Abstract
Early identification of failures in rolling element bearings is an important research issue in mechanical systems. In this study, a reliable methodology for bearing fault detection is proposed, which is based on an optimal sub-band selection scheme using the discrete wavelet packet transform (DWPT) and envelope power analysis techniques. A DWPT-based decomposition is first performed to extract the characteristic defect features from the acquired acoustic emission (AE) signals. The envelope power spectrum (EPS) of each sub-band signal is then calculated to detect the characteristic defect frequencies to reveal abnormal symptoms in bearings. The selection of an appropriate sub-band is essential for effective fault diagnosis, as it can reveal intrinsically explicit information about different types of bearing faults. To address this issue, we propose a Gaussian distribution model-based health-related index (HI) that is a powerful quantitative parameter to accurately estimate the severity of bearing defects. The most optimal sub-band for fault detection is determined using two dimensional (2D) visualization analysis. The efficiency of the proposed approach is validated using several experiments in which different defect conditions are identified under variable, and low operational speeds.
Highlights
Induction motors are the most commonly used rotating machines in industrial applications due to their commercial availability, reliability, and reasonable cost
This paper presents a comprehensive methodology for early detection of the defect frequency components of BCO, BCI, and BCR based on envelope analysis using a Gaussian distribution model (GDM)-based window to capture intrinsic information about the failure
The bearing defects can be identified by calculating the envelope power spectrum (EPS) of 25 − 1 sub-bands from four-level discrete wavelet packet transform (DWPT) with the Db4 mother wavelet function
Summary
Induction motors are the most commonly used rotating machines in industrial applications due to their commercial availability, reliability, and reasonable cost. Sensors 2018, 18, 1389 been successfully diagnosed using different signal processing methods to extract characteristic defect features via vibration analysis [3,4,5], current signature analysis of induction motors [6,7,8], and stray flux measurement [9] These techniques have been extensively applied and have been very effective in detecting and identifying various bearing faults. For the EPS obtained from sub-band signals, kurtogram-based methods have been widely used to discover the appropriate sub-band that contains useful information intrinsic to various bearing defects [16,22,23] These techniques are not always effective in identifying the optimal sub-band due to the inclusion of other components, such as the harmonics of the operating frequency and noise frequencies in their spectra.
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