Abstract
Expulsion identification is of significance for welding quality assessment and control in resistance spot welding. In order to improve the identification accuracy, a novel wavelet decomposition and Back Propagation (BP) neural networks with the peak-to-peak amplitude and the kurtosis index were proposed to identify the expulsion from electrode force sensing signals. The rapid step impulse and resultant damping vibration of electrode force was determined as a robust indication of expulsion, and this feature was extracted from the electrode force waveform by seven-layer wavelet decomposition with Daubechies5 wavelets. Then, the energy distribution proportion of the decomposed detail signals were calculated, and the highest-energy one was selected as the target signal. Two statistical indexes were introduced in this paper to measure the target signal in overall situation and volatility. The bigger the peak-to-peak amplitude is, the more violent the fluctuation is. Moreover, the higher the kurtosis index is, the stronger the impact is, and the lower the dispersion degree of the data is. Experimental analysis showed that neither the peak-to-peak amplitude nor the kurtosis index could accurately judge the expulsion defect individually, because of the early signal fluctuation, likely affected by the work-piece clamping, work-piece clearance, or the oxide film thickness. Therefore, the BP neural networks were introduced to identify the expulsion defects, which is a mature and stable non-linear pattern recognition method. Testing experiments presented good results with the trained networks and improved the evaluable accuracy effectively in the quality assessment of the resistance spot welding.
Highlights
Resistance spot welding (RSW) still stands out due to its high efficiency, low cost, robustness, flexibility, and widespread use in metal joining in automatic manufacturing
The results show that the linear vector quantization (LVQ) neural network is able to detect the expulsion in different materials
The LabVIEW programming was used as the interface to display images and defect recognition results, while the main signal processing procedures were completed via the Matlab using the decomposition and Back Propagation (BP) neural network method based on expulsion indexes
Summary
Resistance spot welding (RSW) still stands out due to its high efficiency, low cost, robustness, flexibility, and widespread use in metal joining in automatic manufacturing. According to the above reviewed works, it shows that the electrode force during the welding process is a suitable and effective signal for expulsion detection online or offline. Signal processing, predicting models, and modern pattern recognition were introduced in the defect features extraction and identification of resistance spot welding. Proposed a method by using wavelets analysis to extract the aluminum alloy shock wave from the electrode force curve of resistance spot welding. A quality assurance technique for resistance spot welding using a neuro-fuzzy algorithm was proposed and obtained good results [16] These are some useful attempts combining the signal time-frequency analysis and pattern recognition together in resistance spot welding quality monitoring. The novel peak-to-peak amplitude and kurtosis index based wavelet decomposition and BP neural networks expressed a more targeted force signal and improved the identification accuracy
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