旋转弹侵彻钢板的数值模拟

利用LS-DYNA3D软件建立了弹靶几何模型,应用有限元程序对旋转弹侵彻钢板过程进行仿真计算,并通过与实验比较,验证了有限元方法的正确性。分析了转速对垂直侵彻和斜侵彻两种状况下性能的影响,通过比较不同转速情况下得到的速度、加速度等响应以及侵彻过程中弹体的质量损失情况,得出旋转对弹体垂直侵彻和斜侵彻具有一定的影响,为弹体结构的设计、改进和优化提供重要参考依据。     

隐身榴弹表面吸波材料的抗压强度分析

在火炮发射隐身榴弹过程中,由于隐身榴弹的静不平衡、动不平衡,造成隐身榴弹在膛内运动过程中碰撞膛线,其表面涂敷的吸波材料将承受较大的接触力.发射过程中应保证不损伤吸波材料表面,确保吸波材料具有良好的吸波性能、不增加隐身榴弹的雷达散射截面.从理论上计算了隐身榴弹与膛线之间的接触力,为研制隐身榴弹用的抗压吸波材料提供了设计指标.     

子母弹首发命中概率

提出了子母弹命中目标的定义,研究了子母弹射击误差的组成、母弹误差和子弹误差的概率分布,射击误差的转换及转换条件,建立了子母弹首发命中概率模型并推导出4种不同条件下子母弹首发命中概率公式,并导出了首发命中概率所满足关系。以算例分析了子母弹的母弹误差、子母的散布误差及目标幅员对子母弹首发命中概率的影响,结论为子母弹射击精度战术技术指标的分析论证及子母弹的射击法则研究提供了基础。     

基于GPS的弹道修正弹驱动控制器系统

针对目前国内二维弹道修正处于起步阶段和一维弹道修正处于研制阶段,提出了一种基于距离及精度二次修正执行机构的驱动控制器,该驱动控制器模块是一种新型的修正组件控制模块,详细介绍了修正组件控制器的工作原理、修正原理和硬件电路设计。硬件电路设计主要包括升压电路、四路起爆电路和异或门电路。每路起爆电路可以独立控制一个阻尼片。该控制器可以完成多种模式的修正,不仅可以完成弹道修正弹的一维一次和一维二次距离修正,还可以完成弹道修正弹的二维修正。     

脱壳弹弹托分离的双目视觉测量

脱壳弹的弹托分离过程对弹体的飞行稳定性和打击效能具有显著的影响。针对脱壳弹出膛后弹托相对弹体的六自由度运动过程,提出采用基于双目视觉原理的弹托分离角测量方法。通过在弹体表面和弹托表面设置标记点,采用图像处理和跟踪算法实现对标记点的识别和跟踪。结合双目空间标定参数解算出标记点的空间位置,进而获得弹托相对弹体的分离角度,同时采用实验验证了上述测量方法的精度,其精度达到2%。以实验室进行的初速度1 550 m/s和1 750 m/s的脱壳弹射击试验为例,测量并分析了不同初速度下的弹托分离轨迹。结果表明:脱壳弹分离初速度越快,弹托分离轨迹越靠近弹体。     

长杆射弹侵彻三种混凝土靶的实验研究

为了研究钻地武器的侵彻性能,在57mm口径的气炮上发射长杆射弹对三种靶体进行模拟侵彻实验。靶体为水泥砂浆石靶、钢纤维混凝土靶和含单层密排刚玉球的钢纤维混凝土靶。实验结果表明,弹头形状对侵彻深度有明显影响;当长杆射弹和撞击速度都相同时,与侵彻钢纤维混凝土靶相比,含单层密排刚玉球的钢纤维混凝土靶中的侵彻深度大约降低了11%,而水泥砂浆石靶中的侵彻深度增加了12%。     

MEFP战斗部结构的正交优化设计

以多爆炸成型弹丸(MEFP)为计算模型,应用显式有限元程序LS-DYNA,分析了药型罩间距、锥角、壁厚、装药高度和装药直径5种因素对MEFP发散角的影响规律。结果表明:随着药型罩间距、壁厚和装药直径的增加以及药型罩锥角、装药高度的减小,MEFP的发散角在减小。在此基础上以MEFP发散角为命中和毁伤概率指标,应用正交优化方法针对5种结构因素对MEFP发散角的影响主次关系进行了分析研究。结果表明药型罩壁厚是MEFP战斗部命中和毁伤概率的主要影响因素,并得到了5种结构因素各水平的最优组合。     

舰炮制导炮弹技术风险评估

针对技术风险评价中信息的模糊性和不确定性,提出了舰炮制导炮弹技术风险的灰色聚类评价方法。首先将舰炮制导炮弹研制方案的关键技术进行分解,确定综合评价指标,得到各指标的属性值;然后按照综合评价要求划分灰类,建立白化权函数;最后结合权重采用灰色聚类综合评价方法获得各关键技术所属风险级别及研制方案的综合技术风险值。算例表明,灰色聚类评价方法可将技术风险评价中的模糊和不确定信息定量化处理,能够有效地对舰炮制导炮弹的技术风险进行评价。     

Partial penetration of annular grooved projectiles impacting ductile metal targets

Changing and optimizing the projectile nose shape is an important way to achieve specific ballistic performance. One special ballistic performance is the embedding effect, which can achieve a delayed high-explosive reaction on the target surface. This embedding effect includes a rebound phase that is significantly different from the traditional penetration process. To better study embedment behavior, this study proposed a novel nose shape called an annular grooved projectile and defined its interaction process with the ductile metal plate as partial penetration. Specifically, we conducted a series of low-velocity-ballistic tests in which these steel projectiles were used to strike 16-mm-thick target plates made with 2024-O aluminum alloy. We observed the dynamic evolution characteristics of this aluminum alloy near the impact craters and analyzed these characteristics by corresponding cross-sectional views and numerical simulations. The results indicated that the penetration resistance had a brief decrease that was influenced by its groove structure, but then it increased significantly-that is, the fluctuation of penetration resistance was affected by the irregular nose shape. Moreover, we visualized the distribution of the material in the groove and its inflow process through the rheology lines in microscopic tests and the highlighted mesh lines in simulations. The combination of these phenomena revealed the embed-ment mechanism of the annular grooved projectile and optimized the design of the groove shape to achieve a more firm embedment performance. The embedment was achieved primarily by the target material filled in the groove structure. Therefore, preventing the shear failure that occurred on the filling material was key to achieving this embedding effect.     

Experimental investigation on enhanced damage to fuel tanks by reactive projectiles impact

Enhanced damage to the full-filled fuel tank,impacted by the cold pressed and sintered PTFE/AL/W reactive material projectile(RMP)with a density of 7.8 g/cm3,is investigated experimentally and theoretically.The fuel tank is a rectangular structure,welded by six pieces of 2024 aluminum plate with a thickness of 6 mm,and filled with RP-3 aviation kerosene.Experimental results show that the kerosene is ignited by the RMP impact at a velocity above 1062 m/s,and a novel interior ignition phenomenon which is closely related to the rupture effect of the fuel tank is observed.However,the traditional steel projectile with the same mass and dimension requires a velocity up to 1649 m/s to ignite the kerosene.Based on the experimental results,the radial pressure field is considered to be the main reason for the shear failure of weld.For mechanism considerations,the chemical energy released by the RMP enhances the hydrodynamic ram(HRAM)effect and provides additional ignition sources inside the fuel tank,thereby enhancing both rupture and ignition effects.Moreover,to further understand the enhanced ignition effect of RMP,the reactive debris temperature inside the kerosene is analyzed theoretically.The initiated reactive debris with high temperature provides effective interior ignition sources to ignite the kerosene,resulting in the enhanced ignition of the kerosene.