ADVANCEMENTS IN CONVERTER TOPOLOGY AND CONTROL STRATEGIES FOR SWITCHED RELUCTANCE MOTORS: RECENT CONTRIBUTIONS

V. Shirish Murty, Shailendra Jain, and Amit Ojha

References

  1. [1] T.J.E. Miller, Switched reluctance motors and their control(Oxford, UK: Magna Phys Publ, Dec 1993).
  2. [2] I. Boldea, L.N. Tutelea, L. Parsa, and D. Dorrell, Automo-tive electric propulsion systems with reduced or no perma-nent magnets: An overview, IEEE Transactions on IndustrialElectronics, 61(10), Oct 2014, 5696–5711.
  3. [3] R. Krishnan, Switched reluctance motor drives: Modeling,simulation, analysis, design and applications, Industrial Elec-tronics Series CRC Press, 1(1), Jun 2001.
  4. [4] N. Zabihi and R. Gouws, A review on switched reluctancemachines for electric vehicles, IEEE 25th International Sympo-sium on Industrial Electronics (ISIE), Santa Clara, California,USA, 2016, 799–804.
  5. [5] Y. A. Alamoudi, A. Ferrah, R. Panduranga, A. Althobaiti, andF. Mulolani, State-of-the art electrical machines for modernelectric vehicles, 2019 Advances in Science and EngineeringTechnology International Conferences (ASET), Dubai, UnitedArab Emirates, 2019, 1–8.
  6. [6] E. Bostanci, M. Moallem, A. Parsapour, and B. Fahimi,Opportunities and challenges of switched reluctance motordrives for electric propulsion: a comparative study, IEEETransactions on Transportation Electrification, 3(1), 2017,58–75.
  7. [7] R. Abdel-Fadil, F. Al-Amyal, and L. Sz´amel, Torque rip-ples minimization strategies of switched reluctance motor – areview, 2019 International IEEE Conference and Workshop in´Obuda on Electrical and Power Engineering (CANDO-EPE),Budapest, Hungary, 2019, 41–46.
  8. [8] P. Pramod, P. Nuli, R. Mitra and S. Mehta, Modeling andsimulation of switched reluctance machines for control andestimation tasks, 2019 IEEE International Electric Machines &Drives Conference (IEMDC), San Diego, CA, USA, 2019,565–570.6
  9. [9] J. Liang et al., Prediction of acoustic noise and vibration of a24/16 traction switched reluctance machine, in IET ElectricalSystems in Transportation, 10(1), 2020, 35–43.
  10. [10] C. Lin and B. Fahimi, Prediction of radial vibration inswitched reluctance machines, IEEE Transactions on EnergyConversion, 28(4), Dec 2013, 1072–1081.
  11. [11] Z. Tang, P. Pillay, Y. Chen, and A.M. Omekanda, Predictionof electromagnetic forces and vibrations in SRMs operatingat steady-state and transient speeds, IEEE Transactions onIndustrial Applications, 41(4), Jul/Aug 2005, 927-934.
  12. [12] S. Elsaiah and C. Brady-Alvarez, A switched reluctance motordrive system for future applications in the emerged IMPS,2018 North American power symposium (NAPS), Fargo, ND,2018, 1–5.
  13. [13] R. Jeyabharath, P. Veena, and M. Rajaram, A new convertertopology for switched reluctance motor drive, IEEE Indi-con conference, Annual IEEE India Conference (INDICON),Chennai, India, Dec 2005, 11–13.
  14. [14] H. Vasquez, J. Parker, and T. Haskew, Control of a 6/4 switchedreluctance motor in a variable speed pumping application,Mechatronics, 15(9), Jun 2005, 1061–1071.
  15. [15] M. Ruba, I. Viorel, and L. Szab´o, Modular stator switchedreluctance motor for fault tolerant drive systems, IET ElectricPower Applications, 7(3), 2013, 159–169.
  16. [16] X. Liu and Z. Pan, Study on switched reluctance motor usingthree-phase bridge inverter: Analysis and comparison withasymmetric bridge, International conf. on electrical machinesand systems, Jun 2008, 1354–1358.
  17. [17] F. Peng, J. Ye, and A. Emadi, An asymmetric three-levelneutral point diode clamped converter for switched reluctancemotor drives, IEEE Transactions on Power Electronics, 32(11),Nov 2017, 8618–8631.
  18. [18] M.N. Anwar and O. Husain, Radial force calculation andacoustic noise prediction in switched reluctance machines,IEEE Transactions on Industrial Applications, 36(6), Nov2000, 1589–1597.
  19. [19] R. Abdel-Fadil, F. Al-Amyal and L. Sz´amel, Torque ripplesminimization strategies of switched reluctance motor - AReview, 2019 International IEEE Conference and Workshop in´Obuda on Electrical and Power Engineering (CANDO-EPE),Budapest, Hungary, 2019, 41–46.
  20. [20] Z.Q. Zhu and D. Howe, Electrical machines and drives forelectric, hybrid, and fuel cell vehicles, Proceedings of the IEEE,95(4), April 2007, 746–765.
  21. [21] M. Zeraoulia, M.E.H. Benbouzid, and D. Diallo, Electric motordrive selection issues for HEV propulsion systems: A com-parative study, IEEE Transactions on Vehicular Technology,55(6), Nov 2006, 1756–1764.
  22. [22] X. Xue, K. Cheng, J. Lin, Z. Zhang, K. Luk, T. Ng, and N.Cheung, ‘Optimal control method of motoring operation forSRM drives in electric vehicles, IEEE Transactions on VehicleTechnology, 59(3), Mar 2010, 1191–1204.
  23. [23] O. Ellabban and H. Abu-Rub, Switched reluctance motorconverter topologies: A review, IEEE international conferenceon industrial technology (ICIT), Vol. 1, Busan, Feb 2014,840–846.
  24. [24] A.P. Khedkar and P.S. Swami, Comparative study of asym-metric bridge and split AC supply converter for switchedreluctance motor, International conference on computationof power, energy information and communication, Dec 2017,522–526.
  25. [25] V. Petrus, A.C. Pop, C.S. Martis, J. Gyselinck, and V. Iancu,Design and comparison of different switched reluctance machinetopologies for electric vehicle propulsion, XIX internationalconference on electrical machines (ICEM), 2010, 1–6.
  26. [26] J. Kavali, A. Mittal, and A. Ojha, A symmetrical multilevelinverter topology with minimal switch count and total harmonicdistortion, Journal of Circuits, Systems and Computers, 2019.
  27. [27] C. Gan, J. Wu, Q. Sun, W. Kong, H. Li, and Y. Hu, A reviewon machine topologies and control techniques for low-noiseswitched reluctance motors in electric vehicle applications,IEEE Access, 6, 2018, 31430-31443.
  28. [28] C. Gan, J. Wu, Y. Hu, S. Yang, W. Cao, and J.M. Guerrero,‘New integrated multilevel converter for switched reluctancemotor drives in plug-in hybrid electric vehicles with flexibleenergy conversion, IEEE Transactions on Power Electronics,32(5), May 2017, 3754–3766.
  29. [29] J. Tandekar, A. Ojha, and S. Jain, Five-level cascaded H-bridgeMLC-based shunt active power filter for active harmonicsmitigation in distributed network, Journal of Circuits, Systemsand Computers, 2018.
  30. [30] H. Torkaman, A. Ghaheri, and A. Keyhani, Axial flux switchedreluctance machines: A comprehensive review of design andtopologies, IET Electric Power Applications, 13(3), 2019,310–321.
  31. [31] F.C. Lin and S.M. Yang, An approach to producing controlledradial force in a switched reluctance motor, IEEE Transactionson Industrial Electronics, 54(4), Aug 2007, 2137–2146.
  32. [32] S.M. Castano, B. Bilgin, E. Fairall, and A. Emadi, ‘Acous-tic noise analysis of a high-speed high-power switched reluc-tance machine: Frame effects, IEEE Transactions on EnergyConversion, 31(31), Mar. 2016, 69–77.
  33. [33] A.Chiba, Y. Takana, M. Takeno, T. Imakawa, N. Hoshi, M.Takemoto, and S. Ogasawara, Torque density and efficiencyimprovements of a switched reluctance motor without rare-earth material for hybrid vehicles, IEEE Transactions onIndustry Applications, 47(3), May–June 2011, 1240–1246.
  34. [34] I. Husain, Minimization of torque ripple in SRM drives, IEEETransactions on Industrial Electronics, 49(1), Feb 2002, 28–39.
  35. [35] V.P. Vujicic, Minimization of torque ripple and copper lossesin switched reluctance drive, IEEE Transactions on PowerElectronics, 27(1), 2012, 388–399.
  36. [36] H. Iqbal, Minimization of torque ripple in SRM drives, IEEETransactions on Industrial Electronics, 49(1), 2002, 28–39.
  37. [37] N. Yan, X. Cao, and Z. Deng, Direct torque control forswitched reluctance motor to obtain high torque–ampere ratio,IEEE Transactions on Industrial Electronics, 66(7), July 2019,5144–5152.
  38. [38] H. Bian, W. Ding, Z. Luo, Y. Li, and K. Song, Directtorque control of a novel modular structure hybrid-excitationswitched reluctance motor based on vector control, 2019 22ndinternational conference on electrical machines and systems(ICEMS), Harbin, China, 2019, 1–5.
  39. [39] Z. Hao, Q. Yu, X. Cao, X. Deng, and X. Shen, An improveddirect torque control for a single-winding bearingless switchedreluctance motor, IEEE Transactions on Energy Conversion,35, 2020, 1381–1393.
  40. [40] P.K. Reddy, D. Ronanki, and P. Perumal, Efficiency improve-ment and torque ripple minimisation of four-phase switchedreluctance motor drive using new direct torque control strategy,IET Electric Power Applications, 14(1), 2020, 52–61.
  41. [41] K. Diao, X. Sun, L. Chen, Y. Cai, H. Wang, and J. Wu, Directtorque control of a segmented switched reluctance motor forBSG in HEVs, 2019 3rd conference on vehicle control andintelligence (CVCI), Hefei, China, 2019, 1–6.
  42. [42] A. Klein-Hessling, A. Hofmann, and R.W. De Doncker,Direct instantaneous torque and force control: A control ap-proach for switched reluctance machines, IET Electric PowerApplications, 11(5), May 2017, 935–943.
  43. [43] R.B. Inderka and R.W.A.A. De Doncker, DITC – Directinstantaneous torque control of switched reluctance drives,IEEE Transactions on Industrial Applications, 39(4), Jul 2003,1046–1051.
  44. [44] R. Shahbazi, S.M. Saghaiannezhad, and A. Rashidi, A newconverter based on DITC for improving torque ripple andpower factor in SRM drives, 2020 11th power electronics, drivesystems, and technologies conference (PEDSTC), Tehran, Iran,2020, 1–5.
  45. [45] S. Wang, Z. Hu, and X. Cui, Research on novel direct instan-taneous torque control strategy for switched reluctance motor,IEEE Access, 8, 2020, 66910–66916.
  46. [46] Q. Sun, J. Wu, and C. Gan, Optimized direct instan-taneous torque control for SRMs with efficiency improve-ment, IEEE Transactions on Industrial Electronics, doi:10.1109/TIE.2020.2975481.
  47. [47] C.H. Kim and I.J. Ha, A new approach to feedback linearizingcontrol of variable reluctance motors for direct-drive appli-cations, IEEE Transactions on Control Systems Technology,4(4), Jul 1996, 348–362.
  48. [48] S.K. Sahoo, S. Dasgupta, S.K. Panda, and J.-X. Xu, ALyapunov function-based robust direct torque controller for a7switched reluctance motor drive system, IEEE Transactionson Power Electronics, 27(2), Feb 2012, 555–564.
  49. [49] M. Ilic’-Spong, R. Marino, S.M. Peresada, and D. Taylor,‘Feedback linearizing control of switched reluctance motors,IEEE Transactions on Automatic Control, 32(5), May 1987,371–379.
  50. [50] S.K. Panda and P.K. Dash, ‘Application of nonlinear control toswitched reluctance motors: A feedback linearisation approach,IEE Proceedings – Electric Power Applications, 143(5), Sep1996, 371–379.
  51. [51] C. Choi, S. Kim, Y. Kim, and K. Park, A new torque controlmethod of aswitched reluctance motor using a torque-sharingfunction, IEEE Transactions on Magnetics, 38(5), Sep 2002,3288–3290.
  52. [52] N.C. Sahoo, J.X. Xu, and S.K. Panda, Low torque ripplecontrol of switched reluctance motors using iterative learning,IEEE Transactions on Energy Conversion, 16(4), Dec 2001,318–326.
  53. [53] S.K. Sahoo, S.K. Panda, and J.X. Xu, Iterative learning-basedhigh-performance current controller for switched reluctancemotors, IEEE Transactions on Energy Conversion, 19(3), Sep2004, 491–498.
  54. [54] R. Gobbi and K. Ramar, Optimisation techniques for a hys-teresis current controller to minimise torque ripple in switchedreluctance motors, IET Electric Power Applications, 3(5), Sep2009, 453–460.
  55. [55] Z. Lin, D. Reay, B. Williams, and X. He, High-performancecurrent control for switched reluctance motors based on on-lineestimated parameters, IET Electric Power Applications, 4(1),Jan 2010, 67–74.
  56. [56] S. Mir, M.E. Elbuluk, and I. Husain, Torque-ripple mini-mization in switched reluctance motors using adaptive fuzzycontrol, IEEE Transactions on Industrial Applications, 35(2),Mar 1999, 461–468.
  57. [57] P. Veena, R. Jeyabharath, and M. Rajaram, Performanceimprovement of direct torque control for switched reluctancemotor using neuro-fuzzy controller, Mechatronics Systems andControl, 38(3), 2010, 156–163.
  58. [58] S. Masoudi, M.R. Soltanpour, and H. Abdollahi, Adaptivefuzzy control method for a linear switched reluctance motor,IET Electric Power Applications, 12(9), 2018, 1328–1336.
  59. [59] J. Ye, B. Bilgin, and A. Emadi, An extended-speed low-ripple torque control of switched reluctance motor drives,IEEE Transactions on Power Electronics, 30(3), Mar 2015,1457–1470.
  60. [60] S. Xu, H. Chen, J. Yang, and F. Dong, Comparative evaluationon switched reluctance motor drive with different phase currentsensing methods, IET Electric Power Applications, 13(12),2019, 1964–1975, doi: 10.1049/iet-epa.2019.0212.
  61. [61] K.B. Hunasikatti, R.L. Naik, and V.D. Nayak, Critical re-view of control strategies for switched reluctance motor em-ployed in electric vehicle, 2018 second international conferenceon advances in electronics, computers and communications(ICAECC), Bangalore, 2018, 1–6.
  62. [62] Y. Zhu, C. Zhao, J. Zhang, and Z. Gong, Vibration controlfor electric vehicles with in-wheel switched reluctance motordrive system, IEEE Access, 8, 2020, 7205–7216.
  63. [63] S.M. Castano, R. Yang, C. Mak, B. Bilgin, and A. Emadi,External-rotor switched reluctance motor for direct-drive homeappliances, IECON 2018 – 44th annual conference of the IEEEindustrial electronics society, Washington, DC, 2018, 514–521.
  64. [64] P.T. Hieu, D. Lee, and J. Ahn, Design of a high speed 4/2switched reluctance motor for blender application, 2017 IEEEtransportation electrification conference and expo, Asia-Pacific(ITEC), Harbin, 2017, 1–5.
  65. [65] M. Tursini, M. Villani, G. Fabri, L. Di Leonardo, A switched-reluctance motor for aerospace application: Design, analysisand results, Electric Power Systems Research, 142, 2017, 74–83.
  66. [66] M. Asgar, E. Afjei, A. Behbahani, and A. Siadatan, A 12/8double-stator switched reluctance motor for washing machineapplication, 6th power electronics, drive systems & technologiesconference, Tehran, 2015, 168–172.
  67. [67] I. Mahmoud, H. Rehaoulia, and M. Ayadi, Design and mod-elling of a linear switched reluctance actuator for biomedicalapplications, International Journal of Physical Sciences, 22(6),Oct 2011, 5171–5180.
  68. [68] V.S. Murty, S. Jain, and A. Ojha, Application of linearswitched reluctance motor for sustainable electric vehicularsystem, International Journal of Power and Energy Systems,40(1), Jan 2020, 41–48.
  69. [69] D. Wang, D. Zhang, X. Du, and X. Wang, Unitized designmethodology of linear switched reluctance motor with segmen-tal secondary for long rail propulsion application, IEEE Trans-actions on Industrial Electronics, 65(12), Dec 2018, 9884–9894.
  70. [70] J. Tandekar, A. Ojha, S. Das, P. Swarnakar, and S. Jain,SEIG-based renewable power generation and compensationin MVDC ship power system, International Transactions onElectrical Energy Systems, 29(4), Dec 2018, 27–42.

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