Divyanshu S. Morghode, D. G. Thakur, Sachin Salunkhe, Lenka Cepova, Emad S. Abouel Nasr
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Three factors led to the selection of Al 7075-T561 and Al2O3 as the target materials. First, the literature review revealed that these materials have already been employed in the construction of armour. Second, Al2O3 is a brittle material whereas Al 7075-T651 is ductile. Consequently, when combined in a layered arrangement, these materials offer the ideal destroyer-absorber arrangement. Thirdly, these materials have lower densities than steel. As a result, these materials offer a lightweight alternative for lead core 7.62 mm bullet defense. From the analysis, it is observed that two layered configurations were found to be effective in the prevention of bullet perforation: a front plate of Al2O3 that was 10 mm thick and had a rear plate of Al 7075-T651 that was 06 mm thick, and a front plate of Al2O3 that was 04 mm thick and had a 12 mm thick layer of Al 7075-T651.","PeriodicalId":53220,"journal":{"name":"Frontiers in Mechanical Engineering","volume":null,"pages":null},"PeriodicalIF":2.0000,"publicationDate":"2024-07-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Analysis of the thickness of layered armor to provide protection against 7.62 mm ball projectiles using experimental and numerical methods\",\"authors\":\"Divyanshu S. Morghode, D. G. Thakur, Sachin Salunkhe, Lenka Cepova, Emad S. 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引用次数: 0
摘要
不同材料板材的分层配置是抵御各种动能弹药的方法之一。每块板的厚度是防止弹丸穿透的最重要影响参数之一。在本研究中,通过使用 LS-DYNA 数值模拟,分析了 Al2O3 和 Al 7075-T651 的分层配置,以防止 7.62 毫米铅芯弹丸在正常冲击条件下穿孔。在 Al 7075-T651 板上进行了实验,并根据实验结果对数值模型进行了验证。为了实现目标,我们使用验证过的数值模型来研究各种 Al2O3 和 Al 7075-T651 组合的影响。选择 Al 7075-T561 和 Al2O3 作为目标材料有三个因素。首先,文献综述显示,这些材料已被用于制造装甲。其次,Al2O3 是一种脆性材料,而 Al 7075-T651 则具有延展性。因此,当这些材料以分层排列的方式结合在一起时,可提供理想的破坏者-吸收者排列方式。第三,这些材料的密度比钢低。因此,这些材料为 7.62 毫米铅芯子弹的防御提供了轻质替代品。从分析中可以看出,有两种分层结构能有效防止子弹穿孔:一种是前板为 10 毫米厚的 Al2O3,后板为 06 毫米厚的 Al 7075-T651;另一种是前板为 04 毫米厚的 Al2O3,后板为 12 毫米厚的 Al 7075-T651。
Analysis of the thickness of layered armor to provide protection against 7.62 mm ball projectiles using experimental and numerical methods
The layered configuration of different material plates is one of the ways of achieving protection against different kinds of kinetic energy ammunitions. The thickness of each plate is one of the most important influencing parameters to prevent the penetration of the projectile. In the present study, a layered configuration of the Al2O3 and Al 7075-T651 is analysed, to prevent the perforation of 7.62 mm Lead core projectile, under normal impact conditions, by using LS-DYNA numerical simulations. Experiments were conducted on Al 7075-T651 plate and Numerical model was validated with experiment results. To achieve the objective, the validated numerical model was used to investigate influence on various Al2O3 and Al 7075-T651 combinations. Three factors led to the selection of Al 7075-T561 and Al2O3 as the target materials. First, the literature review revealed that these materials have already been employed in the construction of armour. Second, Al2O3 is a brittle material whereas Al 7075-T651 is ductile. Consequently, when combined in a layered arrangement, these materials offer the ideal destroyer-absorber arrangement. Thirdly, these materials have lower densities than steel. As a result, these materials offer a lightweight alternative for lead core 7.62 mm bullet defense. From the analysis, it is observed that two layered configurations were found to be effective in the prevention of bullet perforation: a front plate of Al2O3 that was 10 mm thick and had a rear plate of Al 7075-T651 that was 06 mm thick, and a front plate of Al2O3 that was 04 mm thick and had a 12 mm thick layer of Al 7075-T651.