Microstructural Development and Technical Challenges in Laser Additive Manufacturing: Case Study with a 316L Industrial Part

Additive manufacturing (AM) brings disruptive changes to the ways parts, and products are designed, fabricated, tested, qualified, inspected, marketed, and sold. These changes introduce novel technical challenges and concerns arising from the maturity and diversity of today’s AM processes, feedstock...

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Bibliographic Details
Published in:Metallurgical and materials transactions. B, Process metallurgy and materials processing science Process metallurgy and materials processing science, 2015-08, Vol.46 (4), p.1654-1665
Main Authors: Marya, Manuel, Singh, Virendra, Marya, Surendar, Hascoet, Jean Yves
Format: Article
Language:English
Subjects:
Additives
Austenitic stainless steels
Case studies
Characterization and Evaluation of Materials
Chemistry and Materials Science
Cladding
Feedstock
Heat resistant steels
Lasers
Manufacturing
Materials Science
Metallic Materials
Metallurgy
Microstructure
Nanotechnology
Process parameters
Stainless steel
Structural Materials
Surfaces and Interfaces
Thin Films
Vents
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Summary:Additive manufacturing (AM) brings disruptive changes to the ways parts, and products are designed, fabricated, tested, qualified, inspected, marketed, and sold. These changes introduce novel technical challenges and concerns arising from the maturity and diversity of today’s AM processes, feedstock materials, and process parameter interactions. AM bears a resemblance with laser and electron beam welding in the so-called conduction mode, which involves a multitude of dynamic physical events between the projected feedstock and a moving heat source that eventually influence AM part properties. For this paper, an air vent was selected for its thin-walled, hollow, and variable cross section, and limited size. The studied air vents, randomly selected from a qualification batch, were fabricated out of 316L stainless steel using a 4 kW fiber laser powder-fed AM system, referred to as construction laser additive direct (CLAD). These were systematically characterized by microhardness indentation, visual examination, optical and scanning electron microscopy, and electron-back-scattering diffraction in order to determine AM part suitability for service and also broadly discuss metallurgical phenomena. The paper then briefly expands the discussion to include additional engineering alloys and further analyze relationships between AM process parameters and AM part properties, consistently utilizing past experience with the same powder-fed CLAD 3D printer, the well-established science and technology of welding and joining, and recent publications on additive manufacturing.
ISSN:1073-5615
1543-1916
DOI:10.1007/s11663-015-0310-5