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Detection of Sources of Nonlinearity in Multiple Bolted Joints by Use of Laser Vibrometer Read chapter Read first chapter

2019 | OriginalPaper | Chapter

6. Remote Detection of Abnormal Behavior in Mechanical Systems

Authors : Greta Colford, Erica Jacobson, Kaden Plewe, Eric Flynn, Adam Wachtor

Published in: Rotating Machinery, Optical Methods & Scanning LDV Methods, Volume 6

Publisher: Springer International Publishing

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Abstract

Machinery can undergo many different types of operational faults during use. Mitigating these faults through scheduled maintenance programs or upon failure is costly, inefficient, and can introduce safety hazards. An alternative approach to identifying abnormal behavior in mechanical systems is through condition based monitoring, which is applied by taking measurements of machinery and using spectral analysis to diagnose faults. The signals produced by machines contain characteristic frequencies describing the operating state. The application of local sensors to monitor the health of mechanical systems is often expensive or not feasible; it is of interest to find methods of remote sensing to allow for detection of abnormalities in mechanical systems without the need for sensors at the local point of operation. This work intends to utilize the method of remote detection to study the diminishment of fault feature observability as a function of sensor location relative to operating equipment. In this study, the procedure used for fault detection consists of the following: (1) collect signals for rotating machinery operating in a healthy, faulty, and off state (2) identify features that are unique to a faulty operating state (3) use those features to identify faulty behavior. This procedure is performed at three locations. For each location, the observable feature for a healthy, faulty and motor off state is calculated and compared using the statistical mean, standard deviation, p-value and Bhattacharyya distance. The relationship between fault observability and distance is presented as a function of Bhattacharyya distance and classified based on a one-way ANOVA test. Machine fault diagnosis becomes more difficult as the measurement location increases. At greater distances, there is no statistical significance between healthy and faulty machine operation. Using a predictable frequency response, machine faults can be correctly identified up to a certain threshold determined by environment noise.

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Metadata
Title
Remote Detection of Abnormal Behavior in Mechanical Systems
Authors
Greta Colford
Erica Jacobson
Kaden Plewe
Eric Flynn
Adam Wachtor
Copyright Year
2019
Book
Rotating Machinery, Optical Methods & Scanning LDV Methods, Volume 6

Print ISBN: 978-3-030-12934-7

Electronic ISBN: 978-3-030-12935-4

Copyright Year: 2019

DOI
https://doi.org/10.1007/978-3-030-12935-4_6

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