利用有限样本对航空发动机轴承进行高精度智能故障诊断的方法

IF 8.2 1区 计算机科学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Zhenya Wang , Qiusheng Luo , Hui Chen , Jingshan Zhao , Ligang Yao , Jun Zhang , Fulei Chu
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引用次数: 0

摘要

作为支持航空发动机功能的关键部件,对轴承进行有效的故障诊断对于确保发动机的可靠性和持续适航性至关重要。然而,由于航空发动机轴承故障数据的稀缺性,智能诊断技术的实施受到了实际限制。本文提出了一种在样本有限条件下进行航空发动机轴承故障诊断的专门方法。首先,该方法采用精炼复合多尺度相位熵(RCMPhE)来提取能够表征航空发动机轴承瞬态信号动态的熵特征。根据信号振幅信息,制定复合多尺度分解序列,然后为每个子序列创建散点图。这些散点图被划分为若干区段,从而可以在每个区段内进行个性化的概率分布计算,最后进行精细的熵值运算。因此,RCMPhE 解决了现有熵理论中普遍存在的问题,如偏差和不稳定性。随后,引入了 bonobo 优化支持向量机,以建立熵域特征与故障类型之间的映射相关性,从而增强其在航空发动机轴承中的故障识别能力。在动力传动系统轴承数据、实际航空发动机轴承数据和实际航空航天轴承数据上进行的实验验证表明,在每个状态仅需 5 个训练样本的情况下,故障诊断准确率分别高达 99.83 %、100 % 和 100 %。此外,与现有的八种故障诊断方法相比,拟议方法的识别准确率提高了 28.97%。这证明了该方法在解决航空发动机轴承故障诊断小样本限制方面的有效性和潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A high-accuracy intelligent fault diagnosis method for aero-engine bearings with limited samples

A high-accuracy intelligent fault diagnosis method for aero-engine bearings with limited samples

As a crucial component supporting aero-engine functionality, effective fault diagnosis of bearings is essential to ensure the engine's reliability and sustained airworthiness. However, practical limitations prevail due to the scarcity of aero-engine bearing fault data, hampering the implementation of intelligent diagnosis techniques. This paper presents a specialized method for aero-engine bearing fault diagnosis under conditions of limited sample availability. Initially, the proposed method employs the refined composite multiscale phase entropy (RCMPhE) to extract entropy features capable of characterizing the transient signal dynamics of aero-engine bearings. Based on the signal amplitude information, the composite multiscale decomposition sequence is formulated, followed by the creation of scatter diagrams for each sub-sequence. These diagrams are partitioned into segments, enabling individualized probability distribution computation within each sector, culminating in refined entropy value operations. Thus, the RCMPhE addresses issues prevalent in existing entropy theories such as deviation and instability. Subsequently, the bonobo optimization support vector machine is introduced to establish a mapping correlation between entropy domain features and fault types, enhancing its fault identification capabilities in aero-engine bearings. Experimental validation conducted on drivetrain system bearing data, actual aero-engine bearing data, and actual aerospace bearing data demonstrate remarkable fault diagnosis accuracy rates of 99.83 %, 100 %, and 100 %, respectively, with merely 5 training samples per state. Additionally, when compared to the existing eight fault diagnosis methods, the proposed method demonstrates an enhanced recognition accuracy by up to 28.97 %. This substantiates its effectiveness and potential in addressing small sample limitations in aero-engine bearing fault diagnosis.

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来源期刊
Computers in Industry
Computers in Industry 工程技术-计算机:跨学科应用
CiteScore
18.90
自引率
8.00%
发文量
152
审稿时长
22 days
期刊介绍: The objective of Computers in Industry is to present original, high-quality, application-oriented research papers that: • Illuminate emerging trends and possibilities in the utilization of Information and Communication Technology in industry; • Establish connections or integrations across various technology domains within the expansive realm of computer applications for industry; • Foster connections or integrations across diverse application areas of ICT in industry.
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