Thickness measurement by two-sided step-heating thermal imaging

Infrared thermal imaging is a promising nondestructive technique for thickness prediction. However, it is usually thought to be only appropriate for testing the thickness of thin objects or near-surface structures. In this study, we present a new two-sided step-heating thermal imaging method which e...

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Veröffentlicht in:	Review of scientific instruments 2018-01, Vol.89 (1), p.014902-014902
Hauptverfasser:	Li, Xiaoli, Tao, Ning, Sun, J. G., Zhang, Cunlin, Zhao, Yuejin
Format:	Artikel
Sprache:	eng
Schlagworte:	Heat detection Infrared heating Infrared imaging Nondestructive testing Reliability analysis Scientific apparatus & instruments Thermal imaging Thermography Thickness measurement
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creator	Li, Xiaoli Tao, Ning Sun, J. G. Zhang, Cunlin Zhao, Yuejin
description	Infrared thermal imaging is a promising nondestructive technique for thickness prediction. However, it is usually thought to be only appropriate for testing the thickness of thin objects or near-surface structures. In this study, we present a new two-sided step-heating thermal imaging method which employed a low-cost portable halogen lamp as the heating source and verified it with two stainless steel step wedges with thicknesses ranging from 5 mm to 24 mm. We first derived the one-dimensional step-heating thermography theory with the consideration of warm-up time of the lamp, and then applied the nonlinear regression method to fit the experimental data by the derived function to determine the thickness. After evaluating the reliability and accuracy of the experimental results, we concluded that this method is capable of testing thick objects. In addition, we provided the criterions for both the required data length and the applicable thickness range of the testing material. It is evident that this method will broaden the thermal imaging application for thickness measurement.
doi_str_mv	10.1063/1.5009727
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After evaluating the reliability and accuracy of the experimental results, we concluded that this method is capable of testing thick objects. In addition, we provided the criterions for both the required data length and the applicable thickness range of the testing material. 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After evaluating the reliability and accuracy of the experimental results, we concluded that this method is capable of testing thick objects. In addition, we provided the criterions for both the required data length and the applicable thickness range of the testing material. 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subjects	Heat detection Infrared heating Infrared imaging Nondestructive testing Reliability analysis Scientific apparatus & instruments Thermal imaging Thermography Thickness measurement
title	Thickness measurement by two-sided step-heating thermal imaging
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