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access icon free Predictive torque control of open-end winding induction motor drive fed with multilevel inversion using two two-level inverters

© The Institution of Engineering and Technology
Received 26/04/2017, Accepted 02/08/2017, Revised 17/07/2017, Published 04/08/2017

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.

Inspec keywords: machine control; torque control; invertors; predictive control; induction motor drives

Other keywords: unequal DC link voltages; dual-inverter-fed open-end winding induction motor; multilevel inversion; multilevel inversion-fed OEWIM; two-level inverters; start-up problem; ship propulsion; numerical analysis; PTC; torque ripple; flux ripple; flux control; electric vehicles; model predictive control; direct torque control; predictive torque control; Matlab-Simulink; equal DC link voltages; open-end winding induction motor drive

Subjects: Power electronics, supply and supervisory circuits; Mechanical variables control; Drives; Asynchronous machines; DC-AC power convertors (invertors); Control of electric power systems; Optimal control

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