Abstract
Considering various fault states under severe working conditions, the comprehensive feature extraction from the raw vibration signal is still a challenge for the diagnosis task of rolling bearing. To deal with strong coupling and high nonlinearity of the vibration signal, this article proposes a novel multilocation and multikernel scale learning framework based on deep convolution encoder (DCE) and bidirectional long short-term memory network (BiLSTM). The procedure of the proposed method using a cascade structure is developed in three stages. In the first stage, each parallel branch of the multifeature learning combines the skip connection and the DCE, and uses different size kernels. The multifeature learning network can automatically extract and fuse global and local features from different network depths and time scales of the raw vibration signal. In the second stage, the BiLSTM as the feature protection network is designed to employ the internal calculating data of the forward propagation and backward propagation at the same network propagation node. The feature protection network is used for further mining sensitive and complementary features. In the third stage of bearing diagnosis, the classifier identifies the fault types. Consequently, the proposed network scheme can perform well in generalization capability. The performance of the proposed method is verified on the two kinds of bearing datasets. The diagnostic results demonstrate that the proposed method can diagnose multiple fault types more accurately. Also, the method performs better in load and speed adaptation compared with other intelligent fault classification methods.
Highlights
The purpose of this article is to design an end-to-end bearing fault diagnosis system based on a deep convolutional encoder (DCE) and bidirectional long and short-term memory neural network (LSTM) (BiLSTM)
Combining the skip connection and multiple kernel branches, we propose a strong network scheme of fault diagnosis with multilocation and multikernel scale learning defined as the generalized multiscale learning (GMSL)
The purpose of the fault diagnosis system is to obtain high-purity discriminative features, so we only introduce the encoder to the fault diagnosis system
Summary
Rolling bearings are widely used as indispensable components in modern mechanical equipment. The rolling bearings usually work under the severe conditions of varying speed, heavy load, variable load, and high temperature for a long time. They are vulnerable to occur deformation, abrasive wear, or other faults. These faults may lead to equipment performance degradation and even lead to severe economic loss [1]. It is critically important to develop a system that can accurately diagnose various bearing faults under complex operating conditions and working environments
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