Frontiers in Energy >

2012 , Vol. 6 >Issue 2: 129 - 137

DOI: https://doi.org/10.1007/s11708-012-0183-0

RESEARCH ARTICLE

Direct field oriented control scheme for space vector modulated AC/DC/AC converter fed induction motor

  • F. BENCHABANE , 1 ,
  • A. TITAOUINE 1 ,
  • O. BENNIS 2 ,
  • K. YAHIA 1 ,
  • D. TAIBI 1
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  • 1. MSE Laboratory, Department of Electrical Engineering, University of Biskra, BP 145 Biskra, Algeria
  • 2. PRISME Institut, University of Orléans, 21 rue Loigny La Bataille, 28000 Chartres, France

Received date: 05 Dec 2011

Accepted date: 14 Feb 2012

Published date: 05 Jun 2012

Copyright

2014 Higher Education Press and Springer-Verlag Berlin Heidelberg
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Abstract

This paper investigates a Luenberger flux observer with speed adaptation for a direct field oriented control of an induction motor. An improved method of speed estimation that operates on the principle of speed adaptive flux and current observer has been proposed. An observer is basically an estimator that uses a plant model and a feedback loop with measured stator voltage and current. Simulation results show that the proposed direct field oriented control with the proposed observer provides good performance dynamic characteristics. The induction motor is fed by an indirect power electronics converter. This indirect converter is controlled by a sliding mode technique that enables minimization of harmonics introduced by the line converter, as well as the control of the power factor and DC-link voltage. The robustness of the overall system is studied using simulation for different operating modes and varied parameters.

Key words: induction motor; direct filed oriented control; Luenberger observer; estimation; space vector modulation (SVM); sliding mode control; boost-rectifier

Cite this article

F. BENCHABANE , A. TITAOUINE , O. BENNIS , K. YAHIA , D. TAIBI . Direct field oriented control scheme for space vector modulated AC/DC/AC converter fed induction motor[J]. Frontiers in Energy, 2012 , 6(2) : 129 -137 . DOI: 10.1007/s11708-012-0183-0

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