Abstract
Multiple sensor data fusion is necessary for effective condition monitoring as the electric machines operate in a wide range of diverse operations. This study investigates sensor acquired vibration and current signals to establish a reliable multi-fault diagnosis framework of a brushless DC (BLDC) motor. Faults in stator and rotor were created deliberately by shorting two adjacent windings and creating a hole on the surface, respectively. The threshold for different health states was obtained by the third harmonic analysis of motor current. Later, the key features from sensor acquired current and vibration signals are selected based on monotonicity and reduced using the principal component analysis (PCA). For future predictions, an artificial neural network (ANN) is used to classify different fault features and its performance is evaluated using several metrics. Analysis of motor current harmonics and impulsive vibration response at the same time provides a thorough health estimation of BLDC motor in the presence of both electrical and mechanical faults. Multiple sensor information is fused to obtain a better understanding of the fault characteristics and mitigate the randomness of fault diagnosis. The proposed model was able to detect and classify multiple fault features with higher accuracy compared to other similar methods.
Highlights
Predictive maintenance (PdM) using data-driven approaches has become quite popular in academia and industries
A faulty component can cause for catastrophic failures that can be detrimental to humans and environment
This paper presents a fault detection and identification framework considering multiple faults in brushless DC (BLDC) motors
Summary
Predictive maintenance (PdM) using data-driven approaches has become quite popular in academia and industries. The major advantage of a data-driven maintenance framework is that it does not require a prior physics of failure model of the system [1]. A proper mathematical model is often difficult to establish, and considering the intricate industrial operations, a physical model will require continuous updating based on operating conditions. This is a time consuming and economically expensive task. Data-driven methods have gained popularity over the model-based methods over the years. Have made data-driven approaches on top of the maintenance frameworks [2]. Prognostics is making predictions based on historical failure data.
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