© The Institution of Engineering and Technology
This study proposes direct torque and flux control of dual-inverter-fed open-end winding induction motor (OEWIM) with the help of model predictive control. OEWIMs are extensively used in electric vehicles and for ship propulsion but they require a high dynamic performance. Predictive torque control (PTC) retains the features of direct torque control and offers a high dynamic performance by eliminating start-up problems. In this study, predictive torque control is implemented for multilevel inversion-fed OEWIMs. Multilevel inversion is obtained by operating two two-level inverters with equal and unequal DC link voltages. The proposed study gives a comparative analysis of PTC of OEWIM for various speeds and numerical analysis of torque ripple and flux ripple. The proposed methods are simulated using MATLAB/SIMULINK and experimental response shows the validity of the developed methods.
References
-
-
1)
-
31. Wu, D., Wu, X., Su, L.,, et al: ‘A dual three-level inverter based open-end winding induction motor drive with averaged zero-sequence voltage elimination and neutral-point voltage balance’, IEEE Trans. Ind. Electron., 2016, 63, (8), pp. 4783–4795.
-
2)
-
29. Kumar, A., Fernandes, B.G., Chatterjee, K.: ‘Direct torque control of open-end winding induction motor drive using the concept of imaginary switching times for marine propulsion systems’. Proc. Conf. IEEE PESC-04, vol. 2, pp. 1214–1219.
-
3)
-
30. Vinay Kumar, T., Rao, S.S.: ‘Direct torque controlled induction motor drive based on cascaded three two-Level inverters’, Int. J. Modell. Simul., 2014, 34, (2), pp. 70–82.
-
4)
-
22. Dehghani Kiadehi, A., El Khamlichi Drissi, K., Pasquier, C.: ‘Angular modulation of dual-inverter fed open-end motor for electrical vehicle applications’, IEEE Trans. Power Electron., 2016, 31, (4), pp. 2980–2990.
-
5)
-
33. Khairi Rahim, M., Patkar, F., Jidin, A.,, et al: ‘Reduced torque ripple and switching frequency using optimal DTC switching strategy for open-end winding of induction machines’. Proc. Conf. Power Electronics and Drive Systems (PEDS) 2015, 2015, pp. 767–772.
-
6)
-
20. Somasekhar, V.T., Shivakumar, E.G., Gopakumar, K.,, et al: ‘Multi level voltage space phasor generation for an open-end winding induction motor drive using a dual inverter scheme with asymmetrical DC-link voltages’, Eur. Power Electron. Drives J., 2002, 12, (3), pp. 21–29.
-
7)
-
28. Praveen Kumar, K.V., Vinay Kumar, T.: ‘Experimental implementation of direct torque control of open-end winding induction motor’. Proc. Conf. IEEE TENCON-2016, pp. 3318–3323.
-
8)
-
2. Correa, P., Pacas, M., Rodriguez, J.: ‘Predictive torque control for inverter-Fed induction machines’, IEEE Trans. Ind. Electron., 2007, 54, (2), pp. 1073–1079.
-
9)
-
32. Satheesh, G., Brahmananda Reddy, T., Sai babu, C.H..: ‘Four level decoupled SVPWM based direct torque control (DTC) of open end induction motor drive’. Proc. Conf. IEEE APCET-2012, vol. 2, pp. 1–5.
-
10)
-
12. Alireza Davari, S.: ‘Predictive direct angle control of induction motor’, IEEE Trans. Ind. Electron., 2016, 63, (8), pp. 5276–5284.
-
11)
-
18. Habibullah, Md., Dah-Chuan Lu, D.: ‘A speed-Sensorless FS-PTC of induction motors using extended kalman filters’, IEEE Trans. Ind. Electron., 2015, 62, (11), pp. 6765–6778.
-
12)
-
3. Nemec, M., Nedeljkovic, D., Ambrozic, V.: ‘Predictive torque control of induction machines using immediate flux control’, IEEE Trans. Ind. Electron., 2007, 54, (4), pp. 2009–2017.
-
13)
-
9. Zhang, Y., Yang, H.: ‘Model predictive torque control of induction motor drives with optimal duty cycle control’, IEEE Trans. Power Electron., 2014, 29, (12), pp. 6593–6603.
-
14)
-
1. Takahashi, I, Noguchi, T.: ‘A new quick-response and high efficiency control strategy of an induction motor’, IEEE Trans. Ind. Appl., 1986, 22, (5), pp. 820–827.
-
15)
-
8. Karamanakos, P., Stolze, P., Kennel, R.M.,, et al: ‘Variable switching point predictive torque control of induction machines’, IEEE J. Emerg. Selc. Top. Power Electron., 2014, 2, (2), pp. 285–295.
-
16)
-
26. Jain, S., Ramulu, C., Padmanadhan, S.,, et al: ‘Dual MPPT algorithm for dual PV source fed open-end winding induction motor drive for pumping application’, Eng. Sci. Technol. Int. J., 2016, 19, (4), pp. 1771–1780.
-
17)
-
37. Rodriguez, J., Cortes, P.: ‘Predictive control of power converters and electrical drives’ (John Wiley & Sons, Ltd., Chichester, United Kingdom, 2012).
-
18)
-
23. Lu, S., Corzine, K.: ‘Multilevel multi-phase propulsion drives’.Proc. Conf. IEEE Electric Ship Technologies Symposium (ESTS), Philadelphia, PA, July 2005, pp. 363–370.
-
19)
-
19. Habibullah, Md., Dah-Chuan Lu, D., Xiao, D.,, et al: ‘Predictive torque control of induction motor sensor-less drive Fed by a 3L-NPC inverter’, IEEE Trans. Ind. Inf., 2017, 13, (1), pp. 60–70.
-
20)
-
4. Miranda, H., Cortés, P., Yuz, J.I.,, et al: ‘Predictive torque control of induction machines based on state-Space models’, IEEE Trans. Ind. Electron., 2009, 56, (6), pp. 1916–1924.
-
21)
-
27. Venugopal Reddy, B., Somasekhar, V.T., Kalyan, Y.: ‘Decoupled space-vector PWM strategies for a four- level asymmetrical open-End winding induction motor drive with waveform symmetries’, IEEE Trans. Ind. Electron., 2011, 58, (11), pp. 5130–5141.
-
22)
-
35. Buja, G.S., Kazmierkowski, M.P.: ‘Direct torque control of PWM inverter-fed AC motors – a survey’, IEEE Trans. Ind. Electron., 2004, 51, (4), pp. 744–757.
-
23)
-
7. Beerten, J., Verveckken, J., Driesen, J.: ‘Predictive direct torque control for flux and torque ripple reduction’, IEEE Trans. Ind. Electron., 2010, 57, (1), pp. 404–412.
-
24)
-
13. Zhang, Y., Yang, H., Xia, B.: ‘Model-predictive control of induction motor drives: torque control versus flux control’, IEEE Trans. Ind. Appl., 2016, 52, (5), pp. 4050–4060.
-
25)
-
17. Alireza Davari, S., Arab Khaburi, D., Wang, F.,, et al: ‘Using full order and reduced order observers for robust sensorless predictive torque control of induction motors’, IEEE Trans. Power Electron., 2012, 27, (7), pp. 3424–3433.
-
26)
-
5. Geyer, T., Papafotiou, G., Morrari, M.: ‘Model predictive direct torque control—part I: concept, algorithm and analysis’, IEEE Trans. Ind. Electron., 2009, 56, (6), pp. 1894–1905.
-
27)
-
6. Papafotiou, G., Kley, J., Papadopoulos, K.G.,, et al: ‘Model predictive direct torque control—part II: implementation and experimental evaluation’, IEEE Trans. Ind. Electron., 2009, 56, (6), pp. 1906–1915.
-
28)
-
36. Vas, P.: ‘Sensorless vector and direct torque control’ (Oxford University Press, New York, Yokyo, 1998).
-
29)
-
25. Fernao Pires, V., Martins, J.F., Hao, C.: ‘Dual-inverter for grid connected photovoltaic system: modeling and sliding mode control’, Sol. Energy, 2012, 86, (7), pp. 2106–2115.
-
30)
-
15. Vargas, R., Ammann, U., Rodriguez, J.,, et al: ‘Predictive strategy to control common-mode voltage in loads fed by matrix converters’, IEEE Trans. Ind. Electron., 2008, 55, (12), pp. 4372–4380.
-
31)
-
11. Habibullah, Md., Dah-Chuan Lu, D., Fazlur Rahman, Md.: ‘A simplified finite-State predictive direct torque control for induction motor drive’, IEEE Trans. Ind. Electron., 2016, 63, (6), pp. 3964–3975.
-
32)
-
24. Kawabata, Y., Nasu, M., Nomoto, T.,, et al: ‘High-efficiency and low acoustic noise drive system using open winding AC motor and two space-vector modulated inverters’, IEEE Trans. Ind. Electron., 2002, 49, (4), pp. 783–789.
-
33)
-
10. Zhang, Y., Yang, H.: ‘Generalized Two-Vector-Based model-Predictive torque control of induction motor drives’, IEEE Trans. Power Electron., 2015, 30, (7), pp. 3818–3829.
-
34)
-
21. Subotic, I., Bodo, N., Levi, E.,, et al: ‘On-board integrated battery charger for EVs using an asymmetrical nine-phase machine’, IEEE Trans. Ind. Electron., 2015, 62, (5), pp. 3285–3295.
-
35)
-
14. Zhang, Y., Yang, H.: ‘Two-Vector-Based model predictive torque control without weighting factors for induction motor drives’, IEEE Trans. Power Electron., 2016, 31, (2), pp. 1381–1390.
-
36)
-
16. Rodriguez, J., Pontt, J., Silva, C.,, et al: ‘Predictive direct torque control of an induction machine’. Proc. Conf. EPE-PEMC 2004 (Power Electronics and Motion control Conf.), Riga, Lativa, September 2004.
-
37)
-
34. Suresh, L., Nagarjun, S., Somasekhar, V.T.: ‘Improvised SVPWM strategies for an enhanced performance for a four-level open-end winding induction motor drive’, IEEE Trans. Ind. Electron., 2017, 64, (4), pp. 2750–2759.
http://iet.metastore.ingenta.com/content/journals/10.1049/iet-epa.2017.0209
Related content
content/journals/10.1049/iet-epa.2017.0209
pub_keyword,iet_inspecKeyword,pub_concept
6
6