The influences of melting degree of TiC reinforcements on microstructure and mechanical properties of laser direct deposited Ti6Al4V-TiC composites

Abstract

This study is concerned with the influences of melting degree of embedded TiC reinforcements on microstructure and mechanical properties of laser direct deposited Ti6Al4V-TiC composites and a functionally graded material. The melting degree of embedded TiC was controlled by the input laser energy density and the added TiC content. The formation of detrimental primary dendritic TiC grains was successfully avoided by properly adjusting the deposition conditions and the particle size range of TiC reinforcements. The resultant compression test revealed the ultimate strength increasing from 1381±19MPa to 1636±23MPa as the premixed TiC content increased from 0 to 15vol% while a true strain of 0.141±0.002 was still retained for 15vol% TiC. The primary strengthening mechanism for composites with the most melting control of TiC is the solid solution strengthening induced by carbon, while that for the least melting control is dominated by the unmelted TiC particulates and the refined microstructure resulting from the resolidified carbides. The defect-free functionally graded Ti6Al4V-TiC with 0 to 40vol% TiC achieved an increased hardness from HRC ~39 to HRC ~65.