An Accurate Constitutive Model for AZ31B Magnesium Alloy during Superplastic Forming

Abstract: Accurate constitutive material models are essential for the realistic simulation of metal forming processes. However, for superplastic forming, mostly the material models found in the literature are based on fitting of the simple power law equation. In this study, an AZ31B constitutive model that takes into account microstructural evolution is introduced. This model takes into account grain growth and cavity formation in addition to strain and strain rate hardening. The model parameters were calibrated using t… Show more

“…They conclude that data that are not directly measured during the tests should be checked by numerical simulations and refined by an inverse analysis. In their contribution, Guangwen, et al [2] propose a constitutive model for Mg alloys that takes into account the grain growth and cavity formation. The model is calibrated by fitting data from free bulge tests and microstructure analyses.…”

Superplasticity and Superplastic Forming

“…They conclude that data that are not directly measured during the tests should be checked by numerical simulations and refined by an inverse analysis. In their contribution, Guangwen, et al [2] propose a constitutive model for Mg alloys that takes into account the grain growth and cavity formation. The model is calibrated by fitting data from free bulge tests and microstructure analyses.…”

Superplasticity and Superplastic Forming

Determination of biaxial stress–strain curves for superplastic materials by means of bulge forming tests at constant stress

A bulge-test based viscoplastic model for superplastic deformation behaviour of a magnesium alloy