深度子领域自适应网络电机滚动轴承跨工况故障诊断

doi:10.19595/j.cnki.1000-6753.tces.221854

摘要
图/表
参考文献
相关文章 (6)

全文: PDF (14395 KB) HTML
输出: BibTeX | EndNote (RIS)

摘要针对实际生产中旋转机械工况变化引起状态监测数据分布差异及获取待诊断样本标签困难问题,提出多尺度子领域自适应模型（MSDAM）的跨工况下滚动轴承故障诊断方法。首先,以原始振动信号作为输入,无需信号预处理及人工特征参数提取;其次,搭建多尺度卷积神经网络将已知标签样本和待诊断样本特征迁移到同一子空间,捕获具有细粒度信息的多尺度公共特征;然后,以不同的故障类型来划分相关子域,并通过局部最大均值距离（LMMD）来完成子域的适配,有效削弱不同工况同类故障特征的分布差异;最后,在三个数据集的多个迁移任务上进行试验验证。结果证明,所提MSDAM的跨工况故障诊断性能优于关注全局领域适配的迁移学习方法。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	宋向金
	孙文举
	刘国海
	赵文祥
	王照伟

关键词 ：轴承故障诊断, 子领域自适应, 迁移学习, 软标签学习

Abstract：In real-world industrial scenarios, due to variations in working conditions, the vibration data gathered from mechanical equipment presents different probability distributions. Moreover, the gathered vibration data is usually unlabeled. Therefore, the unlabeled vibration data may be misclassified by the trained diagnostic source models. Deep transfer learning with the adaptation of marginal or conditional distribution can extend the knowledge of the trained models in source domains to a novel but it is related to a target domains. However, the only reduction in marginal distribution discrepancy limits the generalization ability and performance of the diagnostic model. Besides, the most effective diagnostic model that matches both marginal and conditional distributions fail to take full advantage of complex and sensitive features in the data set. To address these issues, a multiscale subdomain adaptive model (MSDAM) for rolling bearings fault diagnosis under cross-working conditions is proposed.
Firstly, in order to eliminate signal pre-processing and manual feature extraction dependencies, the original vibration signal is used as the input of the proposed MSDAM. Secondly, a multiscale convolutional neural network is built to capture multiscale common features with fine-grained information and transfer the features of labeled source data and unlabeled target data to the same subspace. Then, the prediction results of the source classifier are used as the soft labels for the unlabeled target data, and the relevant subdomains are divided according to different fault types. Finally,the local maximum mean distance (LMMD) method is employed to align the conditional distributions of the subdomains in the common feature space to effectively reduce the distribution discrepancy of similar fault characteristics under different working conditions.
The location selection experiment of the subdomain adaptation layer shows that the subdomain adaptation layer is set before the classification layer, which can better guide the optimization of the entire network and maintain feature distribution matching. The results on the Paderborn bearing dataset show that the average diagnostic accuracy of the multiscale model is improved by 7.98% compared to the single-scale model. Despite sacrificing extra training time, the proposed MSDAM has stronger transfer ability. To further verify the effectiveness of the proposed MSDAM, a total of 12 transfer learning tasks are carried out on the CWRU bearing dataset, Paderborn bearing dataset, and laboratory-built datasets respectively. The experimental results indicate that the proposed MSDAM has higher accuracy in fault diagnosis across working conditions than the deep adaptation methods such as domain adaptive networks(DAN) and domain-adversarial neural networks (DANN). In addition, t-SNE visualization of the subdomain adaptation layer representations indicates that the proposed MSDAM can accurately align the relevant subdomain distributions.
The following conclusions can be drawn through the analysis of experimental results: (1) The proposed MSDAM can extract more fine-grained common fault features and align relevant subdomains based on LMMD compared with DAN and DANN. (2) The proposed MSDAM only requires the original vibration signal as input, eliminating the need for signal preprocessing and manual feature extraction. (3) A high cross domain diagnostic accuracy on all three datasets proves the strong generalization ability of the proposed MSDAM.

Key words： Bearing fault diagnosis subdomain adaptation transfer learning soft label learning

收稿日期: 2022-09-30

PACS:

TM307

基金资助:国家自然科学基金青年科学基金（52007078, 62002140）、江苏省自然科学基金（BK20200887）和江苏省“双创”项目资助

通讯作者: 宋向金女,1989年生,博士,讲师,硕士生导师,研究方向为交流电机状态监测与故障诊断。E-mail：songxiangjin@ujs.edu.cn

作者简介: 孙文举男,1998年生,硕士研究生,研究方向为旋转机械设备故障诊断。E-mail：2222107041@stmail.ujs.edu.cn

引用本文:

宋向金, 孙文举, 刘国海, 赵文祥, 王照伟. 深度子领域自适应网络电机滚动轴承跨工况故障诊断[J]. 电工技术学报, 2024, 39(1): 182-193. Song Xiangjin, SunWenju, LiuGuohai, ZhaoWenxiang, Wang Zhaowei. Across Working Conditions Fault Diagnosis for Motor Rolling Bearing Based on Deep Subdomain Adaption Network. Transactions of China Electrotechnical Society, 2024, 39(1): 182-193.

链接本文:

https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.221854 https://dgjsxb.ces-transaction.com/CN/Y2024/V39/I1/182

[1] 宋向金, 赵文祥. 交流电机信号特征分析的滚动轴承故障诊断方法综述[J]. 中国电机工程学报, 2022, 42(4): 1582-1595.
Song Xiangjin, Zhao Wenxiang.A review of rolling bearing fault diagnosis approaches using AC motor signature analysis[J]. Proceedings of the CSEE, 2022, 42(4): 1582-1595.
[2] Liu Chenyu, He Deqiang, Chen Yanjun, et al.Rolling bearing fault diagnosis of train running gear based on optimized deep residual network[C]//2021 5th International Conference on Automation, Control and Robots (ICACR), Nanning, China, 2021: 168-172.
[3] 李兵, 梁舒奇, 单万宁, 等. 基于改进正余弦算法优化堆叠降噪自动编码器的电机轴承故障诊断[J]. 电工技术学报, 2022, 37(16): 4084-4093.
Li Bing, Liang Shuqi, Shan Wanning, et al.Motor bearing fault diagnosis based on improved sine and cosine algorithm for stacked denoising autoencoders[J]. Transactions of China Electrotechnical Society, 2022, 37(16): 4084-4093.
[4] Gao Shuzhi, Pei Zhiming, Zhang Yimin, et al.Bearing fault diagnosis based on adaptive convolutional neural network with nesterov momentum[J]. IEEE Sensors Journal, 2021, 21(7): 9268-9276.
[5] 陈剑, 杜文娟, 王海风. 基于对抗式迁移学习的含柔性高压直流输电的风电系统次同步振荡源定位[J]. 电工技术学报, 2021, 36(22): 4703-4715.
Chen Jian, Du Wenjuan, Wang Haifeng.Location method of subsynchronous oscillation source in wind power system with VSC-HVDC based on adversarial transfer learning[J]. Transactions of China Electrotechnical Society, 2021, 36(22): 4703-4715.
[6] 王艳新, 闫静, 王建华, 等. 基于域对抗迁移卷积神经网络的小样本GIS绝缘缺陷智能诊断方法[J]. 电工技术学报, 2022, 37(9): 2150-2160.
Wang Yanxin, Yan Jing, Wang Jianhua, et al.Intelligent diagnosis for GIS with small samples using a novel adversarial transfer learning in convolutional neural network[J]. Transactions of China Electrote-chnical Society, 2022, 37(9): 2150-2160.
[7] 臧海祥, 郭镜玮, 黄蔓云, 等. 基于深度迁移学习的时变拓扑下电力系统状态估计[J]. 电力系统自动化, 2021, 45(24): 49-56.
Zang Haixiang, Guo Jingwei, Huang Manyun, et al.State estimation for power systems with time-varying topology based on deep transfer learning[J]. Automation of Electric Power Systems, 2021, 45(24): 49-56.
[8] Chen Zhuyun, He Guolin, Li Jipu, et al.Domain adversarial transfer network for cross-domain fault diagnosis of rotary machinery[J]. IEEE Transactions on Instrumentation and Measurement, 2020, 69(11): 8702-8712.
[9] Zhou Yuxuan, Dong Yining, Zhou Hongkuan, et al.Deep dynamic adaptive transfer network for rolling bearing fault diagnosis with considering cross-machine instance[J]. IEEE Transactions on Instru-mentation and Measurement, 2021, 70: 1-11.
[10] 袁壮, 董瑞, 张来斌, 等. 深度领域自适应及其在跨工况故障诊断中的应用[J]. 振动与冲击, 2020, 39(12): 281-288.
Yuan Zhuang, Dong Rui, Zhang Laibin, et al.Deep domain adaptation and its application in fault diagnosis across working conditions[J]. Journal of Vibration and Shock, 2020, 39(12): 281-288.
[11] Lou Yunxia, Kumar A, Xiang Jiawei.Machinery fault diagnosis based on domain adaptation to bridge the gap between simulation and measured signals[J]. IEEE Transactions on Instrumentation and Measurement, 2022, 71: 1-9.
[12] Li Tianfu, Zhao Zhibin, Sun Chuang, et al.Domain adversarial graph convolutional network for fault diagnosis under variable working conditions[J]. IEEE Transactions on Instrumentation and Measurement, 2021, 70: 1-10.
[13] Wan Lanjun, Li Yuanyuan, Chen Keyu, et al.A novel deep convolution multi-adversarial domain adaptation model for rolling bearing fault diagnosis[J]. Measurement, 2022, 191: 110752.
[14] 董绍江, 朱朋, 裴雪武, 等. 基于子领域自适应的变工况下滚动轴承故障诊断[J]. 吉林大学学报(工学版), 2022, 52(2): 288-295.
Dong Shaojiang, Zhu Peng, Pei Xuewu, et al.Fault diagnosis of rolling bearing under variable operating conditions based on subdomain adaptation[J]. Journal of Jilin University (Engineering and Technology Edition), 2022, 52(2): 288-295.
[15] 陈仁祥, 唐林林, 孙健, 等. 一维深度子领域适配的不同转速下旋转机械复合故障诊断[J]. 仪器仪表学报, 2021, 42(5): 227-234.
Chen Renxiang, Tang Linlin, Sun Jian, et al.Composite fault diagnosis of rotating machinery under different speed based on one dimensional deep subdomain adaption[J]. Chinese Journal of Scientific Instrument, 2021, 42(5): 227-234.
[16] Gretton A, Borgwardt K M, Rasch M J, et al.A kernel two-sample test[J]. The Journal of Machine Learning Research, 2012, 13(1): 723-773.
[17] 卢志刚, 杨英杰, 李学平, 等. 基于深度迁移学习理论含风电光伏系统的地区电网网损率计算[J]. 中国电机工程学报, 2020, 40(13): 4102-4110.
Lu Zhigang, Yang Yingjie, Li Xueping, et al.A deep migration learning based power loss rate calculation method for distributed power system with wind and solar generation[J]. Proceedings of the CSEE, 2020, 40(13): 4102-4110.
[18] Long Mingsheng, Wang Jianmin. Learning transferable features with deep adaptation networks[EB/OL].2015: arXiv: 1502.02791. https://arxiv.org/abs/1502.02791.
[19] Long M, Zhu H, Wang J, et al.Deep transfer learning with joint adaptation networks[C]//International Conference On Machine Learning, PMLR, 2017: 2208-2217.
[20] Tzeng E, Hoffman J, Zhang Ning, et al. Deep domain confusion: maximizing for domain invariance[EB/OL].2014: arXiv: 1412.3474. https://arxiv.org/abs/1412. 3474.
[21] 徐奇伟, 黄宏, 张雪锋, 等. 基于改进区域全卷积网络的高压引线接头红外图像特征分析的在线故障诊断方法[J]. 电工技术学报, 2021, 36(7): 1380-1388.
Xu Qiwei, Huang Hong, Zhang Xuefeng, et al.Online fault diagnosis method for infrared image feature analysis of high-voltage lead connectors based on improved R-FCN[J]. Transactions of China Electro-technical Society, 2021, 36(7) : 1380-1388.
[22] 郑含博, 李金恒, 刘洋, 等. 基于改进YOLOv3的电力设备红外目标检测模型[J]. 电工技术学报, 2021, 36(7): 1389-1398.
Zheng Hanbo, Li Jinheng, Liu Yang, et al.Infrared object detection model for power equipment based on improved YOLOv3[J]. Transactions of China Electrotechnical Society, 2021, 36(7): 1389-1398.
[23] He Kaiming, Sun Jian.Convolutional neural networks at constrained time cost[C]//2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR), Boston, MA, USA, 2015: 5353-5360.
[24] Barakat A, Bianchi P. Convergence and dynamical behavior of the ADAM algorithm for non-convex stochastic optimization[EB/OL].2018: arXiv: 1810. 02263. https://arxiv.org/abs/1810.02263.
[25] Smith W A, Randall R B. Rolling element bearing diagnostics using the Case Western Reserve University data: a benchmark study[J]. Mechanical Systems and Signal Processing, 2015, 64/65: 100-131.
[26] Lessmeier C, Kimotho J, Zimmer D, et al.Condition monitoring of bearing damage in electromechanical drive systems by using motor current signals of electric motors: a benchmark data set for data-driven classification[C]//European Conference of the Prognostics and Health Management Society, Bilbao, Spain, 2016: 1-17.
[27] Long Mingsheng, Cao Yue, Wang Jianmin, et al. Learning transferable features with deep adaptation networks[EB/OL].2015: arXiv: 1502.02791. https:// arxiv.org/abs/1502.02791.
[28] Ganin Y, Ustinova E, Ajakan H, et al.Domain-adversarial training of neural networks[J]. The Journal of Machine Learning Research, 2016, 17(1): 2096-2030.