Pre-treatment of Selective Laser Melting (SLM) surfaces for thermal spray coating

Pre-treatment of Selective Laser Melting (SLM) surfaces for thermal spray coating

In this work, we investigated the deposition of thermal spray coatings onto additively manufactured parts obtained by Selective Laser Melting (SLM). SLM is indeed replacing conventional subtractive machining to produce diverse industrial parts; hence, it will become increasingly frequent to apply th...

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Bibliographic Details
Published in:Surface & coatings technology Vol. 441; p. 128533
Main Authors: Bolelli, Giovanni, Bonilauri, Maria Francesca, Sassatelli, Paolo, Bruno, Francesco, Franci, Riccardo, Pulci, Giovanni, Marra, Francesco, Paglia, Laura, Gazzadi, Gian Carlo, Frabboni, Stefano, Lusvarghi, Luca
Format: Journal Article
Language:English
Published: Elsevier B.V 15-07-2022
Subjects:
Cyclic impact
Electrochemical polarization
High Velocity Oxygen-Fuel (HVOF)
Roughness
Selective Laser Melting
Tensile adhesion
Cyclic impact
Selective Laser Melting
Tensile adhesion
Electrochemical polarization
High Velocity Oxygen-Fuel (HVOF)
Roughness
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Summary:In this work, we investigated the deposition of thermal spray coatings onto additively manufactured parts obtained by Selective Laser Melting (SLM). SLM is indeed replacing conventional subtractive machining to produce diverse industrial parts; hence, it will become increasingly frequent to apply thermal spray coatings onto SLM surfaces. Whilst grit-blasting is the most widely accepted process to prepare a conventionally machined part for a thermal spray coating, the unique surface texture of SLM surfaces might open new possibilities. As a case study, we chose High Velocity Oxygen-Fuel (HVOF) spraying of WC-10%Co4%Cr onto AISI 316 L SLM surfaces in three different conditions: “as built”, pickled, or grit-blasted. We also examined SLM surfaces grown along different directions: parallel, perpendicular, or inclined with respect to the build platform. The references were a machined and grit-blasted SLM part, and a grit-blasted stainless steel bulk. Dense coatings were obtained on every surface regardless of its roughness and pre-treatment. Electrochemical corrosion testing confirmed the low porosity of the layers. Tensile adhesion/cohesion strength was >70 MPa on both SLM and reference surfaces, but the presence of an oxide scale on as-built surfaces degraded the adhesion strength to some extent. Although TEM analysis showed occasional evidence of diffusion bonding between the coating and the oxide scale, cyclic impact tests revealed that the scale itself broke. Particularly strong adhesion was achieved with pickled surfaces; indeed, failure was only cohesive (i.e. within the coating) in both tensile and impact tests. In addition to mechanical interlocking to the rough surface profile, TEM showed widespread diffusion bonding to the clean metal. An SLM part might therefore need chemical activation but no subtractive machining before application of a thermal spray coating. The coating also exerts a levelling action toward the SLM surface, i.e. the coated surface is smoother than the as built one. [Display omitted] •WC-CoCr was HVOF-sprayed onto SLM AISI316 with different surface pre-treatments.•The microstructure and corrosion resistance of the coatings are independent of the substrate surface condition.•There is evidence of diffusion bonding to a clean (pickled, oxide-free) substrate.•Coatings onto pickled surfaces achieve tensile adhesion strength >75 MPa.•The coating has a levelling effect on the roughness of as-built SLM surfaces.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2022.128533