Abstract
Machinery fault diagnosis methods based on dimensionless indicators have long been studied. However, traditional dimensionless indicators usually suffer a low diagnostic accuracy for mechanical components. Toward this end, an effective fault diagnosis method based on redefined dimensionless indicators (RDIs) and minimum redundancy maximum relevance (mRMR) is proposed to identify the health conditions of mechanical components. In the proposed method, the vibration signals are first processed by the variational mode decomposition, and multiple RDIs are constructed based on the decomposed signals. Subsequently, the mRMR approach is introduced to select the RDIs and several important RDIs can be obtained. Finally, the obtained RDIs are fed into a grid search support vector machine to perform fault pattern identification. To verify the superiority of the proposed method, two experimental examples for different fault types of mechanical components including rolling bearing and gearbox are conducted. The experimental results demonstrated that the RDIs as new fault features can effectively solve the deficiency of the traditional dimensionless indicator, and has stronger distinguishing ability for machinery faults. Additionally, our proposed method successfully differentiated 12 fault conditions of rolling bearings and nine fault conditions of gears with average accuracies of 97.47% and 97.12% with 11 and 5 RDIs, respectively.
Highlights
Rolling bearings and gears are the most commonly used components in modern machinery that frequently functions under harsh environmental conditions
Based on the above analysis, an effective fault diagnosis method for mechanical components is proposed based on variational mode decomposition (VMD), redefined dimensionless indicators (RDIs) extraction, minimum redundancy maximum relevance (mRMR) feature selection, and grid search support vector machine (GSSVM) fault identification
Based on the aforementioned analysis, this study proposes an intelligent fault diagnosis approach for mechanical components based on VMD, RDIs extraction, mRMR feature selection, and GSSVM fault identification
Summary
Rolling bearings and gears are the most commonly used components in modern machinery that frequently functions under harsh environmental conditions. To solve the abovementioned problems of TDIs, a new fault extraction method based on redefined dimensionless indicators (RDIs) is proposed in this study. Based on the RDIs, more types of dimensionless indicators and more useful fault information hidden in the vibration signal can be obtained. In [28], locality preserving projections were used to select the more sensitive low-dimensional information hidden in high-dimensional fusion feature structures These methods have failed to consider the possible redundant and irrelevant features in high-dimensional feature sets, of which redundant and irrelevant features might reduce the fault identification accuracy and increase the computation time. Based on the above analysis, an effective fault diagnosis method for mechanical components is proposed based on VMD, RDIs extraction, mRMR feature selection, and grid search support vector machine (GSSVM) fault identification. The remainder of this paper is organized as follows: section 2 presents the proposed diagnostic framework and techniques involved; section 3 describes the related theories; section 4 presents the experimental demonstration, VMD-based RDIs construction, and mRMR-based RDI selection; section 5 describes the comparative studies; section 6 concludes this paper
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