A non-linear orthotropic hydrocode model for ultra-high molecular weight polyethylene in impact simulations

This paper presents detailed experimental characterization of quasi-static anisotropic directional strength properties as well as the shock behavior of ultra-high molecular weight polyethylene (UHMWPE) for the development of an advanced material model for this class of materials. Specifically, we co...

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Veröffentlicht in:International journal of impact engineering 2015-01, Vol.75, p.110-122
Hauptverfasser: Lässig, Torsten, Nguyen, Long, May, Michael, Riedel, Werner, Heisserer, Ulrich, van der Werff, Harm, Hiermaier, Stefan
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container_end_page 122
container_issue
container_start_page 110
container_title International journal of impact engineering
container_volume 75
creator Lässig, Torsten
Nguyen, Long
May, Michael
Riedel, Werner
Heisserer, Ulrich
van der Werff, Harm
Hiermaier, Stefan
description This paper presents detailed experimental characterization of quasi-static anisotropic directional strength properties as well as the shock behavior of ultra-high molecular weight polyethylene (UHMWPE) for the development of an advanced material model for this class of materials. Specifically, we consider Dyneema® HB26 – pressed from uni-directional (UD) tapes in a 0/90° stacking sequence. A material model based on a constitutive law with orthotropic, non-linear strength, shock response, composite failure and softening criteria is presented. A set of material parameters is derived for applications in hydrocodes (here: ANSYS AUTODYN). High- and hypervelocity impact tests with different impact velocities are used for preliminary validation and discussion of the predictive capabilities in view of future application. •Test methods for a full experimental characterization of a UHMWPE composite.•Quasi-static and dynamic testing of a UHMWPE composite.•Hypervelocity impact experiments on a UHMWPE composite.•Predictive modeling of a UHMWPE under ballistic impact.•Non-linear material model including elasticity, plasticity, failure and softening.
doi_str_mv 10.1016/j.ijimpeng.2014.07.004
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subjects Constitutive model
Criteria
High velocity Impact
Impact velocity
Material characterization
Molecular weight
Nonlinearity
Orthotropy
Polyethylenes
Softening
Stacking
Strength
UHMWPE
title A non-linear orthotropic hydrocode model for ultra-high molecular weight polyethylene in impact simulations
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