Bearing fault diagnosis method based on improved deep residual Siamese neural network

Insight - Non-Destructive Testing and Condition Monitoring Pub Date : 2024-03-01 DOI:10.1784/insi.2024.66.3.174

Chen Qian, Jun Gao, Xing Shao, Cui-Xiang Wang, Jianhua Yuan

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Abstract

Aiming to address the problem that faults in rolling bearings make effective fault diagnosis difficult under small-sample and varying working conditions, this paper proposes a new fault diagnosis method for rolling bearings that monitors their vibration signals and is based on an improved deep residual Siamese neural network, called a WDRCNN. Firstly, the Siamese neural network is applied to extract features with shared weights to achieve an expansion in the number of fault samples. Then, multiple residual blocks are used to extract deeper feature information and effectively alleviate the problem of overfitting. In addition, the attention mechanism is employed to assign weights to the feature information to reduce the interference of redundant features. Finally, the Euclidean distance between the sample pairs is calculated to determine the similarity of the sample pairs and to classify bearing faults for end-to-end bearing fault diagnosis. The experimental results demonstrate that the WDRCNN achieves an average accuracy of 96.31% under different operating conditions. Even when only 90 training samples are available, the WDRCNN achieves an accuracy of over 93%.

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基于改进型深度残差连体神经网络的轴承故障诊断方法

针对滚动轴承故障在小样本和多变工况条件下难以进行有效故障诊断的问题，本文提出了一种新的滚动轴承故障诊断方法，该方法以改进的深度残差暹罗神经网络（WDRCNN）为基础，监测滚动轴承的振动信号。首先，应用连体神经网络提取具有共享权重的特征，以实现故障样本数量的扩展。然后，利用多个残差块提取更深层次的特征信息，有效缓解了过拟合问题。此外，采用注意力机制为特征信息分配权重，以减少冗余特征的干扰。最后，通过计算样本对之间的欧氏距离来确定样本对的相似度，并对轴承故障进行分类，从而实现端到端轴承故障诊断。实验结果表明，在不同的工作条件下，WDRCNN 的平均准确率达到 96.31%。即使只有 90 个训练样本，WDRCNN 的准确率也超过了 93%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Insight - Non-Destructive Testing and Condition Monitoring

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