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Impulses Recovery Technique Based on High Oscillation Region Detection and Shifted Rank-1 Reconstruction—Its Application to Bearing Fault Detection | IEEE Journals & Magazine | IEEE Xplore
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Journals & Magazines >IEEE Sensors Journal >Volume: 22 Issue: 8

Impulses Recovery Technique Based on High Oscillation Region Detection and Shifted Rank-1 Reconstruction—Its Application to Bearing Fault Detection

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Pengcheng Zhou; Liu He; Cai Yi; Qiuyang Zhou
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Abstract:

The health status of bearing is directly related to the safe operation of rotating machinery. Bearing fault detection technology is of great significance to reduce or eli...Show More

Metadata

Abstract:

The health status of bearing is directly related to the safe operation of rotating machinery. Bearing fault detection technology is of great significance to reduce or eliminate safety accidents. Singular value decomposition (SVD), as an effective low-rank approximation tool of data matrix, is widely used in bearing fault detection. The construction of trajectory matrix and the selection of singular value are two important factors that affect the performance of SVD-based fault diagnosis methods. In this paper, a new matrix low-rank approximation tool similar to SVD, shifted rank-1 reconstruction (SR1R), is introduced for fault diagnosis. SR1R uses periodic segment matrix (PSM) as trajectory matrix, and its signal reconstruction does not need to select singular value. In addition, a high oscillation region (HOR) detection method based on variance evaluation is proposed and applied to signal reconstruction of SR1R. The fault impulse detection method combining these two methods is called HOR-SR1R. The proposed method cannot only detect the fault impulses, but also suppress the noise between adjacent fault impulses. By contrast, the traditional SVD cannot eliminate the noise between adjacent fault impulses. The effectiveness of proposed method is validated by simulated signals, wheelset bearing data and open data set. Compared with two SVD-based fault diagnosis methods, Hankel matrix-based SVD and PSM-based SVD, the superiority of the proposed method is highlighted.
Published in: IEEE Sensors Journal ( Volume: 22, Issue: 8, 15 April 2022)
Page(s): 8084 - 8093
Date of Publication: 11 March 2022

ISSN Information:

DOI: 10.1109/JSEN.2022.3159116

Funding Agency:

References is not available for this document.
Contents

I. Introduction

Bearing is a critical and easily damaged component of rotating machinery. Bearing fault diagnosis has received extensive attention since its importance in preventing potential catastrophic accidents and ensuring adequate maintenance time [1]–[3]. Vibration signal collected from bearing contains rich information about the equipment health condition and is sensitive to different fault types. Therefore, vibration signals generated by faults in bearing have been widely studied and a lot of research work has been published [4]–[6]. From the mechanical fault mechanism, when bearing has local defects, there will be periodic impulse in the vibration measurement [7], [8]. Additionally, in some cases, the vibration signals of periodic fault impulses exhibit amplitude modulation features. Therefore, periodic impulses and amplitude modulation features are strong evidence to reveal bearing faults [6], [9], [10]. However, these fault impulses are usually weak because they are buried in strong vibration responses from other mechanical components and severe background noises [11], [12]. Therefore, it is a challenge to extract impulses from the vibration signal for bearing fault diagnosis.

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