Journal of Engineering Research and Reports

Protecting an induction motor from faults is essential to ensure its reliable operation, extend its lifespan, and safeguard the overall electrical system. This paper presents a comprehensive analysis and protection strategy for a 7.5 kW, 400 V, 50 Hz, 1440 RPM, three-phase squirrel-cage induction motor under various fault conditions using MATLAB/Simulink. The faults considered include normal case (without fault), single line-to-ground fault (L-G), double line-to-ground fault (L-L-G), three line-to-ground fault (L-L-L-G), and line-to-line fault (L-L). The simulation runs for a total duration of 2 seconds, with the motor operating under normal conditions from 0 to 0.6 seconds. Faults are applied between 0.6 and 2 seconds, during which an intelligent overcurrent relay is incorporated to detect the fault and trip the motor at 1.4 seconds.

The results reveal distinct behaviors of the induction motor during normal and fault conditions, characterized by variations in rotor speed, electromagnetic torque, and stator currents. Under normal operation, the motor operates at steady-state conditions with balanced stator currents, constant torque, and rotor speed close to the synchronous value. However, during fault conditions, significant disruptions are observed. Single line-to-ground faults cause moderate unbalances, while double line-to-ground faults and line-to-line faults induce higher levels of stator current surges and torque oscillations. Three line-to-ground faults present the most severe case, leading to rapid torque drops, rotor deceleration, and excessive current surges in all phases.

The intelligent overcurrent relay demonstrates its effectiveness by detecting abnormal current levels across all fault scenarios and successfully isolating the motor at 1.4 seconds, mitigating potential damage. This study highlights the critical role of intelligent protection devices in enhancing the reliability and operational safety of induction motors under fault conditions. The MATLAB/Simulink simulation software proves to be an effective tool for modeling, analyzing, and validating the performance of the motor and protection system.

This work provides valuable insights into fault dynamics in three-phase induction motors and underscores the importance of implementing intelligent relay-based protection schemes for improved fault mitigation and motor reliability.