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Constitutive modelling of polylactic acid at large deformation using multiaxial strains
Sweeney, John Thompson, Glen P. Barker, David Coates, Philip D.
Sweeney, John
Thompson, Glen P.
Barker, David
Coates, Philip D.
Publication Date
2021-08
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© 2021 by the authors.
Licensee MDPI, Basel, Switzerland.
This article is an open access article
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Attribution (CC BY) license (https://
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4.0/).
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2021-08-27
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Abstract
Sheet specimens of a PLLA-based polymer have been extended at a temperature near to the glass transition in both uniaxial and planar tension, with stress relaxation observed for some time after reaching the final strain. Both axial and transverse stresses were recorded in the planar experiments. In all cases during loading, yielding at small strain was followed by a drop in true stress and then strain hardening. This was followed by stress relaxation at constant strain, during which stress dropped to reach an effectively constant level. Stresses were modelled as steady state and transient components. Steady-state components were identified with the long-term stress in stress relaxation and associated with an elastic component of the model. Transient stresses were modelled using Eyring mechanisms. The greater part of the stress during strain hardening was associated with dissipative Eyring processes. The model was successful in predicting stresses in both uniaxial and planar extension over a limited range of strain rate.
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Citation
Sweeney J, Spencer P, Thompson G et al (2021) Constitutive modelling of polylactic acid at large deformation using multiaxial strains. Polymers. 13(17): 2967.
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