Akshay Chaudhari scite author profile

Additive manufacturing of stainless steel is becoming increasingly accessible, allowing for the customisation of structure and surface characteristics; there is little guidance for the post-processing of these metals. We carried out this study to ascertain the effects of various combinations of post-processing methods on the surface of an additively manufactured stainless steel 316L lattice. We also characterized the nature of residual surface particles found after these processes via energy-dispersive X-ray spectroscopy. Finally, we measured the surface roughness of the post-processing lattices via digital microscopy. The native lattices had a predictably high surface roughness from partially molten particles. Sandblasting effectively removed this but damaged the surface, introducing a peel-off layer, as well as leaving surface residue from the glass beads used. The addition of either abrasive polishing or electropolishing removed the peel-off layer but introduced other surface deficiencies making it more susceptible to corrosion. Finally, when electropolishing was performed after the above processes, there was a significant reduction in residual surface particles. The constitution of the particulate debris as well as the lattice surface roughness following each post-processing method varied, with potential implications for clinical use. The work provides a good base for future development of post-processing methods for additively manufactured stainless steel.

show abstract

Surface quality and material removal in magnetic abrasive finishing of selective laser melted 316L stainless steel

Zhang

Chaudhari

Wang

2019

Journal of Manufacturing Processes

118

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Micromachining of ferrous metal with an ion implanted diamond cutting tool

Lee

Lüder

et al. 2019

Carbon

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Investigation on the microstructure and machinability of ASTM A131 steel manufactured by directed energy deposition

Bai

Chaudhari

Wang

2020

Journal of Materials Processing Technology

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A novel magnetically driven polishing technique for internal surface finishing

Zhang

Wang

et al. 2018

Precision Engineering

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