Ballistic performance of multi-layered metallic plates impacted by a 7.62-mm APM2 projectile

Flores‐Johnson, E.A.; Saleh, Michael; Edwards, L.

doi:10.1016/j.ijimpeng.2011.08.005

Cited by 166 publications

(98 citation statements)

References 23 publications

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“…6b). This brittle behaviour has been reported in other numerical simulations [28] and experimental results [15] of bulk plate of AA 7075. It can be seen in Fig.…”

Section: Ballistic Performancesupporting

confidence: 85%

“…The JC material model has been successfully employed to model ballistic impact on (a) (b) aluminium plates [15,24,[26][27][28][29] and the parameters used in our model are reported in Table 1 and were validated against independent experimental observations of aluminium plates. Materials parameters for JC material model in Table 1 were obtained from [15], while damage parameters for the JC fracture criterion were obtained from [16,17].…”

Section: Validation Of the Jc Materials Model And Materials Parametersmentioning

confidence: 99%

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Numerical investigation of the impact behaviour of bioinspired nacre-like aluminium composite plates

Flores‐Johnson

Shen

Guiamatsia

et al. 2014

Composites Science and Technology

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133

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Inspired by the hierarchical structure of nacre, an aluminium alloy (AA) 7075 based composite featuring layer waviness and cohesive interface is studied as a low weight impact resistant material. To investigate the mechanical response and the ballistic performance of this laminated structure, a numerical study of the proposed nacre-like composite plates made of 1.1-mm thick AA 7075 tablets bonded with toughened epoxy resin was performed using Abaqus/Explicit. Target thicknesses of 5.4-mm, 7.5-mm and 9.6-mm impacted by a rigid hemi-spherical projectile were simulated. The epoxy material was modelled using a user-defined interface cohesive element with compressive strength enhancement. A significant performance improvement was recorded for the 5.4-mm nacre-like plate (compared to the same thickness bulk plate), which was explained by the hierarchical structure facilitating both localized energy absorption (by deformation of the tablet) and more globalized energy absorption (by inter-layered delamination and friction). For a given projectile, however, the performance improvement of using the proposed composite decreased with increasing laminate thickness, which was attributed to the increased likelihood of ductile failure occurring prior to perforation in thicker bulk plates. For 5.4-mm thick plates impacted at high velocity, the nacre-like plate had a better ballistic performance than that of the plates made of continuous (flat and wavy) layers, which was attributed to the larger area of plastic deformation (observed in the nacrelike plate after impact) due to the tablets arrangement.

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“…6b). This brittle behaviour has been reported in other numerical simulations [28] and experimental results [15] of bulk plate of AA 7075. It can be seen in Fig.…”

Section: Ballistic Performancesupporting

confidence: 85%

Section: Validation Of the Jc Materials Model And Materials Parametersmentioning

confidence: 99%

Numerical investigation of the impact behaviour of bioinspired nacre-like aluminium composite plates

Flores‐Johnson

Shen

Guiamatsia

et al. 2014

Composites Science and Technology

Self Cite

133

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show abstract

“…They found that double layering of the target increased the ballistic limit velocity for spaced plates by nearly 40% compared to a monolithic target of equal thickness. In contrast, based on numerical investigation of monolithic, double-and triple-layered plates Flores-Johnson et al [13] concluded that monolithic plates had a better ballistic performance than a layered target. Multi-layered structures in different combinations were also considered in research conducted by Deng et al [14].…”

Section: Introductionmentioning

confidence: 98%

Numerical investigation on ballistic resistance of aluminium multi-layered panels impacted by improvised projectiles

2017

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This paper presents a numerical study of perforation of the aluminium multi-layered targets impacted by steel projectiles in the shape of a ball, nut and nail. For the construction of the protective panels arc-, rectangular-, V-and U-shaped sheets of metal were considered. During the tests the panel thickness was constant at 160 mm. The panels were composed of 1.5-mm-thick aluminium sheets, and the initial speed of debris was 500 m/s. A comprehensive numerical study indicated the shape of the layer that had superior ballistic resistance and the best strength-to-weight ratio. Computational analyses were also used to investigate the influence of thermal softening and strain rate hardening in the Johnson-Cook constitutive model on the ballistic performance of layered targets. The number of layers required to stop the penetrating objects was compared for the rigid and deformable projectiles. Based on the comparative studies, some guidelines for engineering tasks involving exploration of number of possible technical solutions were proposed.

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“…The impact resistance of multiple thin metallic plates has been found to be better [1,2] or worse [3,4] than that of fewer thick plates, the relative performance depending on the materials, their arrangement, and the shape of the projectile ogive [5,6,7]. Polymers are eight times less dense than steel and thus an obvious route to lighter structures.…”

Section: Introductionmentioning

confidence: 99%

Elastomer-metal laminate armor

et al. 2016

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• Polymer-aluminum laminates on the strike-face of steel plates enhance ballistic performance.• With judicious selection of substrate and laminate, a broad range of performance and weight combinations can be obtained.• There is both a reduction in magnitude of the substrate deformation and spatial dispersion of the impact.• The main function of the metallic layers is to stiffen the polymer without affecting the latter's viscoelasticity response. A study was carried out of pressure wave transmission and the ballistic penetration of steel substrates incorporating a front-face laminate, the latter consisting of alternating layers of thin metal and a soft polymer; the latter undergoes a viscoelastic phase transition on impact. The ballistic properties of laminate/steel structures are substantially better than conventional military armor. This enhanced performance has three origins: large energy absorption by the viscoelastic polymer, a significant strain-hardening of the material, and lateral spreading of the impact force. These mechanisms, active only at high strain rates, depend on the chemical structure of the polymer but not on the particular metal used in the laminate. G R A P H I C A L A B S T R A C T a b s t r a c t a r t i c l e i n f oPublished by Elsevier Ltd.

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Ballistic performance of multi-layered metallic plates impacted by a 7.62-mm APM2 projectile

Cited by 166 publications

References 23 publications

Numerical investigation of the impact behaviour of bioinspired nacre-like aluminium composite plates

Numerical investigation of the impact behaviour of bioinspired nacre-like aluminium composite plates

Numerical investigation on ballistic resistance of aluminium multi-layered panels impacted by improvised projectiles

Elastomer-metal laminate armor

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