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Pawlikowski, Marek
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Publications (7/7 displayed)
- 2024An experimental and theoretical investigation on the hyper-viscoelasticity of polyamide 12 produced by selective laser sinteringcitations
- 2024New approach to alpha-titanium mechanical properties enhancement by means of thermoplastic deformation in mid-temperature range
- 2023Modeling of hyperelasticity in polyamide 12 produced by selective laser sinteringcitations
- 2019The macroscopic behavior of pantographic sheets depends mainly on their microstructure: experimental evidence and qualitative analysis of damage in metallic specimenscitations
- 2019Pantographic metamaterials: An example of mathematically driven design and of its technological challengescitations
- 2018Enhanced Piola–Hencky discrete models for pantographic sheets with pivots without deformation energy: Numerics and experimentscitations
- 2018Enhanced Piola–Hencky discrete models for pantographic sheets with pivots without deformation energy: numerics and experimentscitations
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article
An experimental and theoretical investigation on the hyper-viscoelasticity of polyamide 12 produced by selective laser sintering
Abstract
<jats:p>Polyamide 12 (PA12) is vastly utilized in many additive manufacturing methods, such as Selective Laser Sintering (SLS), and a better understanding of its mechanical behaviors promotes available knowledge on the behaviors of 3D-printed parts made from this polymer. In this paper, SLS-produced standard tensile specimens are studied under monotonic and cyclic tension tests, as well as stress relaxation experiments, and the obtained force-displacement responses are shown to be consistent with a hyper-viscoelastic material model. This finding is also observed in typical pantographic structures produced by the same manufacturing parameters. To propose a constitutive model for predicting these behaviors, the convolution integral of a strain-dependent function and a time-dependent function is developed where the material parameters are determined with the use of both short-term and long-term responses of the specimens. Numerical results of the presented model for standard test specimens are shown to be in good agreements with the experimental ones under various loading conditions. To prove the capabilities of the proposed model in studying any SLS-produced part, finite element implementation of the constitutive equations is shown to provide numerical results in agreement with the empirical findings for tensile loading of the 3D-printed pantographic structure.</jats:p>