基于多时间相关特征融合的混合深度学习的机械智能故障诊断

IF 2.2 3区工程技术 Q3 ENGINEERING, INDUSTRIAL

Quality and Reliability Engineering International Pub Date : 2024-05-28 DOI:10.1002/qre.3597

Yaqiong Lv, Xiaohu Zhang, Yiwei Cheng, Carman K. M. Lee

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引用次数: 0

摘要

随着智能制造时代的到来，对机械故障诊断技术提出了更高的要求。现有的数据驱动方法要么依赖专门的经验知识进行特征分析，要么采用单一的深度神经网络拓扑结构进行自动特征提取，但都存在一定的信息损失，尤其是牺牲了时间序列信息，最终影响了诊断的准确性。针对这一问题，本文提出了一种用于智能故障诊断的新型多时序相关特征融合网（MTCFF-Net），它能从不同维度捕捉并保留时序故障特征信息。MTCFF-Net 包含四个子网络，分别是长短期记忆（LSTM）子网络、格拉西亚角求和场（GASF）-GhostNet 子网络、马尔可夫转换场（MTF）-GhostNet 子网络和特征融合子网络。通过并行 LSTM 子网络、GASF-GhostNet 子网络和 MTF-GhostNet 子网络提取不同维度的特征，然后通过特征融合子网络进行融合，从而实现精确的故障诊断。为了验证所提出的 MTCFF-Net 的有效性和通用性，对轴承进行了两次故障诊断实验研究。实验结果表明，所提出的模型优于其他比较方法。

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Intelligent fault diagnosis of machinery based on hybrid deep learning with multi temporal correlation feature fusion

With the advent of intelligent manufacturing era, higher requirements are put forward for the fault diagnosis technology of machinery. The existing data‐driven approaches either rely on specialized empirical knowledge for feature analysis, or adopt single deep neural network topology structure for automatic feature extraction with compromise of certain information loss especially the time‐series information's sacrifice, which both eventually affect the diagnosis accuracy. To address the issue, this paper proposes a novel multi‐temporal correlation feature fusion net (MTCFF‐Net) for intelligent fault diagnosis, which can capture and retain time‐series fault feature information from different dimensions. MTCFF‐Net contains four sub‐networks, which are long and short‐term memory (LSTM) sub‐network, Gramian angular summation field (GASF)‐GhostNet sub‐network and Markov transition field (MTF)‐GhostNet sub‐network and feature fusion sub‐network. Features of different dimensional are extracted through parallel LSTM sub‐network, GASF‐GhostNet sub‐network and MTF‐GhostNet sub‐network, and then fused by feature fusion sub‐network for accurate fault diagnosis. Two fault diagnosis experimental studies on bearings are implemented to validate the effectiveness and generalization of the proposed MTCFF‐Net. Experimental results demonstrate that the proposed model is superior to other comparative approaches.

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来源期刊

Quality and Reliability Engineering International 管理科学-工程：工业

CiteScore

4.90

自引率

21.70%

发文量

181

审稿时长

6 months

期刊介绍： Quality and Reliability Engineering International is a journal devoted to practical engineering aspects of quality and reliability. A refereed technical journal published eight times per year, it covers the development and practical application of existing theoretical methods, research and industrial practices. Articles in the journal will be concerned with case studies, tutorial-type reviews and also with applications of new or well-known theory to the solution of actual quality and reliability problems in engineering. Papers describing the use of mathematical and statistical tools to solve real life industrial problems are encouraged, provided that the emphasis is placed on practical applications and demonstrated case studies. The scope of the journal is intended to include components, physics of failure, equipment and systems from the fields of electronic, electrical, mechanical and systems engineering. The areas of communications, aerospace, automotive, railways, shipboard equipment, control engineering and consumer products are all covered by the journal. Quality and reliability of hardware as well as software are covered. Papers on software engineering and its impact on product quality and reliability are encouraged. The journal will also cover the management of quality and reliability in the engineering industry. Special issues on a variety of key topics are published every year and contribute to the enhancement of Quality and Reliability Engineering International as a major reference in its field.