Selective Laser Melting is utilized to build metallic parts directly from CAD-Data by solidification of thin powder layers through application of a fast scanning laser beam. In this study layerwise monitoring of the temperature distribution is used to gather information about the process stability and the resulting part quality. The heat distribution varies with different kinds of parameters including scan vector length, laser power, layer thickness and inter-part distance in the job layout which in turn influence the resulting part quality. By integration of an off-axis mounted uncooled thermal detector the solidification as well as the layer deposition are monitored and evaluated. Errors in the generation of new powder layers usually result in a locally varying layer thickness that may cause poor part quality. For effect quantification, the locally applied layer thickness is determined by evaluating the heat-up of the newly deposited powder. During the solidification process space and time-resolved data is used to characterize the zone of elevated temperatures and to derive locally varying heat dissipation properties. Potential quality indicators are evaluated and correlated to the resulting part quality: Thermal diffusivity is derived from a simplified heat dissipation model and evaluated for every pixel and cool-down phase of a layer. This allows the quantification of expected material homogeneity properties. Maximum temperature and time above certain temperatures are measured in order to detect hot spots or delamination issues that may cause a process breakdown. Furthermore, a method for quantification of sputter activity is presented. Since high sputter activity indicates unstable melt dynamics this can be used to identify parameter drifts, improper atmospheric conditions or material binding errors. The resulting surface structure after solidification complicates temperature determination on the one hand but enables the detection of potential surface defects on the other hand. These issues and proper key figures for thermographic monitoring of the Selective Laser Melting process are discussed in the paper. Even though microbolometric temperature measurement is limited to repetition rates in the Hz-regime and sub megapixel resolution, current results show the feasibility of process surveillance by thermography for a limited section of the building platform in a commercial system.
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31 March 2015
41ST ANNUAL REVIEW OF PROGRESS IN QUANTITATIVE NONDESTRUCTIVE EVALUATION: Volume 34
20–25 July 2014
Boise, Idaho
Research Article|
March 31 2015
Thermographic process monitoring in powderbed based additive manufacturing
Harald Krauss;
Harald Krauss
AMLab, iwb Application Center Augsburg, Technische Universität München,
Germany
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Thomas Zeugner;
Thomas Zeugner
Augsburg University,
Germany
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Michael F. Zaeh
Michael F. Zaeh
AMLab, iwb Application Center Augsburg, Technische Universität München,
Germany
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Harald Krauss
Thomas Zeugner
Michael F. Zaeh
AMLab, iwb Application Center Augsburg, Technische Universität München,
Germany
AIP Conf. Proc. 1650, 177–183 (2015)
Citation
Harald Krauss, Thomas Zeugner, Michael F. Zaeh; Thermographic process monitoring in powderbed based additive manufacturing. AIP Conf. Proc. 31 March 2015; 1650 (1): 177–183. https://doi.org/10.1063/1.4914608
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