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- 2014 (16) (entfernen)
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- Beitrag zu einem Tagungsband (7)
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- Aktive Thermografie (3)
- Active thermography (2)
- CFRP (2)
- D. Thermal analysis (2)
- Flash (2)
- Flash thermography (2)
- Lockin (2)
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- 3D Tracking (1)
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Eingeladener Vortrag
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In dem von der Forschungsinitiative Zukunft Bau geförderten Projekt
zur „3D Kartierung von Bauwerksoberflächen“ wurden Verfahren zur Ortung von Rissen und Rissverläufen an historischen Gebäuden und Skulpturen weiterentwickelt und optimiert. Diese neuen Entwicklungen zur effizienten 3D Erfassung, Darstellung und zum Monitoring von Rissen basieren auf der aktiven Thermografie, einem Trackingsystem und Ultraschall.
Systematische Untersuchungen zur Zuverlässigkeit und zu Messgenauigkeiten der Messverfahren im Labor wurden durch den kombinierten Einsatz der Verfahren an Skulpturen aus historischem Beton an der Giebichensteinbrücke in Halle ergänzt.
Carbon fiber reinforced polymer (CFRP) specimens with artificial delaminations and with impact damage have been characterized using active thermography with flash excitation. Systematic investigations have been performed in four different experimental configurations of flash lamps and infrared (IR) camera in transmission as well as in reflection alignment. It is shown here that the diffusivities determined for the sound and for the damaged areas give a good measure for damage characterization. Although reflection measurements also give information about defect depth, reflection measurements from only one side are not sufficient for assessing the whole cross section of the specimens. Thus, depending on sample thickness the lateral size of damage could only be determined from reflections measurements from both sides or from transmission measurements. In this paper, measurement accuracy and limits of flash thermography for the investigation of CFRP specimens are presented in detail together with quantitative data concerning the defects.
Standards for the application of flash thermography as well as of lock-in thermography are urgently required.
Both methods are applied more and more often in research and industry, but still extensive validation procedures are required for each individual application. In this paper, the results of two research projects concerning the validation and standardisation of both methods are presented. This includes results of a detailed study of the influence of measurements parameters on flash thermography, of the comparison of the lateral resolution obtained with flash and lock-in thermography and the description of a draft standard for flash thermography.
Eine Arbeitsgruppe der BAM in der Abteilung für Zerstörungsfreie Prüfung forscht seit 2011 an verschiedenen technischen Fragestellungen, die sich aus dem thermografischen Lösungsansatz ergeben. Zum Beispiel werden spezielle Prüfkörper aus GFK im Labor unter dem Gesichtspunkt untersucht, inwieweit (materielle) innere Strukturen und äußerlich nicht sichtbare Schäden mit Thermografie offenbart werden können. Hierbei werden verschiedene Anregungs- und Auswertungstechniken auf ihre Eignung für diese Problemstellung untersucht. Der folgende Beitrag erläutert einige technische Schwierigkeiten bei der praktischen Anwendung der geplanten Inspektionsmethode und stellt einen erfolgversprechenden Lösungsansatz vor.
We present a systematic study on the performance of laser-thermography for the detection of surface cracks in metallic components. Scanning a metallic surface with laser causes local heating that is mapped simultaneously by an IR-camera and allows identifying cracks with sub-µm openings. The detectability, however, depends on a number of acquisition parameters (e.g. scanning speed, laser power, IR-camera resolution) that typically relate on each other. Most importantly, the detection-sensitivity of surface breaking cracks is given by a particular combination for the acquisition parameter values. As a result, this sensitivity is adaptable within wide ranges allowing the detection of cracks with openings ranging from 200 to 0.1 µm at testing speeds of 100 to 0.05 cm²/s. By examining artificial as well as fatigue cracks, we demonstrate that the method can be even applied to shiny surfaces with no need of pretreatments, which makes it an entirely contactless, remote and automatable NDT technique. A comparison with magnetic particle testing shows that laser-thermography has the potential to become a strong competitor to conventional surface inspection methods in the future.
Flash lamps are widely used excitation sources in the field of non-destructive testing with active thermography. Though the realized energy density in front of the investigated object is a significant factor with regard to detection sensitivity, only few data concerning this issue have been published so far. It is shown here that local energy densities can be estimated by means of a simple metal plate, which exhibits a certain temperature increase after flash excitation. After discussing the underlying calorimetric principle the sensor concept is reviewed using constant blackbody radiation and short laser pulses, since both kinds of sources generate known energy densities. The relative uncertainty of measurements of the energy density is found to be in the range of 10%. The last part of the present paper describes an application for characterizing the radiation of a usual 6 kJ flash lamp. The energy conversion efficiency was found to be only about 11%.