Abstract
Traditional fault diagnosis methods of DC (direct current) motors require establishing accurate mathematical models, effective state and parameter estimations, and appropriate statistical decision-making methods. However, these preconditions considerably limit traditional motor fault diagnosis methods. To address this issue, a new mechanical fault diagnosis method was proposed. Firstly, the vibration signals of motors were collected by the designed acquisition system. Subsequently, variational mode decomposition (VMD) was adopted to decompose the signal into a series of intrinsic mode functions and extract the characteristics of the vibration signals based on sample entropy. Finally, a united random forest improvement based on a SPRINT algorithm was employed to identify vibration signals of rotating machinery, and each branch tree was trained by applying different bootstrap sample sets. As the results reveal, the proposed fault diagnosis method is featured with good generalization performance, as the recognition rate of samples is more than 90%. Compared with the traditional neural network, data-heavy parameter optimization processes are avoided in this method. Therefore, the VMD-SampEn-RF-based method proposed in this paper performs well in fault diagnosis of DC motors, providing new ideas for future fault diagnoses of rotating machinery.
Highlights
Reliable operation of DC motors is crucial to factories, which has a huge impact on personal safety and on efficiency of operations [1]
As vibration signals generated by mechanical components often provide various dynamic information about the status of the mechanical system, many studies on DC motor fault diagnosis have focused on mechanical vibration signals [2,3], which have achieved successful application to a certain extent in the past decades
The main contribution of this paper is to propose a novel mechanical fault diagnosis method for DC motors based on variational mode decomposition (VMD), sample entropy (SampEn), and random forest (RF), during which the optimal RF
Summary
Reliable operation of DC motors is crucial to factories, which has a huge impact on personal safety and on efficiency of operations [1]. LMD and EWT algorithms are essentially adaptive signal decomposition methods based on a recursive mode, with endpoint effects and modal aliasing problems [15,16]. In recent years, another important method for diagnosis-based signals is based on principal component analysis (PCA) of the data. To solve the above problems, a new fault diagnosis method based on the RF algorithm is proposed in this paper. The main contribution of this paper is to propose a novel mechanical fault diagnosis method for DC motors based on VMD, SampEn, and RF, during which the optimal RF classifier is established through the SPRINT algorithm. The improved RF classifier is employed to identify the labeled samples
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