Abstract
The incipient damages of mechanical equipment excite weak impulse vibration, which is hidden, almost unobservable, in the collected signal, making fault detection and failure prevention at the inchoate stage rather challenging. Traditional feature extraction techniques, such as bandpass filtering and time-frequency analysis, are suitable for matrix processing but challenged by the higher-order data. To tackle these problems, a novel method of impulse feature extraction for vibration signals, based on sparse non-negative tensor factorization is presented in this paper. Primarily, the phase space reconstruction and the short time Fourier transform are successively employed to convert the original signal into time-frequency distributions, which are further arranged into a three-way tensor to obtain a time-frequency multi-aspect array. The tensor is decomposed by sparse non-negative tensor factorization via hierarchical alternating least squares algorithm, after which the latent components are reconstructed from the factors by the inverse short time Fourier transform and eventually help extract the impulse feature through envelope analysis. For performance verification, the experimental analysis on the bearing datasets and the swashplate piston pump has confirmed the effectiveness of the proposed method. Comparisons to the traditional methods, including maximum correlated kurtosis deconvolution, singular value decomposition, and maximum spectrum kurtosis, also suggest its better performance of feature extraction.
Highlights
In modern industry, the increasing complexity of mechanical equipment assigns great significance to the normal operation of every single part
To accurately extract the fault impulses, as well as to make the best use of the advantage of tensor factorization, we present a novel feature extraction finesse for vibration signals based on sparse non-negative tensor factorization (SNTF)
In order to verify the effectiveness of feature extraction, some representative models were theoretical frequency calculated with the hypothesis of rollers’
Summary
The increasing complexity of mechanical equipment assigns great significance to the normal operation of every single part. An unexpected failure could lead to the instability or even breakdown of the mechanical system [1,2]. Incipient fault prognosis is expected to provide early warning before the occurrence of catastrophic failure. Vibration signals are effective tools for condition monitoring and fault diagnosis, mainly because of their revelations of dynamic information and their convenience for measurements. In Stanisław’s study, various measurement systems for evaluating the vibrations of rolling bearings were thoroughly compared [3]. Due to the complexity of the transmission, the vibration signal with incipient fault often incorporates a large amount of the interference apart from the fault
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