Abstract
Fault diagnosis of rotating machinery mainly includes fault feature extraction and fault classification. Vibration signal from the operation of machinery usually could help diagnosing the operational state of equipment. Different types of fault usually have different vibrational features, which are actually the basis of fault diagnosis. This paper proposes a novel fault diagnosis model, which extracts features by combining vibration severity, dyadic wavelet energy time-spectrum, and coefficient power spectrum of the maximum wavelet energy level (VWC) at the feature extraction stage. At the stage of fault classification, we design a support vector machine (SVM) based on the modified shuffled frog-leaping algorithm (MSFLA) for the accurate classifying machinery fault method. Specifically, we use the MSFLA method to optimize SVM parameters. MSFLA can avoid getting trapped into local optimum, speeding up convergence, and improving classification accuracy. Finally, we evaluate our model on real rotating machinery platform, which has four different states, i.e., normal state, eccentric axle fault (EAF), bearing pedestal fault (BPF), and sealing ring wear fault (SRWF). As demonstrated by the results, the VWC method is efficient in extracting vibration signal features of rotating machinery. Based on the extracted features, we further compare our classification method with other three fault classification methods, i.e., backpropagation neural network (BPNN), artificial chemical reaction optimization algorithm (ACROA-SVM), and SFLA-SVM. The experiment results show that MSFLA-SVM achieves a much higher fault classification rate than BPNN, ACROA-SVM, and SFLA-SVM.
Highlights
Fault diagnosis of rotating machinery is a borderline discipline with high integrity accompanied by the rapid development of modern industry
Fault feature extraction and fault classification are hot topics in fault diagnosis. e vibration signals from rotating machinery contain a lot of information which can be applied to determine whether the equipment is operating normally or not. e different fault types have different features of vibration signals
E training dataset is collected from 4 different rotational machinery states, i.e., normal, eccentric axle fault (EAF), bearing pedestal fault (BPF), and sealing ring wear fault (SRWF). e 22 features are composed of vibration severity, 1/2f0∼6f0 in three directions as Figures 8 and 9
Summary
Fault diagnosis of rotating machinery is a borderline discipline with high integrity accompanied by the rapid development of modern industry. Samanta and Al-Balushi [23] extracted the features of the vibration signals under normal and fault states of the rotating machinery and applied these data to the input of ANN. Reference [30] gave a fault diagnosis model using empirical mode decomposition (EMD) and GA-SVM and analyzed high-voltage circuit breaker They combined EMD and energy entropy as the feature vector and used GA-SVM to improve generation ability and classification accuracy. Aiming at gear fault diagnosis, Yang et al [31] exploited ensemble empirical mode decomposition extracting fault features and used SVM for classifying faults They adopted ABCA to optimize SVM parameters and obtained higher classification accuracy than GA-based and PSO-based methods. SRWF could cause a backflow of the internal medium and could get the impeller damaged
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