双重系统加密研究: 获得完全安全的IBE及其扩展

双重系统加密技术首先由Waters提出,是用于构造完仝安全的基于身份的加密(IBE)及其扩展方案的有力方法.针对完全安全方案的构造,研究了双重系统加密技术并提出了一个完全安仝方案的通用构造方法,即将一个利用双重系统加密的IBE方案与一个普通的方案相结合,得到一个新的可以利用双重系统加密证明安全的方案.在通用构造的基础上提出了一个实例,该实例是一个基于层级身份的加密( HIBE)方案,具有常密文长度.该方案比Waters提出的双重系统加密HIBE方案更高效,并且在判定BDH假设和判定线性假设下证明是完全安全的.     

多阶段任务系统可靠性并联冗余优化模型

多阶段任务系统是一类普遍存在的复杂系统,研究其可靠性冗余优化对于该类系统设计具有重要的参考价值。针对多阶段任务系统的可靠性并联冗余优化问题,提出了采用冗余故障树和冗余BDD来描述系统冗余结构的方法。给出了冗余模块在多阶段任务系统中的可靠度计算方法,建立了整个冗余多阶段任务系统可靠度计算模型。在此基础上以费用最小为目标,构建多阶段任务系统可靠性冗余优化模型,并应用微粒群算法对模型进行求解。算例验证了模型的合理性及算法的有效性。     

管内高压气体冲击静态液柱的CFD模拟

为可视化内部流场,采用Fluent软件对警用脉冲防暴水炮炮管内高压气体冲击静态液柱的过程进行了三维数值模拟,得到了重力作用和无重力时的三维气液界面形状,分析了不同时刻管内的速度和压力变化情况,将压力模拟值与理论计算值进行了比较分析.从模拟结果可以看出,重力对于界面形状影响较大,液柱加速过程开始呈线性增加,当t>0.01...     

航空自导深弹和磁探仪攻潜模型与仿真

针对反潜巡逻机使用磁探仪和自导深弹的攻潜效能研究,提出了一种基于蒙特卡洛法的计算模型。在建立攻潜坐标系的基础上,给出了连投深弹射击深度的定义;结合磁探仪定位原理,提出了基于峰值追踪的定位目标和连投攻击的方法,仿真结果表明该方法能够提高命中概率;给出了目标分布和连投深弹的散布模型,依据攻潜过程和命中判定条件,进行了攻潜效能的计算;仿真分析了影响攻潜效能的主要因素,并研究了投弹间隔的确定方法。     

航天部队试验综合能力评估模型研究

根据航天试验综合能力评估的特点和要求,依据系统工程的理论方法,确定了装备、人员和保障能力为主要评估要素,设置了评估层次和控制点,建立了航天试验综合能力评估模型。该模型由下至上分为3个层次：基础层主要对分系统各岗位人员和所属装备进行评估;分系统层主要对人员素质、装备性能和保障能力进行评估;系统层主要对整个系统的综合试验能力进行评估。通过实例表明该模型大大提高了航天试验综合能力量化评估的准确性。     

聚碳硅烷纤维化学气相交联研究

以环己烯作为反应气氛,对聚碳硅烷(PCS)纤维进行了化学气相交联不熔化处理。与空气不熔化进行对比,研究了不熔化过程中PCS纤维的反应程度及凝胶含量的变化,并进行了元素分析和热重差热分析,初步探讨了PCS纤维环己烯化学气相交联反应的机理。结果表明,在环己烯气氛中,PCS分子结构中Si-H键的反应程度随不熔化温度的提高逐渐增加,相应地,PCS纤维的凝胶含量迅速提高直至不熔。环己烯受热后产生自由基,引发PCS分子中的Si-H和Si-CH3键断裂形成自由基,促进PCS分子间形成Si-CH2-Si结构而实现交联。     

高压合成聚碳硅烷的沉淀与复配

研究了沉淀与复配两种调控高压合成聚碳硅烷(PCS)分子量及其分布的方法。研究表明,在PCS的良溶剂(如二甲苯)溶液中加入沉淀剂(如丙酮)比例超过临界点后,PCS中分子量越高的部分越先沉淀出来,从而降低了PCS的软化点、分子量和分散系数,PCS的高、中、低分子量的比例得到调节。复配是将不同分子量分布的PCS均匀地混合在一起,其分子量、软化点和高、中、低各部分的含量基本符合混合率的关系。因此,可以按照混合率来设计所需PCS的软化点、分子量及高、中、低分子含量。     

Thermal and combustion behavior of Al-MnO2 nanothermite with poly(vinylidene fluoride -co- hexafluoropropylene) energetic binder

Fluoropolymers get increasing attention in energetic materials application due to the high fluorine content. To explore the effect of poly(vinylidene fluoride-co-hexafluoropropylene) (P(VDF-HFP)) on Al/MnO2 nanothermite, the samples with different contents are prepared and characterized by SEM, TG-DSC, XRD, and their ignition and combustion behavior are tested and recorded. The results show that P(VDF-HFP) as an energetic binder can combine the nanothermite components together, even exist in the gaps. The integrity of energetic materials has been improved. Thermal analysis shows that the addition of P(VDF-HFP) greatly changes the thermal reaction processes, and the exothermic peaks appear early, but the utilization of fuel and oxidizer is not efficient from the XRD results. Furthermore, the appropriate addition of P(VDF-HFP) can directly reduce the ignition energy threshold and increase the combustion time, which is necessary for the potential ignition charge application. The possible reasons for above phenomena are discussed and analyzed. This research provides a reference for improvement of thermite-based ignition charge formulation.     

Simulation of the plasticizing behavior of composite modified double-base (CMDB) propellant in grooved calendar based on adaptive grid technology

The frequent occurrence of safety accidents during the calendering process is caused by the flammable and explosive properties of composite modified double-base (CMDB) propellant. Optimization of process parameters with the aid of fluid simulation technology could effectively ensure the safety of the calendering process. To improve the accuracy of the simulation results, material parameters and model structure were corrected based on actual conditions, and adaptive grid technology was applied in the local mesh refinement. In addition, the rheological behavior, motion trajectories and heat transfer mechanisms of CMDB propellant slurry were studied with different gaps, rotational rates and temperatures of two rollers. The results indicated that the refined mesh could significantly improve the contour clarity of boundaries and simulate the characteristics of CMDB propellant slurry reflux movement caused by the convergent flow near the outlet. Compared with the gap, the increased rotational rate of roller could promote the reflux movement and intensify the shear flow of slurry inside the flow region by viscous shear dragging. Meanwhile, under the synergistic effect of contact heat transfer as well as convective heat exchange, heat accumulated near the outlet and diffused along the reflux movement, which led to the countercurrent heat dissipation behavior of CMDB propellant slurry. The plasticizing mechanism of slurry and the safety of calendering under different conditions were explored, which provided theoretical guidance and reference data for the optimization of calendering process conditions. Based on the simulation results, the safety of the CMDB propellant calendering process could be significantly improved with a few tests conducted during a short research and development cycle.     

Formation and characterization of core-shell CL-20/TNT composite prepared by spray-drying technique

The core-shell 2,4,6,8,10,12-Hexanitro-2,4,6,8,10,12-hexaazaisowurtzitane/2,4,6-Trinitrotoluene (CL-20/TNT) composite was prepared by spray-drying method in which sensitive high energy explosive (CL-20) was coated with insensitive explosive (TNT). The structure and properties of different formulations of CL-20/TNT composite and CL-20/TNT mixture were characterized by scanning electron microscopy (SEM), Transmission electron microscopy (TEM), Laser particle size analyzer, X-ray photoelectron spectroscopy (XPS), X-ray diffraction (XRD), differential scanning calorimetry (DSC), impact sensitivity test and detonation performance. The results of SEM, TEM, XPS and XRD show that ϵ-CL-20 particles are coated by TNT. When the ratio of CL-20/TNT is 75/25, core-shell structure is well formed, and thickness of the shell is about 20–30 nm. And the analysis of heat and impact show that with the increase of TNT content, the TNT coating on the core-shell composite material can not only catalyze the thermal decomposition of core material (CL-20), but also greatly reduce the impact sensitivity. Compared with the CL-20/TNT mixture (75/25) at the same ratio, the characteristic drop height of core-shell CL-20/TNT composite (75/25) increased by 47.6% and the TNT coating can accelerate the nuclear decomposition in the CL-20/TNT composites. Therefore, the preparation of the core-shell composites can be regarded as a unique means, by which the composites are characterized by controllable decomposition rate, high energy and excellent mechanical sensitivity and could be applied to propellants and other fields.