首页|期刊导航|爆炸与冲击|带截顶内衬的高熵合金/Al/PTFE双层复合药型罩成型机理与毁伤特性

带截顶内衬的高熵合金/Al/PTFE双层复合药型罩成型机理与毁伤特性OA

Formation mechanism and damage characteristics of a high-entropy alloy/Al/PTFE double-layer composite liner with a truncated inner layer

中文摘要英文摘要

针对传统金属射流在侵彻混凝土目标时存在毁伤面积有限、动态响应不足等问题,首次提出了一种新型高熵合金/铝/聚四氟乙烯(high-entropy alloys/aluminium/polytetrafluoroethylene,HEA/Al/PTFE)双层含能复合药型罩结构.采用真空电弧熔炼、粉末压制与烧结工艺,成功制备出带截顶内衬的半球形复合罩,并通过试验与数值模拟相结合的方法,系统研究了其成型机理、侵彻特性与毁伤效能.试验结果表明,相较于单层HEA罩,该复合结构能显著增强混凝土内部的碎裂和裂纹扩展能力,有效融合了HEA的优异力学性能与Al/PTFE的高能量释放特性.数值模拟表明,内衬对HEA射流具有抑制径向发散、提升射流中段凝聚性的"包覆"作用,但其多次碰撞-追随-分离行为也会延迟系统动态平衡.进一步建立了该复合罩分区成型理论模型,通过引入能量损失系数修正爆轰能量传递过程.理论预测结果与数值模拟结果的对比显示,形成的射流半径与杵体半径的误差小于 15%.在此基础上分析了内衬厚度和高度对射流成型的影响规律,确定最优参数为厚度3.5 mm、高度12 mm,可在射流凝聚性、长度及毁伤威力之间实现最佳平衡.

Aiming at the limitations of traditional metal jets in penetrating concrete targets,such as limited damage range and insufficient dynamic response,a novel double-layer energetic composite liner structure with a truncated inner layer made of high-entropy alloys/aluminum/polytetrafluoroethylene (HEA/Al/PTFE) was proposed for the first time. The hemispherical composite liner's HEA layer was prepared using vacuum arc melting,while the Al/PTFE inner layer was formed through powder compaction and sintering. To thoroughly verify the performance advantages of the composite liner,two types of shaped charge structures were fabricated during the experimental phase for comparison:one with the composite liner and the other with a single-layer HEA liner. C35 plain concrete cylinders were used as targets,with single-point initiation at the center of the charge top. Additionally,numerical simulations of the jet formation process were conducted using the commercial finite element software ANSYS-LS-DYNA. The explosive and liner were modeled with the Smoothed Particle Hydrodynamics(SPH) algorithm to accurately capture the dispersal behavior during jet formation,while the casing was simulated with the Lagrangian algorithm to describe the expansion and fragmentation process of the outer shell. In the simulation,the high-temperature and high-strain-rate mechanical behaviors of HEA,Al/PTFE,and 45 steel were described using the Johnson-Cook constitutive model. The explosive was modeled with the classical JWL equation of state,and air was treated as an ideal gas. All relevant parameters were sourced from published literature. Based on the axisymmetric curvature characteristics of the hemispherical liner and the material discontinuity introduced by truncation,a partitioned formation theoretical model was further established. An energy loss coefficient η (η=0.2) was introduced to modify the detonation energy transfer process.According to the truncation angle,the composite liner was divided into two regions with different physical mechanisms. The jet radius and slug radius for each region were derived using mass and momentum conservation. Experimental results show that both the composite liner and the single-layer HEA liner can form stable penetrating jets,achieving complete penetration of the concrete targets. Compared to the single-layer HEA liner,the composite structure significantly enhances the fragmentation and crack propagation capabilities inside the concrete. Numerical simulation results indicate that the Al/PTFE inner layer exhibits a"coating and cohesive" effect on the HEA jet,effectively suppressing radial dispersion and improving the continuity of the mid-section of the jet. However,multiple collision-following-separation behaviors between the inner layer and the main jet delay the system from reaching dynamic equilibrium. The established partitioned formation theoretical model demonstrates good predictive accuracy,with relative errors of less than 15% between the predicted jet and slug radii and the numerical simulation results. Further parametric analysis reveals that the thickness and height of the inner layer significantly influence jet formation. The optimal parameter combination is a thickness of 3.5 mm and a height of 12 mm,which achieves the best balance between suppressing radial dispersion,maintaining jet length,and enhancing mid-section cohesion. This composite liner effectively integrates the excellent mechanical properties of HEA with the high energy release characteristics of Al/PTFE.The established partitioned formation theoretical model provides a reliable theoretical basis for the design of hemispherical composite liners. The research findings offer important theoretical and experimental support for the optimized design and engineering application of novel energetic composite liners.

郑贺龄;王展翾;王明扬;李先成;李欣田;李正坤;徐立志;杜忠华

沈阳理工大学装备工程学院,辽宁 沈阳 110159南京理工大学机械工程学院,江苏 南京 210094南京理工大学机械工程学院,江苏 南京 210094沈阳理工大学装备工程学院,辽宁 沈阳 110159南京理工大学机械工程学院,江苏 南京 210094东北大学冶金学院,辽宁 沈阳 110819南京理工大学机械工程学院,江苏 南京 210094沈阳理工大学装备工程学院,辽宁 沈阳 110159||南京理工大学机械工程学院,江苏 南京 210094

数理科学

高熵合金Al/PTFE复合药型罩成型

high-entropy alloysAl/PTFEcomposite linerforming

《爆炸与冲击》 2026 (3)

70-86,17

空基信息感知与融合全国重点实验室开放基金(ASFC-20240001059006)军事科学院目标易损性评估全国重点实验室开放基金(YSX2024KFYS003)江苏省自然科学基金(BK20220968)工程材料与结构冲击振动四川省重点实验室开放基金(22kfgk03)兴辽英才计划(XLYC2202021)

10.11883/bzycj-2025-0325

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