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基于自适应投影本征变换多变量经验模态分解和高阶奇异值分解的滚动轴承多故障诊断

Multi-Fault Diagnosis of Rolling Bearings via Adaptive Projection Intrinsically Transformed Multivariate Empirical Mode Decomposition and High Order Singular Value Decomposition.

作者信息

Yuan Rui, Lv Yong, Song Gangbing

机构信息

Key Laboratory of Metallurgical Equipment and Control Technology, Wuhan University of Science and Technology, Ministry of Education, Wuhan 430081, China.

Hubei Key Laboratory of Mechanical Transmission and Manufacturing Engineering, Wuhan University of Science and Technology, Wuhan 430081, China.

出版信息

Sensors (Basel). 2018 Apr 16;18(4):1210. doi: 10.3390/s18041210.

DOI:10.3390/s18041210
PMID:29659510
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5948897/
Abstract

Rolling bearings are important components in rotary machinery systems. In the field of multi-fault diagnosis of rolling bearings, the vibration signal collected from single channels tends to miss some fault characteristic information. Using multiple sensors to collect signals at different locations on the machine to obtain multivariate signal can remedy this problem. The adverse effect of a power imbalance between the various channels is inevitable, and unfavorable for multivariate signal processing. As a useful, multivariate signal processing method, Adaptive-projection has intrinsically transformed multivariate empirical mode decomposition (APIT-MEMD), and exhibits better performance than MEMD by adopting adaptive projection strategy in order to alleviate power imbalances. The filter bank properties of APIT-MEMD are also adopted to enable more accurate and stable intrinsic mode functions (IMFs), and to ease mode mixing problems in multi-fault frequency extractions. By aligning IMF sets into a third order tensor, high order singular value decomposition (HOSVD) can be employed to estimate the fault number. The fault correlation factor (FCF) analysis is used to conduct correlation analysis, in order to determine effective IMFs; the characteristic frequencies of multi-faults can then be extracted. Numerical simulations and the application of multi-fault situation can demonstrate that the proposed method is promising in multi-fault diagnoses of multivariate rolling bearing signal.

摘要

滚动轴承是旋转机械系统中的重要部件。在滚动轴承多故障诊断领域,从单通道采集的振动信号往往会遗漏一些故障特征信息。使用多个传感器在机器上的不同位置采集信号以获得多变量信号可以解决这个问题。各通道之间功率不平衡的不利影响是不可避免的,并且不利于多变量信号处理。自适应投影作为一种有用的多变量信号处理方法,本质上对多变量经验模式分解(APIT-MEMD)进行了变换,并且通过采用自适应投影策略以减轻功率不平衡,表现出比MEMD更好的性能。APIT-MEMD的滤波器组特性也被采用,以实现更准确和稳定的本征模态函数(IMF),并缓解多故障频率提取中的模态混叠问题。通过将IMF集排列成三阶张量,可以采用高阶奇异值分解(HOSVD)来估计故障数量。使用故障相关因子(FCF)分析进行相关性分析,以确定有效的IMF;然后可以提取多故障的特征频率。数值模拟和多故障情况的应用表明,该方法在多变量滚动轴承信号的多故障诊断中具有良好的前景。

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