Analysis of the effects of microstructure heterogeneity on the mechanical behavior of additively manufactured Ti6Al4V using mechanics of structure genome

In this paper, the mechanics of structure genome (MSG) is introduced as a computationally efficient multiscale modeling approach to predict the effects of heterogeneous microstructure on the mechanical properties of AMed Ti6Al4V. Homogenization using MSG is conducted on a structure genome (SG) that incorporates the basic building details of the heterogeneous microstructure from the grain level and the modeling is carried out using the constitutive behaviors of the constituent phases with the evolution of microstructure without redoing homogenization. The microstructure-based MSG was employed to simulate the compression and tensile behaviors of AMed Ti6Al4V based on their microstructures. The predicted true stress-strain curves were then compared to the corresponding curves acquired from experimental testing. The simulation results matched well with the experimental results and showed the existence of martensite to be the reason behind the high strength in the AMed Ti6Al4V and the reduced ductility. Additionally, the inclusion of the microstructure in the SG allowed the MSG simulations to conform to the experiments in showing the reductions in the strengths and improvements in the maximum elongations in the AMed+heat treated Ti6Al4V due to grain coarsening and absence of martensite. (C) 2021 The Author(s). Published by Elsevier Ltd.

Automated summary

By utilizing MSG to simulate compression and tensile behaviors, the predicted results matched well with experimental data, indicating the presence of martensite as the reason behind the high strength and reduced ductility in AMed Ti6Al4V. Moreover, considering the microstructure in SG allowed the MSG simulations to align with experiments, showing reductions in strength and improvements in maximum elongations in AMed+heat treated Ti6Al4V due to grain coarsening and absence of martensite.