Energy absorption during projectile perforation of lightweight sandwich panels with metallic fibre cores |
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| Authors: | J Dean A S-Fallah PM Brown LA Louca TW Clyne |
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| Affiliation: | 1. Department of Materials Science & Metallurgy, Cambridge University, Pembroke Street, Cambridge CB2 3QZ, UK;2. Department of Civil and Environmental Engineering, Skempton Building, South Kensington Campus, Imperial College, London SW7 2AZ, UK;3. DSTL, Physical Sciences Research Department, Porton Down, Salisbury, Wiltshire SP4 0JQ, UK |
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| Abstract: | This paper concerns energy absorption during projectile penetration of thin, lightweight sandwich panels with metallic fibre cores. The panels were made entirely of austenitic stainless steel (grade 304). The faceplates were 0.4 mm thick and the core (∼1–2 mm thick) was a random assembly of metallic fibres, consolidated by solid state sintering. The impact tests were simulated using ABAQUS. Faceplate behaviour was modelled using the Johnson and Cook plasticity relation and a strain rate-dependent, critical plastic strain failure criterion. The core was modelled as an anisotropic, compressible continuum, with failure based on a quadratic, shear stress-based criterion. The experimental data show that, with increasing impact velocity, the absorbed energy decreased from the ballistic limit, reached a minimum value, and then underwent a monotonic increase. The FEM modelling demonstrates that this increase arises from the kinetic energy of ejected fragments, while the energy absorbed by plastic deformation and fracture tends to a plateau. Normalised absorbed energies have been compared to values for single faceplates. The sandwich panels are marginally superior to single plates on an areal density basis. |
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| Keywords: | Ballistic Impact Sandwich Perforation ABAQUS Fibre network |
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