Affiliation:
1. Department of Mechanical Engineering, Federation University Australia, Ballarat, Australia.
Abstract
Magnesium and its alloys are turning out to be
increasingly more utilized in the aviation and automobile industry
due to its low weight. The technology has endured numerous
enhancements enabling magnesium alloys to have a mechanical
performance close to aluminium alloys and prevention from
corrosion. This enables numerous potential applications for
magnesium alloys subjected to multiaxial fatigue. To perform the
plastic deformation on AZ31 alloy, we have utilised two
techniques of multilinear hardening methods. i) isotropic
hardening, ii) Kinematic hardening. To come up with an accurate
result, we leveraged ANSYS software to perform the simulation
with accuracy and precision. on arriving to the conclusion our
goal towards analysing the multilinear properties of the AZ31
alloy with two mesh size 0.4 and 0.6mm.
Publisher
Blue Eyes Intelligence Engineering and Sciences Engineering and Sciences Publication - BEIESP
Subject
Computer Science Applications,General Engineering,Environmental Engineering
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