Optimized Switching PWM Technique With Common-Mode Current Minimization for Five-Phase Open-End Winding Induction Motor Drives

Abstract

This paper presents a novel approach to derive a pulsewidth modulation (PWM) technique for the generalized multi-phase drive. This novel approach is called a phase traversing principle. The given phase traversing principle is applied to the proposed PWM technique for five-phase open-end winding induction motor drive fed from a single dc source. The proposed PWM technique has the benefits of phase clamping, symmetrical operation of inverters, and common-mode current (CMC) elimination. Thus, it reduces the switching losses and also minimizes the issue of the CMC. The symmetrical operation of dual inverters further helps in the even distribution of losses. Also, the proposed PWM technique gives a good harmonic performance. The performance of the proposed PWM technique is analyzed using the switching loss function and harmonic flux trajectory methods. The first analysis gives justification of the reduced switching losses. While the second analysis gives the deviations in the motor flux with respect to variation in. modulation indices The proposed PWM technique is verified with both simulation and hardware results.