Convolutional Neural Networks for Automated Rolling Bearing Diagnostics in Induction Motors Based on Electromagnetic Signals

Bearing faults account for over 40% of induction motor faults, and for this reason, for several decades, much attention has been paid to their condition monitoring, through vibration measurements and, more recently, through electromagnetic signal analysis. Furthermore, in the last few years, researc...

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Bibliographic Details
Published in:Applied sciences 2021-09, Vol.11 (17), p.7878
Main Authors: Minervini, Marcello, Mognaschi, Maria Evelina, Di Barba, Paolo, Frosini, Lucia
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Anomalies
Automation
bearing fault
Bearings
Classification
convolutional neural network
Datasets
Decision making
Deep learning
diagnostics
Electromagnetic induction
electromagnetic signal
Fault detection
Fault diagnosis
induction motor
Induction motors
Laboratories
Learning algorithms
Neural networks
Point defects
Power supply
Principal components analysis
Roller bearings
Sensors
Signal analysis
Spectrograms
Transfer learning
Vibration
Vibration analysis
Vibration measurement
Vibration monitoring
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Summary:Bearing faults account for over 40% of induction motor faults, and for this reason, for several decades, much attention has been paid to their condition monitoring, through vibration measurements and, more recently, through electromagnetic signal analysis. Furthermore, in the last few years, research has been focused on evaluating deep learning algorithms for the automatic diagnosis of these faults. Therefore, the purpose of this study is to propose a novel procedure to automatically diagnose different types of bearing faults and load anomalies by means of the stator current and the external stray flux measured on the induction motor in which the bearings are installed. All the data were collected by performing experimental tests in the laboratory. Then, these data were processed to obtain images (scalograms and spectrograms), which were elaborated by a pre-trained Deep Convolutional Neural Network, modified through the transfer learning technique. The results demonstrated the ability of the electromagnetic signals, and in particular of the stray flux, to detect bearing faults and mechanical anomalies, in agreement with the recent literature. Moreover, the Convolutional Neural Network has been proven to be able to automatically discriminate bearing defects and with respect to the healthy condition.
ISSN:2076-3417
2076-3417
DOI:10.3390/app11177878