Abstract
Induction motors are the backbone of the industries because they are easy to operate, rugged, economical and reliable. However, they are subjected to stator’s faults which damage the windings and consequently lead to machine failure and loss of revenue. Early detection and classification of these faults are important for the effective operation of induction motors. Stators faults detection and classification based on wavelet Transform was carried out in this study. The feature extraction of the acquired data was achieved using lifting decomposition and reconstruction scheme while Euclidean distance of the Wavelet energy was used to classify the faults. The Wavelet energies increased for all three conditions monitored, normal condition, inter-turn fault and phase-to-phase fault, as the frequency band of the signal decreases from D1 to A3. The deviations in the Euclidean Distance of the current of the Wavelet energy obtained for the phase-to-phase faults are 99.1909, 99.8239 and 87.9750 for phases A and B, A and C, B and C respectively. While that of the inter-turn faults in phases A, B and C are 77.5572, 61.6389 and 62.5581 respectively. Based on the Euclidean distances of the faults, Df and normal current signals, three classification points were set: K1 = 0.60 x 102, K2 = 0.80 x 102 and K3 = 1.00 x 102. For K2 ≥ Df ≥ K1 inter-turn faults is identified and for K3 ≥ Df ≥ K2 phase to phase fault identified. This will improve the induction motors stator’s fault diagnosis. 
 Keywords: induction motor, stator fault classification, data acquisition system, Discrete Wavelet Transform
Highlights
Induction motors are widely used as industrial drives because they are rugged, reliable and economical and easy to operate (Dubravko, 2015)
Fault feature extraction of the mechanical irregularity of induction motors bearing proposed by He et al (2015) was based on Ensemble Super-wavelet transform (ESW)
Stator fault classification has been presented in this paper
Summary
Induction motors are widely used as industrial drives because they are rugged, reliable and economical and easy to operate (Dubravko, 2015). Current and vibration data are one of the most important parameters used for condition monitoring and fault analysis since they possess the dynamic information of the motor (Bhowmik et al, 2013). Their performance depends on the efficiency of the technique used in the processing of the data. Signal monitoring technique for broken bars fault diagnosis based on uncertainty bounds violation for three-phase induction motors has been proposed (Mustafa et al, 2012).
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