Liu, Cen , Goel, Saurav , Llavori, Inigo , Stolf, Pietro , Giusca, Claudiu L. , Zabala, Alaitz , Kohlscheen, Joern , Paiva, Jose Mario , ENDRINO ARMENTEROS, JOSÉ LUIS, Veldhuis, Stephen C. , Rabinovich, German S. Fox
Si
J. Mech. Behav. Biomed. Mater.
Article
Científica
3.372
0.944
01/09/2019
000483636600016
2-s2.0-85065731770
Use of an alpha-beta (multiphase HCP-BCC) titanium alloy, Ti6Al4V, is ubiquitous in a wide range of engineering applications. The previous decade of finite element analysis research on various titanium alloys for numerous biomedical applications especially in the field of orthopedics has led to the development of more than half a dozen material constitutive models, with no comparison available between them. Part of this problem stems from the complexity of developing a vectorised user-defined material subroutine (VUMAT) and the different conditions (strain rate, temperature and composition of material) in which these models are experimentally informed. This paper examines the extant literature to review these models and provides quantitative bench marking against the tabulated material model and a power law model of Ti6Al4V taking the test case of a uniaxial tensile and cutting simulation.
Ti6Al4V; Material models; Johnson-cook model; Zerilli armstrong model; Voyiadjis-abed model; Tensile test; Cutting