Validating a nonlinear elastic model for predicting the nonlinear mechanical behaviour of plasma sprayed YSZ coatings under tension

Abstract

Plasma sprayed ceramics exhibit nonlinear stress-strain behaviour under tension and compression due to porosity and microcracks existing in their microstructure. The modelling done in the previous works, was reported under compression and tensile loading of YSZ. In the present study, it was extended to the effect of microstructural parameters on tensile behaviour of YSZ and validates the experimental results and introduces the variation of stress with microstructural parameters. In this paper, the nonlinear tensile behaviour of YSZ plasma sprayed material is modelled phenomenologically by obtaining a relationship between microcrack density and tensile strength . The governing equations in this model are used from the previous works done on compression behaviour of plasma sprayed materials. In the present work, an empirical relationship between tensile stress and crack density is proposed based on the experimental stress strain curves obtained from the uniaxial tensile tests on freestanding YSZ coating. The variations in maximum strength corresponding to a strain and elastic modulus were also studied for different microcrack densities and porosity. Further, the effect of porosity and crack density on mechanical behaviour of YSZ coatings is extrapolated at different combinations of porosity and crack densities ranging from 0.1–0.5 per unit volume. The result obtained using the proposed numerical model was found to be in good agreement with the obtained experimental results and the non-linear tensile behaviour of YSZ could be modelled phenomenologically. • A phenomenological model replicating the experimental behaviour of YSZ coatings in tension. • An empirical relation between the microcrack density and the tensile stress based on tensile experimental results. • Effect of tensile properties on microstructural parameters of YSZ proposed numerically.