Litcius/Paper detail

Crystal plasticity finite element simulations on extruded Mg-10Gd rod with texture gradient

Jaeseong Lee, D. Steglich, Youngung Jeong

2024Journal of Magnesium and Alloys12 citationsDOIOpen Access PDF

Abstract

• Mg-10Gd rod produced for vascular stents was investigated. • CP-FEM simulation was used to validate the mechanical behavior in hoop direction. • Simulated force responses and texture were in good agreement with experiments. The mechanical properties of an extruded Mg-10Gd sample, specifically designed for vascular stents, are crucial for predicting its behavior under service conditions. Achieving homogeneous stresses in the hoop direction, essential for characterizing vascular stents, poses challenges in experimental testing based on standard specimens featuring a reduced cross section. This study utilizes an elasto-visco-plastic self-consistent polycrystal model (ΔEVPSC) with the predominant twinning reorientation (PTR) scheme as a numerical tool, offering an alternative to mechanical testing. For verification, various mechanical experiments, such as uniaxial tension, compression, notched-bar tension, three-point bending, and C-ring compression tests, were conducted. The resulting force vs. displacement curves and textures were then compared with those based on the ΔEVPSC model. The computational model's significance is highlighted by simulation results demonstrating that the differential hardening along with a weak strength differential effect observed in the Mg-10Gd sample is a result of the interplay between micromechanical deformation mechanisms and deformation-induced texture evolution. Furthermore, the study highlights that incorporating the axisymmetric texture from the as-received material incorporating the measured texture gradient significantly improves predictive accuracy on the strength in the hoop direction. Ultimately, the findings suggest that the ΔEVPSC model can effectively predict the mechanical behavior resulting from loading scenarios that are impossible to realize experimentally, emphasizing its valuable contribution as a digital twin.

Topics & Concepts

Materials scienceCrystal plasticityFinite element methodTexture (cosmology)Composite materialPlasticityStructural engineeringComputer scienceArtificial intelligenceImage (mathematics)EngineeringMagnesium Alloys: Properties and ApplicationsMetal and Thin Film MechanicsMicrostructure and mechanical properties