Influence of Dynamic Multiaxial Transverse Loading on Ultra High Molecular Weight Polyethylene (UHMWPE) Dyneema SK76 Single Fiber Failure

Abstract

A novel methodology for testing microscale single ballistic fibers under transverse impact to induce multiaxial loading is proposed and demonstrated using micron-scale (~18-m diameter) Dyneema SK76. Fibers are directly gripped to load cells and directly impacted by varying cylindrical loading geometries: razor (~2 m) to sharp (20 m) to blunt (200 m) in a modified Hopkinson bar at velocities of 10 and 20 m/s corresponding to nominal strain rates of 40006300 s1. Compared to high-strain-rate uniaxial tensile loading, failure strain was reduced by 28 , 32 , and 58 for blunt, sharp, and razor indenters, respectively, at strain rates of 4000 s1. At strain rates of 6300 s1, reductions were 34 , 39 , and 61 for blunt, sharp, and razor indenters, respectively. Fiber failure surfaces indicate tensile-dominated failure under blunt loading, shear failure under razor loading, and mixed failure under sharp loading. Experiments are modeled in LS-DYNA using a user material model to incorporate nonlinear inelastic transverse compressive behavior. A failure criterion incorporating multiaxial loading effects is applied to predict fiber failure, showing good agreement to the experimental results.

Document Details

Document Type

Technical Report

Publication Date

Dec 03, 2020

Accession Number

AD1116960

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