WC-Co/316L stainless steel bonding enhancement by laser surface texturing and pressure-assisted sintering

abstract

WC-Co cutting tools are widely used in harsh conditions, but the brittleness of this material can limit their use. Joining steels to WC-Co can provide an alternative, by combining the toughness of steel with the high hardness and wear resistance of WC-Co. The creation of textures at the bonding interface is known to increase the adhesion between materials, through a mechanical interlocking effect and an increase in the contact area. In this sense, this work proposes the laser surface texturing of WC-Co green compacts with cross-hatched and circular micropatterns and subsequent pressure-assisted sintering of the textured and sintered WC-Co with 316L SS powder to improve the bonding between materials. Results showed that the bonding of the textured multi-material was successfully processed and an interdiffusion zone was formed at the bonding interface without the presence of detrimental compounds. The addition of textures showed a tendency to increase the shear bond strength, with the cross-hatched micropatterns generally showing a higher bonding strength than the circular micropatterns. This approach showed to have the potential to improve the bonding between materials, thus contributing to the development of novel multi-material WC-Co/316L stainless steel cutting tools with enhanced properties and performance.

keywords

MECHANICAL-PROPERTIES; INTERFACIAL MICROSTRUCTURE; CEMENTED CARBIDE; HOLDING TIME; WC; STRENGTH; BEHAVIOR; JOINT; ADHESION; TUNGSTEN

subject category

Automation & Control Systems; Engineering

authors

Basílio, L; Guimaraes, B; Carvalho, O; Fernandes, C; Figueiredo, D; Silva, F; Miranda, G

our authors

acknowledgements

The authors would like to thank Engineer Filipe Marques for his help in designing the multi-material shear test device used in this work.

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