Abstract
The health condition of rolling bearing possesses a significant impact on the safety and efficiency of rotating machinery. Accordingly, to diagnose the faults in rolling bearings effectively and accurately, a novel hybrid approach coupling variational mode decomposition (VMD), composite multiscale fine-sorted dispersion entropy (CMFSDE) and support vector machine (SVM) optimized by mutation sine cosine algorithm and Harris hawks optimization (MSCAHHO) is proposed in the paper. Firstly, VMD is employed to decompose raw vibration signals with various fault types into different sets of intrinsic mode functions (IMFs) to weaken the non-stationarity of signals, before which the parameter $K$ of VMD is decided through central frequency observation method. Subsequently, CMFSDE is put forward in this paper to analyze the complexity of fault signals by fully considering the relationship between neighboring elements based on composite multiscale technique, with which the representative features of different fault samples are extracted to construct feature vectors. Later, an enhanced hybrid optimization approach called MSCAHHO is proposed by integrating sine cosine algorithm (SCA) and a periodic mutation strategy to improve Harris hawks optimization (HHO). Then, MSCAHHO is employed to optimize the parameters of SVM, after which the optimal SVM model is utilized for fault classification. Finally, the performance of the proposed methodology is evaluated with four validity indices through comparative experiments. The experimental results reveal that the proposed VMD-CMFSDE-MSCAHHO-SVM method achieves favorable diagnosis results comparing with other relevant methods.
Highlights
Rolling bearings, as the most important supporting component, are widely employed in rotating machinery systems, such as large generator sets, aero engines and advanced precision machine tools [1], [2]
ENGINEERING APPLICATION IN FAULT DIAGNOSIS OF ROLLING BEARING 1) COMPARATIVE EXPERIMENT AND EVALUATION INDICES To verify the availability of the developed fault diagnosis method based on variational mode decomposition (VMD)-composite multiscale fine-sorted dispersion entropy (CMFSDE)-mutation sine cosine algorithm (SCA)-Harris hawks optimization (HHO) (MSCAHHO)-support vector machine (SVM), comparative experiments were performed in the feature extraction and parameter optimization stages
To analyze the complexity of vibration signal and promote the accuracy of fault diagnosis in rolling bearing, a novel hybrid fault diagnosis approach is proposed based on CMFSDE as the feature extractor and MSCAHHO optimized SVM as the fault classifier in the paper
Summary
As the most important supporting component, are widely employed in rotating machinery systems, such as large generator sets, aero engines and advanced precision machine tools [1], [2]. As an effective tool for estimating the irregularity and uncertainty of the signal, has been widely employed to extract features within non-stationary time series, such as sample entropy (SampEn) [17], permutation entropy (PE) [18], fuzzy entropy (FE) [19] These classical entropies remain some drawbacks and need much effort to be improved. Similar to other optimization algorithms, the original HHO may still suffer from the troubles described above On this account, an enhanced hybrid optimization method termed as mutation SCA-HHO (MSCAHHO) combining the respective advantages of periodic mutation strategy [38], SCA and HHO is proposed in this study, which has fast convergence speed and can approximate the best global optimum based on test of several benchmark functions, including unimodal, multi-modal and composite functions.
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