Abstract
The effectiveness of pulsed thermography (PT) for detecting delamination in carbon fiber-reinforced polymer (CFRP) plates has been widely verified. However, delaminations are usually characterized by weak visibility due to the influences of inspection factors and the delaminations with weak visibility are easily missed in real inspections. In this study, by introducing a deep learning algorithm—stacked autoencoder (SAE)—to PT, we propose a novel approach (SAE-PT) to enhance the visibility of delaminations. Based on the ability of SAE to learn unsupervised features from data, the thermal features of delaminations are extracted from the raw thermograms. The extracted features are then employed to construct SAE images, in which the visibility of delaminations is expected to be enhanced. To test the performance of SAE-PT, we inspected CFRP plates with prefabricated delaminations. By implementing SAE-PT on the raw inspection data, the delaminations were more clearly indicated in the constructed SAE images. We also compare SAE-PT to the widely used principal component thermography (PCT) method to further verify the validity of the proposed approach. The results reveal that compared to PCT, SAE-PT can show delaminations in CFRP with higher contrast. By effectively enhancing the delamination visibility, SAE-PT thus has potential for improving the inspection accuracy of PT for non-destructive testing (NDT) of CFRP.
Highlights
Carbon fiber-reinforced polymer (CFRP) is extensively applied in structural engineering due to its high strength to weight ratio, high stiffness and powerful corrosion resistance [1,2,3,4]
Since the occur delaminations arethermograms located at different depths in specimenThe
Experiments on a carbon fiber-reinforced polymer (CFRP) plate with prefabricated delaminations demonstrate the efficacy of stacked autoencoder (SAE)-pulsed thermography (PT)
Summary
Carbon fiber-reinforced polymer (CFRP) is extensively applied in structural engineering due to its high strength to weight ratio, high stiffness and powerful corrosion resistance [1,2,3,4]. Internal and invisible defects can significantly deteriorate the residual stiffness and load-bearing capacity of CFRP [5,6,7,8], detecting such defects of CFRP is critical to guarantee the safety of CFRP structures. A delamination, which is usually the result of an impact, is one typical kind of internal and invisible defect seen in CFRP. Pulsed thermography (PT), which is an important non-destructive testing (NDT) technique, has been verified effective for detecting delamination in CFRP [9,10,11]. The delamination visibility during PT is significantly influenced by some factors, including the performance of the infrared imager, the dimension and location of a delamination, and the quantity of heat energy injected
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