A robust detector for rolling element bearing condition monitoring based on the modulation signal bispectrum and its performance evaluation against the Kurtogram

•A robust MSB detector is developed.•MSB is applied to vibrations of motor and planetary gearboxes.•Simulated data are applied to performance evaluation.•Experimental vibrations of motor and planetary gearbox are investigated. Envelope analysis is a widely used method for rolling element bearing fau...

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Published in:Mechanical systems and signal processing 2018-02, Vol.100, p.167-187
Main Authors: Tian, Xiange, Xi Gu, James, Rehab, Ibrahim, Abdalla, Gaballa M., Gu, Fengshou, Ball, A.D.
Format: Article
Language:English
Subjects:
Analysis
Bearing
Bearing fault detection
Condition monitoring
Data analysis
Demodulation
Envelope analysis
Fault detection
Frequencies
Gears
Kurtogram
Modulation
Modulation signal bispectrum
Motors
Narrowband
Noise reduction
Noise sensitivity
Performance evaluation
Random noise
Robustness
Vibration
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cited_by cdi_FETCH-LOGICAL-c424t-341d0c697455e57bc45a11c14150ef98967530757e15689d0b2930cffb26e0ec3
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container_end_page 187
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container_start_page 167
container_title Mechanical systems and signal processing
container_volume 100
creator Tian, Xiange
Xi Gu, James
Rehab, Ibrahim
Abdalla, Gaballa M.
Gu, Fengshou
Ball, A.D.
description •A robust MSB detector is developed.•MSB is applied to vibrations of motor and planetary gearboxes.•Simulated data are applied to performance evaluation.•Experimental vibrations of motor and planetary gearbox are investigated. Envelope analysis is a widely used method for rolling element bearing fault detection. To obtain high detection accuracy, it is critical to determine an optimal frequency narrowband for the envelope demodulation. However, many of the schemes which are used for the narrowband selection, such as the Kurtogram, can produce poor detection results because they are sensitive to random noise and aperiodic impulses which normally occur in practical applications. To achieve the purposes of denoising and frequency band optimisation, this paper proposes a novel modulation signal bispectrum (MSB) based robust detector for bearing fault detection. Because of its inherent noise suppression capability, the MSB allows effective suppression of both stationary random noise and discrete aperiodic noise. The high magnitude features that result from the use of the MSB also enhance the modulation effects of a bearing fault and can be used to provide optimal frequency bands for fault detection. The Kurtogram is generally accepted as a powerful means of selecting the most appropriate frequency band for envelope analysis, and as such it has been used as the benchmark comparator for performance evaluation in this paper. Both simulated and experimental data analysis results show that the proposed method produces more accurate and robust detection results than Kurtogram based approaches for common bearing faults under a range of representative scenarios.
doi_str_mv 10.1016/j.ymssp.2017.07.037
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Envelope analysis is a widely used method for rolling element bearing fault detection. To obtain high detection accuracy, it is critical to determine an optimal frequency narrowband for the envelope demodulation. However, many of the schemes which are used for the narrowband selection, such as the Kurtogram, can produce poor detection results because they are sensitive to random noise and aperiodic impulses which normally occur in practical applications. To achieve the purposes of denoising and frequency band optimisation, this paper proposes a novel modulation signal bispectrum (MSB) based robust detector for bearing fault detection. Because of its inherent noise suppression capability, the MSB allows effective suppression of both stationary random noise and discrete aperiodic noise. The high magnitude features that result from the use of the MSB also enhance the modulation effects of a bearing fault and can be used to provide optimal frequency bands for fault detection. 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subjects Analysis
Bearing
Bearing fault detection
Condition monitoring
Data analysis
Demodulation
Envelope analysis
Fault detection
Frequencies
Gears
Kurtogram
Modulation
Modulation signal bispectrum
Motors
Narrowband
Noise reduction
Noise sensitivity
Performance evaluation
Random noise
Robustness
Vibration
title A robust detector for rolling element bearing condition monitoring based on the modulation signal bispectrum and its performance evaluation against the Kurtogram
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