X. Maldague scite author profile

X. Maldague

2Publications

9Citation Statements Received

12Citation Statements Given

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The influence of surface coatings on the differences between numerical and experimental results for samples subjected to pulse thermography examination

Susa¹,

Maldague²,

Svaic³

et al. 2008

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This paper presents the analysis of the influence that black surface paint layers have on the differences in the results obtained from numerical modelling and those obtained experimentally. Surface paints are commonly used for the purposes of pulse experiments in order to increase the sample surface emissivity and help enhance the signal obtained. The paper argues that it is important to include these paint layers in the numerical analysis either directly, as additional material layer, or alternatively, to estimate their influence and take it into account when comparing the corresponding results. IntroductionInfrared thermography is a method of non-contact surface temperature measurement. The measurement principle is based on the radiation law, which puts into relation the energy radiated from the object's surface and its surface temperature. Two different surfaces do not necessarily radiate the same amount of energy when they are at the same temperature. The amount of energy emitted depends also on the object surface emissivity, a coefficient ranging from 0 to 1 and putting into relation the energy emitted from the real object surface at a given temperature and the energy that the ideal blackbody surface would emit at the same temperature. The higher the surface emissivity, the closer the real object surface to the ideal blackbody surface and the higher the quantity of energy emitted at a given temperature.In non-destructive testing, more often than not, surface characteristics of materials that are subject to pulse thermography (or other IR thermography) testing procedures, have poor surface emissivity properties. In the case of different metals, such as aluminium and steel, emissivity values range from 0.1 to 0.4 [1]. Knowing already that the thermal signal has a relatively low signal to noise ratio (SNR), especially when the temperatures obtained are not much higher with respect to room temperature, different strategies of signal enhancement are commonly used [2]. High emissivity surface paints (ε>0.95) are applied on tested sample surfaces prior to experiment in order to increase the signal that is emitted from the sample surface and captured by the IR camera. Those layers of paint are often neglected when thermal contrast analysis is made, assuming therefore that their influence on the experimental results is negligible. An experiment, in which a metal flat-bottom hole sample plate was tested, revealed large differences when the results were compared between the black-painted region and a small region where the surface black paint fell off over the time. This observation encouraged further research which was directed towards a Plexiglass model. It was expected that Plexiglass was to be easier to work with due to its lower conductivity and, therefore, to the slower rate at which the changes in the sample appear during the experiment, thus making it easier to see the differences. As a result of that research, this article demonstrates to what extent the surface paints can influence the maximum therma...

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Application of the Source Distribution Image (SDI) procedure for porosity detection in honeycomb structures

Susa¹,

Maldague²,

Boras³

2010

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The article presents the results of Pulse Thermography experiment applied on a complex multi-layer honeycombbased sample. The sample was a part of the aircraft and it was replaced because of the appearance of porosity in the adhesive layer of the assembly. The exact location, shape and level of porosity were not known. Non-uniform heating of the sample was limiting factor for the quality of the analysis results. The difficulty in determining the area where the porosity appeared was overcome using the Source Distribution Image procedure which takes into account the distribution of the heating non-uniformity when thermal image of the sample is analysed. The results obtained matched well the results obtained using ultrasonic inspection.

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X. Maldague

The influence of surface coatings on the differences between numerical and experimental results for samples subjected to pulse thermography examination

Application of the Source Distribution Image (SDI) procedure for porosity detection in honeycomb structures

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