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Finite Element Analysis of the Ballistic Impact on Auxetic Sandwich Composite Human Body Armor

Imtiaz Alam Shah, Rafiullah Khan, Seyed Saeid Rahimian Koloor, Michal Petrů, Saeed Badshah, Sajjad Ahmad, Muhammad Amjad

2022Materials47 citationsDOIOpen Access PDF

Abstract

In this study, the ballistic impact behavior of auxetic sandwich composite human body armor was analyzed using finite element analysis. The auxetic core of the armor was composed of discrete re-entrant unit cells. The sandwich armor structure consisted of a front panel of aluminum alloy (Al 7075-T6), UHMWPE (sandwich core), and a back facet of silicon carbide (SiC) bonded together with epoxy resin. Numerical simulations were run on Explicit Dynamics/Autodyne 3-D code. Various projectile velocities with the same boundary conditions were used to predict the auxetic armor response. These results were compared with those of conventional monolithic body armor. The results showed improved indentation resistance with the auxetic armor. Deformation in auxetic armor was observed greater for each of the cases when compared to the monolithic armor, due to higher energy absorption. The elastic energy dissipation results in the lower indentation in an auxetic armor. The armor can be used safely up to 400 m/s; being used at higher velocities significantly reduced the threat level. Conversely, the conventional monolithic modal does not allow the projectile to pass through at a velocity below 300 m/s; however, the back face becomes severely damaged at 200 m/s. At a velocity of 400 m/s, the front facet of auxetic armor was destroyed; however, the back facet was completely safe, while the monolithic panel did not withstand this velocity and was completely damaged. The results are encouraging in terms of resistance offered by the newly adopted auxetic armor compared to conventional monolithic armor.

Topics & Concepts

ArmourAuxeticsMaterials scienceProjectileComposite materialIndentationStructural engineeringSandwich-structured compositeFinite element methodCore (optical fiber)Ballistic limitLayer (electronics)EngineeringMetallurgyHigh-Velocity Impact and Material BehaviorCellular and Composite StructuresStructural Response to Dynamic Loads
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