Abstract
Traditional intelligent fault diagnosis methods focus on distinguishing different fault modes, but ignore the deterioration of fault severity. This paper proposes a new two-stage hierarchical convolutional neural network for fault diagnosis of rotating machinery bearings. The failure mode and failure severity are modeled as a hierarchical structure. First, the original vibration signal is transformed into an energy spectrum matrix containing fault-related information through wavelet packet decomposition. Secondly, in the model training method, an adaptive learning rate dynamic adjustment strategy is further proposed, which adaptively extracts robust features from the spectrum matrix for fault mode and severity diagnosis. To verify the effectiveness of the method, the bearing fault data was collected using a rotating machine test bench. On this basis, the diagnostic accuracy, convergence performance and robustness of the model under different signal-to-noise ratios and variable load environments are evaluated, and the feature learning ability of the method is verified by visual analysis. Experimental results show that this method has achieved satisfactory results in both fault pattern recognition and fault severity evaluation, and is superior to other machine learning and deep learning methods.
Highlights
Rotating machinery is the most critical component in the mechanical system and is widely used in heavy machinery, automobile manufacturing, shipbuilding and other industries
adaptive hierarchical deep convolutional model (A-HDCNN) model, at the the same same time, time, In order to verify the superiority of model, at the performance difference between model after learning the performance difference between HDCNN and A-HDCNN model after learning rate rate adaptive
All the samples in the healthy state are used in the first layer failure mode determination layer, and a total of 1000 samples are used for training (500 samples) and testing (500 samples)
Summary
Rotating machinery is the most critical component in the mechanical system and is widely used in heavy machinery, automobile manufacturing, shipbuilding and other industries. Bearing failure is considered to be the most common cause of failure in rotating machinery. The failure of rolling bearings will affect the normal operation of the machine, causing huge economic losses and even casualties. Effective and feasible fault diagnosis technology is of great significance for avoiding dangerous accidents in modern industry and improving the safety and reliability of equipment operation. People have proposed many fault diagnosis methods for rolling bearings based on vibration signal analysis [1,2,3,4]. With the rapid development of machine learning technology, intelligent fault diagnosis methods have become a research hotspot in the field of fault diagnosis. More and more intelligent fault diagnosis methods have been proposed, such as artificial neural networks and support vector machines [5,6]
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