PERFORMANCE ENHANCEMENT OF SIX-PHASE INDUCTION MOTOR DRIVES USING ADVANCED CONTROL METHODS

In order to make six-phase induction motor drives more dependable, efficient, and load-responsive than three-phase systems, this work employs sophisticated control techniques. The inherent benefits of six-phase induction motors include reduced torque ripple, harmonic distortion, fault tolerance, and power density. For these sensors to function, contemporary control systems are required. This study investigates the potential benefits of fuzzy logic, vector control, model predictive control, and direct torque control (DTC) for enhancing motor performance under different conditions. The recommended adjustments minimize losses, boost power stability, and enhance performance even in the event of a break or imbalance. Six-phase induction motor drives are effective in high-performance industries. Significant gains in torque responsiveness, speed control, and system durability are shown by simulation and experiment findings.