Fault Resistance and Adaptive Analysis of Induction Motors under Voltage Variations in Industrial Applications

The resilience of three-phase induction motors under fault conditions is critical for the stability and reliability of power systems, especially in industrial and commercial settings where voltage disturbances are common. Induction motors are highly susceptible to under-voltage faults caused by grid instability, load imbalances, or transient faults, which can lead to severe operational issues, reduced motor life, and potential system failures if not properly managed. Understanding how induction motors respond to varying levels of under-voltage disturbances provides essential insights into their adaptive limits and helps identify the thresholds at which protective measures become necessary. This research underscores the importance of integrating advanced fault tolerance designs and adaptive mechanisms to improve system reliability in voltage-sensitive industrial applications. The specification of induction motor used in this analysis are, 7.5Kw rated power, line voltage of 400 volts, and rated speed of 1440 RPM. MATLAB/Simulink simulations software were utilized for this analytical investigation, induction motors were subjected to controlled under-voltage variations applied to single-phase and three-phase systems. The study specifically analyzed the rotor speed, electromagnetic torque, and stator current to evaluate how the motors adapted to faults and how these parameters behaved during fault recovery. Faults were simulated with voltage reductions of 20, 40, and 60%, examining both motor resilience and system recovery upon fault clearance. The findings revealed that at moderate under-voltage levels (20% and 40%), the induction motors adapted effectively by increasing current to maintain adequate performance, with system parameters returning to normal post-fault. However, under extreme 60% under-voltage conditions, the motors experienced significant current surges, causing thermal stress and a failure to return to nominal operating conditions after fault clearance, highlighting the motor’s adaptive limit under severe fault scenarios. Additionally, Ohm’s law analysis demonstrated how voltage drops and compensatory current increases temporarily reduced effective resistance, facilitating fault resilience under moderate conditions was also analyzed. The study shows that, as the voltage reduce, current increase which cause the resistance to reduce. This study provides insight into the adaptive limits of induction motors in power systems, offering guidelines for implementing effective protection mechanisms in power networks prone to voltage instabilities. The results support improved fault management strategies and motor protection in industrial applications, particularly under varying fault conditions.