, Chapter 3 in The Industrial Electronics Handbook: Power Electronics and Motor Drives, in The Industrial Electronics Handbook: Power Electronics and Motor Drives, 2nd Edition, 2nd ed., 2nd, Ed. CRC Press: Taylor and Francis Group: Boca Raton, FL, 2011, (2011), pp. 3.1–3.31.
  • [13] Sadeghi S., Guo L., Toliyat H. A., and Parsa L., “Wide Operational Speed Range of Five-Phase Permanent Magnet Machines by Using Different Stator Winding Configurations,” IEEE Trans. Ind. Electron., vol. 59, (Jun. 2012), no. 6, pp. 2621–2631.
  • [14] Karugaba S., Wang G., Ojo O., and Omoigui M., “Dynamic and steady-state operation of a five phase induction machine with an open stator phase,” in Power Symposium, 2008. NAPS ’08. 40th North American, (2008), pp. 1–8..
  • [15] Kazmierkowski M. P. and Malesani L., “Current control techniques for three-phase voltage-source PWM converters: a survey,” IEEE Trans. Ind. Electron., vol. 45, (1998), no. 5, pp. 691–703.
  • [16] Zhao Y. and Lipo T. A., “Space vector PWM control of dual three-phase induction machine using vector space decomposition,” Ind. Appl. IEEE Trans., vol. 31, (1995), no. 5, pp. 1100–1109.
  • [17] Grandi G., Serra G., and Tani A., “Space Vector Modulation of a Six-Phase VSI based on three-phase decomposition,” 2008 Int. Symp. Power Electron. Electr. Drives, Autom. Motion, (Jun. 2008), pp. 674–679.
  • [18] Dujic D., “Development of Pulse-Width-Modulation Techniques for Multi-phse and multi-leg Voltage Source Inverter,” Liverpool John Moores University, (2008).
  • [19] Yepes A. G., Vidal A., Member S., and Malvar J., Tuning Method Aimed at Optimized Settling Time and Overshoot for Synchronous Proportional-Integral Current Control in Electric Machines, IEEE Trans. Power Electron vol. 29, (2014), no. 6, pp. 3041–3054.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d792db0f-51de-4d22-935b-06a9f898397b
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