Electrical Motor Fault Detection System using AI's Random Forest Classifier Technique

Electrical Motor Fault Detection System using AI's Random Forest Classifier Technique

Induction motors are very commonly used to create traction for electric vehicles. In electric vehicles and other rotating machine systems, faults develop during regular operation, which, if unaddressed, can accelerate the damage to machines. Therefore, early detection and prediction of faults hold t...

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Bibliographic Details
Published in:2023 IEEE International Conference on Advanced Systems and Emergent Technologies (IC_ASET) pp. 1 - 5
Main Authors: Yaqub, Raziq, Ali, Hassan, Bin Abd Wahab, Mohd Helmy
Format: Conference Proceeding
Language:English
Published: IEEE 29-04-2023
Subjects:
Artificial intelligence
Electric vehicles
Fans
fault detection
fault prediction
faults
induction motor
Induction motors
predictive maintenance
preventive maintenance
random forest classifier
rotating machines
Sensors
Traction motors
vibration frequencies
Vibrations
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Summary:Induction motors are very commonly used to create traction for electric vehicles. In electric vehicles and other rotating machine systems, faults develop during regular operation, which, if unaddressed, can accelerate the damage to machines. Therefore, early detection and prediction of faults hold the key importance in predictive and preventive maintenance. This work focuses on collecting sounds and vibrations data of an electric motor, which are the critical indicators of fault initiation in electric vehicle systems. We use artificial intelligence (AI) to predict and classify the types of faults associated with different vibration frequencies and sound levels. We explore random forest classifier technique for faults prediction and derive promising results for different fault conditions. Results show that we correctly predicted and classified different types of manually induced faults associated with different vibration frequencies and sound levels with a 92% accuracy and 86 to 91 % precision level.
DOI:10.1109/IC_ASET58101.2023.10150924