CoCrFeNiCux高熵合金爆炸成型弹丸药型罩结构的优化与毁伤效能OA
Optimization of structural design and damage efficacy for CoCrFeNiCux high-entropy alloy liners in explosively formed projectiles
探究了CoCrFeNiCux高熵合金作为药型罩材料在爆炸成型弹丸领域中的应用潜力,旨在通过优化药型罩结构提升爆炸成型弹丸的成形性能和毁伤效能.通过准静态和动态拉伸试验研究了CoCrFeNiCux高熵合金的力学性能,并拟合了Johnson-Cook本构模型参数.结果表明,2 种高熵合金(x=0,1)均表现出优异的塑性、延展性及正应变率敏感性,动态屈服强度随应变率升高显著提升.基于AUTODYN软件对比分析了紫铜与高熵合金药型罩的成形规律,发现高熵合金因强度高导致初始结构成形困难,弹丸尾部闭合不良.通过对药型罩进行均匀变壁厚优化,使形成的爆炸成型弹丸长径比分别提升至 2.0(x=0)和 2.5(x=1),速度分别达到 2 260 和 2 357 m/s.侵彻性能验证表明,优化后的弹丸对100 mm厚4340 钢靶的侵彻深度分别为37.8 和41.5 mm,对1 000 mm厚C35 混凝土靶的侵彻深度分别达287.6 和303.7 mm,扩孔直径均超过装药口径的 260%,显示出优异的侵彻毁伤能力.研究结果表明,通过优化CoCrFeNiCux高熵合金药型罩结构可显著改善爆炸成型弹丸的成形质量与侵彻性能,为高效毁伤战斗部设计提供了理论依据与新思路.
High-entropy alloys (HEAs),as a novel class of high-performance metallic materials,have demonstrated considerable potential in the fields of damage and penetration mechanics. This study investigates the application of CoCrFeNiCux HEAs as liner materials for explosively formed projectiles (EFPs),with the objective of enhancing EFP formation quality and damage efficacy through structural optimization of the liner. Quasi-static and dynamic tensile tests were conducted to characterize the mechanical properties of the HEAs with different copper contents (x=0 and x=1). The experimental data were used to fit parameters for the Johnson-Cook (J-C) constitutive model. The results indicate that both HEA compositions exhibit outstanding plasticity,ductility,and positive strain-rate sensitivity,with dynamic yield strength increasing significantly under high strain-rate loading. Numerical simulations were performed using the nonlinear finite element software AUTODYN to compare the EFP formation processes between conventional copper liners and the proposed HEA liners. The simulations revealed that the superior strength of the HEAs impeded the complete closure of the projectile tail when using a conventional uniform wall thickness liner geometry. To address this issue,a uniform variable wall thickness design was implemented for the HEA liners. This optimization successfully improved the formed EFPs,resulting in length-to-diameter ratios of 2.0 for x=0 and 2.5 for x=1,with velocities reaching 2 260 m/s and 2 357 m/s,respectively. The penetration performance of the optimized HEA EFPs was validated against two target types. The projectiles achieved penetration depths of 37.8 mm (x=0) and 41.5 mm (x=1) into 100-mm-thick 4340 steel targets,and 287.6 mm and 303.7 mm into 1 000-mm-thick C35 concrete targets. The crater diameters exceeded 260% of the charge caliber,confirming excellent penetration and damage capabilities. This work demonstrates that structural optimization of CoCrFeNiCux HEA liners significantly enhances EFP formation quality and penetration performance,providing a theoretical foundation and a novel strategy for the design of high-efficiency damage warheads.
李镕辛;陈嘉琳;王瑞琪;宋佳星;黄骏逸;张阿震;吴家祥;李裕春
陆军工程大学野战工程学院,江苏 南京 210007||军事科学院国防工程研究院目标易损性评估国家重点实验室,北京 100036军事科学院国防工程研究院目标易损性评估国家重点实验室,北京 100036陆军工程大学野战工程学院,江苏 南京 210007西安稀有金属研究院有限公司,陕西 西安 710006陆军工程大学野战工程学院,江苏 南京 210007陆军工程大学野战工程学院,江苏 南京 210007陆军工程大学野战工程学院,江苏 南京 210007陆军工程大学野战工程学院,江苏 南京 210007
数理科学
高熵合金爆炸成型弹丸药型罩结构优化侵彻性能
high-entropy alloyexplosively formed projectilelinerstructural optimizationpenetration performance
《爆炸与冲击》 2026 (3)
51-69,19
陕西省自然科学基础研究计划青年项目(2025JC-YBQN-103)
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