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使用反卷积增强的倒谱编辑技术对直升机行星齿轮齿圈裂纹进行诊断与趋势分析

Helicopter Planet Gear Rim Crack Diagnosis and Trending Using Cepstrum Editing Enhanced with Deconvolution.

作者信息

Sawalhi Nader, Wang Wenyi, Blunt David

机构信息

Defence Science and Technology Group (DSTG), Melbourne, VIC 3207, Australia.

出版信息

Sensors (Basel). 2024 Apr 18;24(8):2593. doi: 10.3390/s24082593.

DOI:10.3390/s24082593
PMID:38676209
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11055071/
Abstract

Detecting gear rim fatigue cracks using vibration signal analysis is often a challenging task, which typically requires a series of signal processing steps to detect and enhance fault features. This task becomes even harder in helicopter planetary gearboxes due to the complex interactions between different gear sets and the presence of vibration from sources other than the planetary gear set. In this paper, we propose an effectual processing algorithm to isolate and enhance rim crack features and to trend crack growth in planet gears. The algorithm is based on using cepstrum editing (or liftering) of the hunting-tooth synchronous averaged signals (angular domain) to extract harmonics and sidebands of the planet gears and low-pass filtering and minimum entropy deconvolution (MED) to enhance extracted fault features. The algorithm has been successfully applied to a vibration dataset collected from a planet gear rim crack propagation test undertaken in the Helicopter Transmission Test Facility (HTTF) at DSTG Melbourne. In this test, a seeded notch generated by an electric discharge machine (EDM) was used to initiate a fatigue crack that propagated through the gear rim body over 94 load cycles. The proposed algorithm demonstrated a successful isolation of incipient fault features and provided a reliable trending capability to monitor crack progression. Results of a comparative analysis showed that the proposed algorithm outperformed the traditional signal processing approach.

摘要

利用振动信号分析检测齿轮轮缘疲劳裂纹通常是一项具有挑战性的任务,这通常需要一系列信号处理步骤来检测和增强故障特征。由于不同齿轮组之间的复杂相互作用以及行星齿轮组以外的其他振动源的存在,在直升机行星齿轮箱中,这项任务变得更加困难。在本文中,我们提出了一种有效的处理算法,用于分离和增强轮缘裂纹特征,并跟踪行星齿轮裂纹的扩展。该算法基于对寻齿同步平均信号(角域)进行倒谱编辑(或提升),以提取行星齿轮的谐波和边带,并通过低通滤波和最小熵反卷积(MED)来增强提取的故障特征。该算法已成功应用于从墨尔本国防科学与技术集团(DSTG)直升机传动试验设施(HTTF)进行的行星齿轮轮缘裂纹扩展试验中收集的振动数据集。在该试验中,使用电火花加工(EDM)产生的预置缺口来引发疲劳裂纹,该裂纹在94个载荷循环中贯穿齿轮轮缘体。所提出的算法成功地分离了早期故障特征,并提供了可靠的跟踪能力来监测裂纹扩展。对比分析结果表明,所提出的算法优于传统的信号处理方法。

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本文引用的文献

1
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ISA Trans. 2020 Jun;101:453-460. doi: 10.1016/j.isatra.2020.01.019. Epub 2020 Jan 14.