Fault diagnosis strategy of a wind power bearing based on an improved convolutional neural network

被引：0

作者：

Chang M. ^{[1
]}

Shen Y. ^{[1
]}

机构：

[1] Engineering Research Center of Internet of Things Technology Applications of Ministry of Education, Jiangnan University, Wuxi

来源：

Dianli Xitong Baohu yu Kongzhi/Power System Protection and Control | 2021年 / 49卷 / 06期

基金：

中国国家自然科学基金;

关键词：

Convolution neural network; Deep learning; Fault diagnosis; Gear case; Rolling bearing; Wind power;

D O I：

10.19783/j.cnki.pspc.200585

中图分类号：

学科分类号：

摘要：

The rolling bearing of a wind turbine has problems of weak fault characteristics, difficult extraction and low diagnosis efficiency. To solve these problems we propose a fault diagnosis algorithm based on an improved Convolution Neural Network (CNN). The structure of the CNN model is improved, a new convolution layer is added in front of the full connection layer, the deep features of the signal are excavated to improve the generalization ability of the model, the convolution layer data are standardized, and the stochastic gradient descent with momentum is used to speed up the training speed. The working principle of the improved CNN is introduced in detail, and the flow chart of fault diagnosis with improved CNN is given. Finally, the data of a rolling bearing database at Case Western Reserve University is used to verify the method, and proves that this method does not need to extract the fault features of the signal in advance, and can directly achieve fault feature extraction and fault identification of bearings, and the diagnosis rate is high. © 2021 Power System Protection and Control Press.

引用

页码：131 / 137

页数：6

共 23 条

[1] YAO Zhiqing, ZHANG Qun, CHEN Peng, Et al., Research on fault diagnosis for MMC-HVDC systems, Protection and Control of Modern Power Systems, 1, 1, pp. 71-77, (2016)
[2] KOCHMANN J, MANJUNATHA K, GIERDEN C, Et al., A simple and flexible model order reduction method for FFT-based homogenization problems using a sparse sampling technique, Computer Methods in Applied Mechanics & Engineering, 347, pp. 622-638, (2018)
[3] SEBASTIAN P, DSA P A., Implementation of a power quality signal classification system using wavelet based energy distribution and neural network, 2015 International Conference on Power & Advanced Control Engineering (ICPACE), pp. 157-161, (2015)
[4] MUHAMMET U, MUSTAFA O, MUSTAFA D, Et al., Fault diagnosis of rolling bearings using a genetic algorithm optimized neural network, Measurement, 58, pp. 187-196, (2014)
[5] KUMAR A., Bearing fault diagnosis based on vibration signature analysis using discrete wavelet transform, International Journal of Engineering and Technical Research, 3, 8, pp. 1258-1261, (2014)
[6] VONG C M, WONG P K., Engine ignition signal diagnosis with wavelet packet transform and multi-class least squares support vector machines, Expert Systems with Applications, 38, 7, pp. 8563-8570, (2011)
[7] LU Jinling, SHENG Feifei, ZHAO Hongshan, Fault diagnosis method of main bearing main bearing based on limit learning machine, Renewable Energy, 34, 11, pp. 1588-1594, (2016)
[8] GUO Yanping, YAN Wenjun, BAO Zhejing, Et al., Fault diagnosis method of wind turbine rolling bearing based on empirical modal decomposition and divergence index, Power System Protection and Control, 40, 17, pp. 83-87, (2012)
[9] BUXTON B, GOLDSTON D, DOCTOROW C, Et al., Big data: science in the petabyte era, Nature, 455, pp. 8-9, (2008)
[10] ZHOU Feiyan, JIN Linpeng, DONG Jun, Research on convolutional neural network, Journal of Computer Science, 40, 6, pp. 1229-1251, (2017)

← 1 2 3 →