A Testbed for Investigation of Selective Laser Melting at Elevated Atmospheric Pressure

Metal additive manufacturing (AM) by laser powder bed fusion (L-PBF) builds upon fundamentals established in the field of laser welding which include the influence of gas and plume dynamics on weld depth and quality. L-PBF demands a thorough investigation of the complex thermophysical phenomena that...

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Bibliographic Details
Published in:arXiv.org 2021-07
Main Authors: Griggs, David A, Gibbs, Jonathan S, Baker, Stuart P, Penny, Ryan W, Feldmann, Martin C, Hart, A John
Format: Article
Language:English
Subjects:
Aspect ratio
Fluid dynamics
Gas flow
Gas pressure
Laser beam melting
Laser beam welding
Lasers
Metal plates
Metal powders
Open architectures
Powder beds
Pressure effects
Rapid prototyping
Test stands
Vapor pressure
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Summary:Metal additive manufacturing (AM) by laser powder bed fusion (L-PBF) builds upon fundamentals established in the field of laser welding which include the influence of gas and plume dynamics on weld depth and quality. L-PBF demands a thorough investigation of the complex thermophysical phenomena that occur where the laser interacts with the metal powder bed. In particular, melt pool turbulence and evaporation are influenced by the ambient gas chemistry and pressure. This paper presents the design and validation of high pressure laser melting (HPLM) testbed; this accommodates bare metal plate samples as well as manually-coated single powder layers, and operates at up to 300 psig. The open architecture of this testbed allows for full control of all relevant laser parameters in addition to ambient gas pressure and gas flow over the build area. Representative melt tracks and rasters on bare plate and powder are examined in order to validate system performance, and preliminary analysis concludes that pressure has a significant impact on melt pool aspect ratio. The HPLM system thus enables careful study pressure effects on processing of common L-PBF materials, and can be applied in the future to materials that are challenging to process under ambient pressure, such as those with high vapor pressures.
ISSN:2331-8422