Investigation of the Interface between Laser-Melted CoCr and a Stainless Steel Substrate

Recent advances in laser technologies offer significant flexibility in the additive manufacturing domain. Extensive work was focused on material processing using laser-directed energy deposition for repairing parts. This pilot study investigated the use of selective laser melting (SLM) for depositin...

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Published inMetals (Basel ) Vol. 12; no. 6; p. 965
Main Authors Cosma, Cosmin, Teusan, Christina, Gogola, Peter, Simion, Mihaela, Gabalcova, Zuzana, Trif, Adrian, Berce, Petru, Balc, Nicolae
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.06.2022
Subjects
adhesion strength
Adhesive strength
Alloys
CoCr
Corrosion resistance
Dissimilar materials
Dissimilar metals
Heat affected zone
Interfaces
Investigations
Laser beam melting
Lasers
Mechanical tests
Microhardness
Microporosity
Scanning electron microscopy
selective laser melting
Software
Solid solutions
Stainless steel
Stainless steels
Standard deviation
Substrates
Tomography
Ultimate tensile strength
X-ray computed tomography
X-rays
Germany
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Summary:Recent advances in laser technologies offer significant flexibility in the additive manufacturing domain. Extensive work was focused on material processing using laser-directed energy deposition for repairing parts. This pilot study investigated the use of selective laser melting (SLM) for depositing a superior material such as CoCr on an existing stainless steel base. The interface between these dissimilar materials was analyzed. During fabrication, both metals were gradually mixed in the liquid state as the first CoCr powder layer was melded on the steel base without obvious defects. According to SEM and EDAX, the heat-affected zone has a limited depth (<20 µm). XRD patterns recorded across the CoCr–304 interface show a homogenous mixture of γ(Fe) and α(Co) solid solutions. The microporosity calculated by CT was under 0.5%. Microhardness was measured at and near the interface region, showing that the intermixing zone has high hardness (470–480 HV1), which may be related to the fine-grained microstructure. Mechanical testing reveals that the adhesion strength at rupture is 35% higher compared with the ultimate tensile strength of 304 steel. This adhesion strength can be attributed to the complete melting of CoCr particles after laser irradiation and to the reduced thickness of the HAZ and the IZ.
ISSN:2075-4701
2075-4701
DOI:10.3390/met12060965