{"title":"Vector Control Using Series Iron Loss Model of Induction, Motors and Power Loss Minimization","authors":"Kheldoun Aissa, Khodja Djalal Eddine","volume":28,"journal":"International Journal of Electrical and Computer Engineering","pagesStart":596,"pagesEnd":603,"ISSN":"1307-6892","URL":"https:\/\/publications.waset.org\/pdf\/8777","abstract":"The iron loss is a source of detuning in vector controlled\r\ninduction motor drives if the classical rotor vector controller is used for\r\ndecoupling. In fact, the field orientation will not be satisfied and the\r\noutput torque will not truck the reference torque mostly used by Loss\r\nModel Controllers (LMCs). In addition, this component of loss, among\r\nothers, may be excessive if the vector controlled induction motor is\r\ndriving light loads. In this paper, the series iron loss model is used to\r\ndevelop a vector controller immune to iron loss effect and then an LMC\r\nto minimize the total power loss using the torque generated by the speed\r\ncontroller.","references":"[1] Abrahamsen F., Blaabjerg F., Pederson J. K., Grabowski P. Z. and\r\nThogersen P., \u00d4\u00c7\u00ffOn the energy optimized control of standard and high\r\nefficiency induction motors in CT and HVAC applications-, IEEE trans. on\r\nindustry applications, vol. 34, No 4, July-August 1998\r\n[2] D.W.Novotny and T.A.Lipo, \u00d4\u00c7\u00ffVector Control and Dynamics of AC Drives-,\r\nClarendon Press, Oxford, UK, 1996.\r\n[3] S. Vaez-Zadeh and F. Hendi, \u00d4\u00c7\u00ffA continuous efficiency optimization\r\ncontroller for induction motor drives-, Energy Conversion and Management\r\n46 (2005) 701-713\r\n[4] Wang J.B., Liaw C.M., \"Indirect field oriented induction drive with fuzzy\r\ndetuning correction and efficiency optimization controls\", IEE Proc. Electr.\r\nPower. Appl., Vol.144 n\u252c\u2591.1, January 1997, pp.37-45.\r\n[5] Sousa G.C.D., Bose B.K., \"Fuzzy logic based on-line efficiency\r\noptimization control of an indirect vector controlled induction motor drive\",\r\nIEEE conference record IAS, pp.1168-1174, 15-19 \/Nov, 1993, Hawai,\r\nUSA.\r\n[6] Lim S. and Nam K., \u00d4\u00c7\u00ffLoss-minimising control scheme for induction\r\nmotors-, IEE Proc.-Electr. Power Appl., Vol. 151, No. 4, pp. 385-397, July\r\n2004\r\n[7] Nam S. W. and Nasir Uddin M., \u00d4\u00c7\u00ffModel-Based Loss Minimization Control\r\nof an Induction Motor Drive- IEEE ISIE 2006, July 9-12, 2006, Montreal,\r\nQuebec, Canada\r\n[8] Matsuse K., Yoshizumi T., Katsuta S., Tanigushi S., \" High - Response\r\nFlux Control of Direct Field Oriented Induction Motor with High Efficiency\r\nTacking Core Loss into Account\", IEEE Trans. on Indus. Appl., Vol.35, No.\r\n1, JAN.\/FEB. 1999, pp.62-69.\r\n[9] Dal Y. Ohm, \u00d4\u00c7\u00ffDynamic Model of Induction Motors for Vector Control-,\r\nDrivetech, Inc., Blacksburg, Virginia, 2000.\r\n[10] Levi E., Boglietti A., and Lazzar M. \u00d4\u00c7\u00ffPerformance Deterioration in Indirect\r\nVector Controlled Induction Motor Drives due to Iron Losses-, IEEE trans.\r\non Indus. Appl., pp. 1312-1318, 1995.\r\n[11] Jinh w. J., Nam K., \u00d4\u00c7\u00ffA Vector Control Scheme for EV Induction Motors\r\nwith Series Iron Loss Model-, IEEE trans. Ind. Electron. Vol. 45, No. 4, pp.\r\n617-624, August 1998.","publisher":"World Academy of Science, Engineering and Technology","index":"Open Science Index 28, 2009"}