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Publication - Professor Stephen Hallett

    Finite element modelling of Dyneema® composites

    From quasi-static rates to ballistic impact

    Citation

    Hazzard, M, Trask, R, Heisserer, U, Van Der Kamp, M & Hallett, S, 2018, ‘Finite element modelling of Dyneema® composites: From quasi-static rates to ballistic impact’. Composites Part A: Applied Science and Manufacturing, vol 115., pp. 31-45

    Abstract

    A finite element methodology to predict the behaviour of Dyneema® HB26 fibre composites at quasi-static rates of deformation, under low velocity drop weight impact, and high velocity ballistic impact has been developed. A homogenised sub-laminate approach separated by cohesive tied contacts was employed. The modelling approach uses readily available material models within LS-DYNA, and is validated against experimental observations in literature. Plane-strain beam models provide accurate mechanisms of deformation, largely controlled through Mode II cohesive interface properties and kink band formation. Low velocity drop weight impact models of HB26 give force-deflection within 10% of new experimental observations, with in-plane shear strain contour plots from models directly compared with experimental Digital Image Correlation (DIC). Ballistic impact models utilising rate effects and damage showed similar modes of deformation and failure to that observed in literature, and provide a good approximation for ballistic limit under 600 m/s impact speed.

    Full details in the University publications repository