Abstract
Bearings prevent damage caused by frictional forces between parts supporting the rotation and they keep rotating shafts in their correct position. However, the continuity of work under harsh conditions leads to inevitable bearing failure. Thus, methods for bearing fault diagnosis (FD) that can predict and categorize fault type, as well as the level of degradation, are increasingly necessary for factories. Owing to the advent of deep neural networks, especially convolutional neural networks (CNNs), intelligent FD methods have achieved significantly higher performance in terms of accuracy. However, in addition to accuracy, the efficiency issue still needs to be weathered in complicated diagnosis scenarios to adapt to real industrial environments. Here, we introduce a method based on multi-output classification, which utilizes the correlated features extracted for bearing compound fault type classification and crack-size classification to serve both aims. Additionally, the synergy of a time–frequency signal processing method and the proposed two-dimensional CNN helped the method perform well under the condition of variable rotational speeds. Monitoring signals of acoustic emission also had advantages for incipient FD. The experimental results indicated that utilizing correlated features in multi-output classification improved both the accuracy and efficiency of multi-task diagnosis compared to conventional CNN-based multiclass classification.
Highlights
Electric machines have been widely used and play an undeniable role in industrial applications, as well as in machinery serving life
After providing an overview of the proposed method, we clarify the characteristics of the signal processing technique used, and the terms related to multi-output classification in fault diagnosis (FD)
We show and discuss the results obtained from the experiments
Summary
Electric machines have been widely used and play an undeniable role in industrial applications, as well as in machinery serving life. Based on some surveys of the IEEE Industry Application Society and other related organizations, bearings account for approximately 40% of machine fault causes [1]. This has caused alarm and heightened the need to develop bearing fault diagnosis (FD) methods that will prevent unwanted incidents and ensure the reliability and safety of sophisticated systems. Industrial companies increasingly seem to find FD an essential task to keep track of desirable performance during the production processes. Most industrial companies desire to improve their performance by enhancing their capability to handle faults. The level of a smart factory depends on its ability to utilize information from the data
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