Possibilities of CT Scanning as Analysis Method in Laser Additive Manufacturing

• Published in: Physics procedia Vol. 78; pp. 347 - 356
• Main Authors: Karme, Aleksis, Kallonen, Aki, Matilainen, Ville-Pekka, Piili, Heidi, Salminen, Antti
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 2015
• Subjects: analysis; CT scanning; Laser additive manufacturing; methodology; porosity; stainless steel; surface roughness; volumetric; 3D; stainless steel; porosity; volumetric; CT scanning; analysis; Laser additive manufacturing; methodology; surface roughness
• ISSN: 1875-3892; 1875-3892
• DOI: 10.1016/j.phpro.2015.11.049

Laser additive manufacturing is an established and constantly developing technique. Structural assessment should be a key component to ensure directed evolution towards higher level of manufacturing. The macroscopic properties of metallic structures are determined by their internal microscopic features, which are difficult to assess using conventional surface measuring methodologies. X-ray microtomography (CT) is a promising technique for three-dimensional non-destructive probing of internal composition and build of various materials. Aim of this study is to define the possibilities of using CT scanning as quality control method in LAM fabricated parts. Since the parts fabricated with LAM are very often used in high quality and accuracy demanding applications in various industries such as medical and aerospace, it is important to be able to define the accuracy of the build parts. The tubular stainless steel test specimens were 3D modelled, manufactured with a modified research AM equipment and imaged after manufacturing with a high-power, high-resolution CT scanner. 3D properties, such as surface texture and the amount and distribution of internal pores, were also evaluated in this study. Surface roughness was higher on the interior wall of the tube, and deviation from the model was systematically directed towards the central axis. Pore distribution showed clear organization and divided into two populations; one following the polygon model seams along both rims, and the other being associated with the concentric and equidistant movement path of the laser. Assessment of samples can enhance the fabrication by guiding the improvement of both modelling and manufacturing process.