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Numerical and experimental investigation of the geometry dependent layer-wise evolution of temperature during laser powder bed fusion of Ti–6Al–4V
Citation Link: https://doi.org/10.15480/882.4911
Publikationstyp
Journal Article
Date Issued
2023-08
Sprache
English
Institut
TORE-DOI
Volume
8
Issue
5
Start Page
961
End Page
975
Citation
Progress in Additive Manufacturing 8 (5): 961-975 (2023-10)
Publisher DOI
Scopus ID
Publisher
Springer International Publishing AG
Laser powder bed fusion (L-PBF) is currently the additive manufacturing process with the widest industrial use for metal parts. Yet some hurdles persist on the way to a widespread industrial serial production, with reproducibility of the process and the resulting part properties being a major concern. As the geometry changes, so do the local boundary conditions for heat dissipation. Consequently, the use of global, geometry-independent processing parameters, which are today’s state of the art, may result in varying part properties or even defects. This paper presents a numerical simulation as a method to predict the geometry-dependent temperature evolution during the build. For demonstration, an overhang structure with varying angles towards the build platform was manufactured using Ti–6Al–4V. A calibrated infrared camera was integrated into a commercial L-PBF system to measure the temperature evolution over time for a total build height of 10 mm, and the results are used for validation of the simulation. It is shown that the simulation is capable of predicting the temperature between layers. The deviations between simulation and measurement remain in single digit range for smaller overhang structures (90°, 60° and 45°). For large overhang structures (30°), the simulation tends to over-predict the temperatures up to 15 °C. Experiments with varying process parameters showed the feasibility of energy reduction as compensation of the heat accumulation produced by overhang structures.
Subjects
Feedforward control
Heat development
L-PBF
Numerical simulation
Varying process parameter
DDC Class
600: Technik
Publication version
publishedVersion
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s40964-022-00370-y-2.pdf
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5.23 MB
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Adobe PDF