Experimental and numerical study on failure mechanisms of bone simulants subjected to projectile impact

Żochowski, Paweł; Cegła, Marcin; Berent, Jarosław; Grygoruk, Roman; Szlązak, Karol; Smędra, Anna

doi:10.1002/cnm.3687

Cited by 3 publications

(1 citation statement)

References 68 publications

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“…Different failure mechanisms can occur depending on factors such as impact velocity, angle, and the properties of the composite. The failure mechanisms that may be investigated in such simulations include the energy absorption/dissipation capabilities and failure mechanisms of hyper-elastic target materials [52,53]. The impact of the target surface will be affected by different velocity ranges and angles observed in the simulation.…”

Section: Resultsmentioning

confidence: 99%

Numerical simulation of composite materials with sisal and glass fibers for ballistic impact resistance

Zelelew,

Ali,

Ayele

et al. 2024

Mater. Eng. Res.

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Body armor is critical to mitigating penetrating injuries and saving soldiers' lives. However, ballistic impacts to body armor can cause back deformation (BFD), posing a serious threat of fatal injury on the battlefield. The study performs finite element modeling to evaluate the protection of body armor panels. The numerical simulations consider various parameters, including impact velocities, and angles of projectile impact, which are used to estimate the residual velocity and damage patterns of the composite laminate. The simulations are carried out using the LS-DYNA code based on finite element analysis. The main results of the research reveal crucial insights into the ballistic behavior of composite materials with sisal and glass fibers. The study identifies specific responses, damage development patterns, and comparative analyses between sisal and fiberglass composites. The results have practical implications for the development of advanced materials to improve ballistic protection.

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Section: Resultsmentioning

confidence: 99%

Numerical simulation of composite materials with sisal and glass fibers for ballistic impact resistance

Zelelew,

Ali,

Ayele

et al. 2024

Mater. Eng. Res.

View full text Add to dashboard Cite

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Experimental Investigation of the Ballistic Response of Head Surrogate Against Fragment Simulating Projectiles

Pandey,

Joshi,

Khan

et al. 2023

Exp Mech

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Evaluation of an anthropometric head surrogate exposed to chisel-nosed fragment simulating projectile impact

Pandey,

Ganpule

2024

Front. Mech. Eng.

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Fragment-induced penetrating injuries pose a significant threat in modern combat. Explosions from explosive devices generate metallic fragments that can lethally penetrate various body regions, with the head being particularly most vulnerable to fatality in terms of penetration. Hence, understanding the head’s response to fragment impact is crucial. To this end, this study investigated the ballistic response of an anatomically accurate anthropometric head surrogate to fragment impact. The head surrogate comprised simulants for the three major layers of the head (skin, skull, and brain). Using a pneumatic gas gun, we impacted chisel-nosed fragment simulating projectiles (FSPs) of 1.10-g and 2.79-g on the head surrogate. We analyzed the ballistic response of the head surrogate in terms of ballistic limit velocities (V50), energy densities (E50/A), and failure mechanisms in each layer. The results indicated sensitivity to the FSP size. The 1.10-g FSP had a ∼41% higher V50 and a ∼63% higher E50/A compared to the 2.79-g FSP. Additionally, each head surrogate layer exhibited distinct failure mechanisms. The skin simulant failed due to a combination of shearing and elastic hole enlargement, forming a cavity smaller than the size of the FSP. The skull simulant fractured, creating a cavity at the entry point matching the FSP size. The brain simulant failure involved shearing of the cavity and penetration of fractured skull fragments. We also observed no significant difference in response when introducing a flexible neck attachment on which the head surrogate was mounted. Furthermore, comparisons of an anthropometric (close-shape) head surrogate with a simplified open-shaped head surrogate revealed the minimal influence of the head curvature on the response due to the localized nature of fragment penetration. These findings provide a comprehensive understanding of the head surrogate’s mechanical response to fragment impact. The insights from this work hold significant value in the assessment of penetrating head injury, especially against small fragments. The results can be applied in modern warhead design and forensic investigations.

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Experimental and numerical study on failure mechanisms of bone simulants subjected to projectile impact

Cited by 3 publications

References 68 publications

Numerical simulation of composite materials with sisal and glass fibers for ballistic impact resistance

Numerical simulation of composite materials with sisal and glass fibers for ballistic impact resistance

Experimental Investigation of the Ballistic Response of Head Surrogate Against Fragment Simulating Projectiles

Evaluation of an anthropometric head surrogate exposed to chisel-nosed fragment simulating projectile impact

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