Investigation of laser powder bed fusion manufacturing and post-processing for surface quality of as-built 17-4PH stainless steel

Laser powder bed fusion (LPBF) technique enables to manufacture complex parts and difficult-to-cut materials with saving the material costs and manufacturing time. However, there still has been technical challenges and qualities issues for LPBF products to be used in engineering applications. In ord...

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Bibliographic Details
Published in:Surface & coatings technology 2021-09, Vol.422, p.127492, Article 127492
Main Authors: Yang, Kyung-Tae, Kim, Min-Kyeom, Kim, Dongwon, Suhr, Jonghwan
Format: Article
Language:English
Subjects:
Appearance quality
Bones
Defects
Densification
Flux density
Gloss
Hot isostatic pressing
Jewelry
Laser powder bed fusion
Manufacturing
Martensitic stainless steels
Mechanical polishing
Physical vapor deposition
Post-production processing
Powder beds
Precipitation hardening steels
Rapid prototyping
Stainless steel
Surface energy
Surface properties
Surface roughness
Touch sensation
Vapor deposition coating
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Summary:Laser powder bed fusion (LPBF) technique enables to manufacture complex parts and difficult-to-cut materials with saving the material costs and manufacturing time. However, there still has been technical challenges and qualities issues for LPBF products to be used in engineering applications. In order to obtain the high-quality surface products including minimal defects and voids, this study systematically investigated and determined LPBF manufacturing process and post-processing using a 17-4PH stainless steel. It was experimentally found that design of LPBF process conditions could only attain the densification of as-built products, while surface qualities were not as good as commercial products. Therefore, the post-processing was indispensably explored by conducting mechanical polishing, physical vapor deposition coating, and hot isostatic pressing for the high surface quality and densification of as-built specimens. The surface qualities of the specimens, fabricated with optimum volumetric energy density of 97.66 J/mm3, were carefully characterized for their surface roughness, gloss, surface energy and frictional behaviors. After the post-processing, the surface roughness and gloss were dramatically improved by more than 800% over the as-built parts, and the porosity was reduced by up to 57.8%. This study demonstrates that optimum LPBF process and post-processing could enhance the qualities of LPBF products up to the same or beyond level of commercial products, comparing the defects, roughness, gloss, and touch sensation. The LPBF technique coupled with post-processing, if optimized, can show the great potential for the use in a wide variety of real-world engineering applications including mobile phones, jewelry, electronic appliances, artificial teeth and bones. •3D printed surface of 17-4PH stainless steel was experimentally investigated.•Feasible process parameters were determined by characterizing the surface and defects.•Post processing techniques (polishing, PVD and HIP) confirmed high quality surface.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2021.127492