Abstract
In prognostics and health management (PHM), the majority of fault detection and diagnosis is performed by adopting segregated methodology, where electrical faults are detected using motor current signature analysis (MCSA), while mechanical faults are detected using vibration, acoustic emission, or ferrography analysis. This leads to more complicated methods for overall fault detection and diagnosis. Additionally, the involvement of several types of data makes system management difficult, thus increasing computational cost in real-time. Aiming to resolve that, this work proposes the use of the embedded electrical current signals of the control unit (MCSA) as an approach to detect and diagnose mechanical faults. The proposed fault detection and diagnosis method use the discrete wavelet transform (DWT) to analyze the electric motor current signals in the time-frequency domain. The technique decomposes current signals into wavelets, and extracts distinguishing features to perform machine learning (ML) based classification. To achieve an acceptable level of classification accuracy for ML-based classifiers, this work extends to presenting a methodology to extract, select, and infuse several types of features from the decomposed wavelets of the original current signals, based on wavelet characteristics and statistical analysis. The mechanical faults under study are related to the rotate vector (RV) reducer mechanically coupled to electric motors of the industrial robot Hyundai Robot YS080 developed by Hyundai Robotics Co. The proposed approach was implemented in real-time and showed satisfying results in fault detection and diagnosis for the RV reducer, with a classification accuracy of 96.7%.
Highlights
With the advancement in the field of automation and control, modern industrial systems have adopted programmed robotics arrangements to execute tasks autonomously with minimum human interference
This leads to more currentofsignals of allshould motorsbeshould be analyzed, regardless of the fault location. This leads complex to more current signals of all motors should be analyzed, regardless of the fault location. This leads to more fault detection diagnosis system, but upon several with the results presented complex faultand detection and diagnosis system, but experimental upon severalfindings experimental findings with the complex fault detection and diagnosis system, but upon several experimental findings with the results presented in Figure 14, it is clear that for a robotic arm like the Hyundai Robot, the mechanical couplings along the robotic arm notthat affect current signals of another Robot, motor.the
The mechanical faults can be categorized as (1) faults related to electric machines and (2) faults related to coupled mechanical components
Summary
With the advancement in the field of automation and control, modern industrial systems have adopted programmed robotics arrangements to execute tasks autonomously with minimum human interference. These robots act as basic building blocks in the automation of industrial systems, and over time, their continuous operation in manufacturing processes causes the degradation of constituent sub-systems and components. Without proper maintenance, this degradation can create several faults in the system, which in turn causes unexpected shutdowns and production loss to the manufacturers. Health refers to a certain industrial application or component’s condition, efficiency, and remaining
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