In situ TiC reinforced Ti6Al4V matrix composites manufactured via selective laser melting

PurposeCurrent methods for the preparation of composite powder feedstock for selective laser melting (SLM) rely on costly nanoparticles or yield inconsistent powder morphology. This study aims to develop a cost-effective Ti6Al4V-carbon feedstock, which preserves the parent Ti6Al4V particle's flowability, and produces in situ TiC-reinforced Ti6Al4V composites with superior traits.Design/methodology/approachTi6Al4V particles were directly mixed with graphite flakes in a planetary ball mill. This composite powder feedstock was used to manufacture in situ TiC-Ti6Al4V composites using various energy densities. Relative porosity, microstructure and hardness of the composites were evaluated for different SLM processing parameters.FindingsHomogeneously carbon-coated Ti6Al4V particles were produced by direct mixing. After SLM processing, in situ grown 100-500 nm size TiC nanoparticles were distributed within the alpha-martensite Ti6Al4V matrix. The formation of TiC particles refines the Ti6Al4V beta grain size. Relative density varied between 96.4% and 99.5% depending on the processing parameters. Hatch distance, exposure time and point distance were all effective on relative porosity change, whereas only exposure time and point distance were effective on hardness change.Originality/valueThis work introduces a novel, cost-effective powder feedstock preparation method for SLM manufacture of Ti6Al4V-TiC composites. The in situ SLM composites achieved in this study have high relative density values, well-dispersed TiC nanoparticles and increased hardness. In addition, the feedstock preparation method can be readily adapted for various matrix and reinforcement materials in future studies.

Automated summary

This study developed a cost-effective Ti6Al4V-carbon feedstock for in situ TiC-reinforced Ti6Al4V composites. Homogeneously carbon-coated Ti6Al4V particles were produced by direct mixing and in situ grown TiC nanoparticles effectively refined the Ti6Al4V beta grain size. The powder feedstock preparation method can be adapted for various matrix and reinforcement materials in future studies.