Effect of metal powders on explosion of fuel-air explosives with delayed secondary igniters

In order to improve the energy level of fuel air explosive(FAE) with delayed secondary igniters, high energetic metal powders were added to liquid fuels mainly composed of ether and isopropyl nitrate. Metal powders' explosive properties and reaction mechanisms in FAE were studied by high-speed video, pressure test system, and infrared thermal imager. The results show that compared with pure liquid fuels, the shock wave overpressure, maximum surface fireball temperature and high temperature duration of the mixture were significantly increased after adding high energetic metal powder. The overpressure values of the liquid-solid mixture at all measuring points were higher than that of the pure liquid fuels. And the maximum temperature of the fireball was up to 1700 ℃, which was higher than that of the pure liquid fuels. After replacing 30％of aluminum powder with boron or magnesium hydride, the shock wave pressure of the mixture was further increased. The high heat of combustion of boron and the hydrogen released by magnesium hydride could effectively increase the blast effect of the mixture. The improvement of the explosion performance of boron was better than magnesium hydride. It shows that adding high energetic metal powder to liquid fuels can effectively improve the explosion performance of FAE.     

A novel method for determination of lethal radius for high-explosive artillery projectiles

A new model has been defined that enables the estimation of the lethal radius (radius of efficiency) of HE (High Explosive) artillery projectiles against human targets. The model is made of several modules: CAD (Computer Aided Design) modeling, fragment mass distribution estimation, fragment initial velocity prediction, fragment trajectory calculation, effective fragment density estimation, and high explosive projectile lethal radius estimation. The results were compared with the experimental results obtained based on tests in the arena used in our country, and the agreement of the results was good. This model can be used in any terminal-ballistics scenario for high explosive projectiles since it is general, para-metric, fast and relatively easy to implement.     

浅谈舰载燃料空气炸药武器抗击巡航导弹

通过对FAE武器的特种杀伤效果和对巡航导弹相关技战术性能分析,利用FAE武器(云爆弹)的爆轰、冲击波、破片、窒息和电磁电热效应等特种杀伤效果,剧烈改变导弹的工作环境和对巡航导弹的弹体、导引系统、控制系统和发动机等关键部件进行“软”、“硬”破坏,以期达到抗击巡航导弹的目的,同时阐述了装备水面舰艇的可行性。     

弹道冲击下层合板破坏模式及抗弹性能实验研究

以舰用轻型复合装甲研究为背景,针对不同纤维增强种类(包括玻纤织物 C400、C200、SW220 和芳纶纤维织物T750)以及不同面密度层合板结构,在6.2 g刚性微曲面柱形弹弹道冲击下的防护能力展开实验研究,着重讨论了层合板结构弹道冲击下破坏模式、弹体初始侵彻速度及面密度与抗弹能力和抗弹效率之间的关系,认为不同的破坏模式体现了不同的吸能特性和纤维失效机理.     

多孔材料药型罩聚能射流的形成条件

依据Herrmann状态方程和斜冲击波关系估算了多孔材料药型罩压垮之前的冲击温升,求解了经过冲击压缩卸载后材料的声速。给出了多孔材料药型罩聚能射流的形成条件。初始冲击温升会使材料的声速和强度降低,从而使多孔材料聚能射流形成射流的高速和低速条件降低。     

S-四嗪类高氮含能化合物的合成及性能

以3,6-对(3,5-二甲基吡唑)-S-四嗪(BT)为起始物,研究了S-四嗪类高氮含能化合物3-氨基-6-(3,5-二甲基吡唑)-S-四嗪(ADMPT)、3-肼基-6-(3,5-二甲基吡唑)-S-四嗪(HDMPT)、3,6-二氨基-S-四嗪(DATz)、3,6-二肼基-S-四嗪(DHTz)与3,3’-偶氮-(6-氨基-S-四嗪)(DAAT)的合成,经IR、元素分析、1HNMR、13CNMR等对其结构进行了表征和确认。对DHTz和DAAT的热分解性能进行了研究,由不同升温速率下的DSC实验获得了其热分解动力学参数。结果表明DAAT热稳定性好、能量高,在10℃/min升温速率下,DAAT在280℃开始分解,放热峰值330℃,放热峰的分解焓为1974.33J/g;DHTz在120℃开始分解,放热峰值159℃,放热峰的分解焓为1843.23J/g。同时,采用高温高压爆轰产物状态方程(VLW EOS)对DHTz和DAAT的爆轰性能进行了理论计算。     

复杂系统理论对作战实践的指导

比较研究了机械模式与复杂系统模式的两种作战系统观,分析了复杂系统的整体性、非线性、开放性、自适应性、不确定性等特点。然后,根据作战系统是一复杂系统这一基本观点,并以复杂系统理论为指导,探讨了作战中的指挥控制、进攻作战、防御作战的一些基本策略。     

爆炸沸腾研究进展

分析讨论了液体过热极限、汽泡内压力等爆炸沸腾的重要参数 ,综述了三种主要实验方法 ,提出了有待进一步研究的问题 .     

炸药装药在压剪加载下的起爆特点

进行了两类压剪加载实验：（１）利用石英的平面正碰撞产生压剪加载的实验,采用电磁质速法测试装药试件内部不同质点的运动情况,分析炸药装药中发生化学反应的可能性;（２）在压剪炮上采用平行倾斜碰撞产生压剪加载的实验,观测炸药装药爆炸的可能性。由实验可以看出：在亚爆轰状态的压缩加载应力条件下,剪切的联合作用对炸药的起爆起到敏化作用,适当比例的压剪加载造成更加敏感的炸药起爆响应。文中给出了起爆响应规律和响应机制的实验分析。     

定性测量与定量测量火炸药静电感度的对比分析

采用先进测试系统,对氮化铅、硝化棉、梯恩梯和黑索金火炸药静电感度分别进行了定性测量和定量测量,得出了相对静电感度值和实际静电感度值,并对其进行了对比分析。