指定目标不延误条件下的拦截决策算法

从现有的拦截排序准则出发,根据实际作战中进袭目标的特点,应用现代排序理论,分别建立了动态目标拦截排序模型和总损失最小化模型,给出相应的求解算法。最后实例计算得出模型既体现了现有的拦截准则,又对现有的准则进行了推广。     

不同形状喷嘴内流场模拟分析

建立了前混合磨料水射流喷嘴内固液两相流动的数学模型,运用Fluent软件对圆柱型、圆锥收敛型、流线型和圆锥带圆柱段收敛型喷嘴内流场进行了数值模拟,分析了喷嘴形状对喷嘴内流场和磨料颗粒加速性能的影响,并通过切割实验验证了仿真结果的可靠性。结果表明:圆柱型喷嘴能量损耗较大,圆锥收敛型喷嘴对磨料颗粒的加速性能差,流线型喷嘴性能良好但不易加工,只有圆锥带圆柱段收敛型喷嘴是用作前混合式磨料水射流喷嘴的最优选择。     

汽车加油机器人关键技术分析

传统加油模式使操作人员易受有毒易燃油气的侵害,而且严冬酷暑时加油站作业环境恶劣,因此在加油站配置机器人实现智能化加油变得十分迫切。介绍了国内外汽车加油机器人的研究进展,指出其作业对象的差异性、环境的多变性以及作业过程的危险性。分析了当前汽车加油机器人所采用的加油机构、加注接口以及识别与定位技术的特点,指出加油机构优化、安全控制、智能识别与定位研究是汽车加油机器人发展的方向。     

电磁脉冲对高频结构的热效应分析

对于Cerenkov型器件,由高频结构温升引发的热脱附会造成的射频击穿,进而导致输出功率降低和脉冲缩短。基于此,研究了电磁脉冲对高频结构的加热温升效应,推导了高频结构的温升公式,指出了理论公式的适用范围,并给出了数值求解试件温升的方法。以二周期1 MV·cm^-1的高频结构为例,进行了温升的数值计算和仿真研究。结果表明,脉宽100 ns的单脉冲对不锈钢试件的温升效应明显高于其他材料。当系统工作在高重频时,电磁脉冲的温升作用可能使金属材料达到气体脱附的阈值从而引发气体脱附形成局部高压。该研究可为高功率微波源中的气体脱附以及射频击穿等研究提供参考。     

单兵信息系统协同作战技术研究

协同作战是提高体系作战能力,发挥整体作战效能的关键,针对单兵班组在未来信息化条件下单兵作战单元协同作战的协同模式、协同流程、协同策略,协同指挥、协同作战效能评估等方面进行阐释,对未来单兵信息系统班组协同作战技术研究具有一定的指导意义。     

结合景象匹配与惯导信息的SAR平台定位方法

利用高度传感器提供高度信息,结合高精度异源图像匹配技术与惯导系统漂移修正方法实现SAR平台定位。根据成像中间时刻SAR平台与SAR图像中心线上物点在水平面的投影共线的特性,在单帧图像中心线上均匀选取若干点与光学基准图进行高精度景象匹配;计算平台在水平面上投影位置,并利用高度信息确定其空间位置;使用序列图像定位结果估计惯导系统漂移参数,对惯导系统输出的位置数据进行修正,实现高精度的SAR平台定位。对各误差因素的影响进行分析,推导了精度估计公式。仿真和实际序列图像实验结果表明,方法正确可行,具有较高的平台定位精度,具备一定工程实用价值。     

改进IAHP-CIM模型的雷达组网探测能力评估方法

针对雷达组网探测能力的评估问题,采用鱼骨图法对影响雷达组网探测能力的多种因素进行梳理,得到结构层次清晰的指标评价体系。采用改进的区间层次分析—控制区间和记忆模型对该指标体系进行评估,具体方法是:运用区间层次分析法构造区间判断矩阵;利用蛙跳算法求解区间判断矩阵中满足最小一致性的确定性矩阵;利用控制区间和记忆模型来确定各指标的风险概率,实现指标体系的评估。以具体的案例为对象进行仿真实验,结果表明,所提评估方法有效,评估结论相对客观、可信,对雷达组网探测能力评估具有一定参考价值,从而为雷达组网的优化部署奠定良好基础。     

基于飞行仿真的近地告警包线计算

TSO-C151b标准中近地告警包线为通用模型设计,未结合飞机的自身特性。为精确给出飞机过大下降速率告警包线,通过结合飞机自身气动特性和操纵特性,分析告警机理,建立飞机六自由度仿真程序。依据飞机发动机数据、气动力数据、质量特性数据等,建立仿真模型及操作程序,实时模拟飞机各舵面的操作响应过程,以及飞机的运动姿态和飞行轨迹,计算飞机在不同下降速率时拉起的损失高度,设计近地告警包线。实际试飞数据验证了模型设计合理,计算结果准确。同时,将仿真计算得出的告警包线与TSO-C151b对比,给出适用于飞机的近地告警包线使用建议,保证飞机飞行安全。     

A study on the surface overpressure distribution and formation of a double curvature liner under a two-point initiation

The formation mechanism of an EFP(explosively formed projectile) using a double curvature liner under the overpressure effect generated by a regular oblique reflection was investigated in this paper.Based on the detonation wave propagation theory,the change of the incident angle of the detonation wave collision at different positions and the distribution area of the overpressure on the surface of the liner were calculated.Three-dimensional numerical simulations of the formation process of the EFP with tail as well as the ability to penetrate 45# steel were performed using LS-DYNA software,and the EFP ve-locity,the penetration ability,and the forming were assessed via experiments and x-ray photographs.The experimental results coincides with those of the simulations.Results indicate that the collision of the detonation wave was controlled to be a regular oblique reflection acting on the liner by setting the di-mensions of the unit charge and maintaining the pressure at the collision point region at more than 2.4 times the CJ detonation when the incident angle approached the critical angle.The distance from the liner midline to the boundary of the area within which the pressure ratio of the regular oblique reflection pressure to the CJ detonation pressure was greater than 2.5,2,and 1.5was approximately 0.66 mm,1.32 mm,and 3.3 mm,respectively.It is noted that pressure gradient caused the liner to turn inside out in the middle to form the head of the EFP and close the two tails of the EFP at approximately 120μs.The penetration depth of the EFP into a 45# steel target exceeded 30 mm,and there was radial expansion between the head and tail of the EFE increasing the penetration resistance of the EFP.Therefore,the structural size of the unit charge and the liner can be further optimized to reduce resistance to increase the penetration ability of the EFP.     

One-step synthesis of FeO(OH) nanoparticles by electric explosion of iron wire underwater

In this study,we investigated electric explosion of iron wire in distilled water with different energy input adjusted by charging voltage.The as-prepared samples were characterized by X-ray diffraction (XRD),scanning electron microscopy (SEM),transmission electron microscopy (TEM) and X-ray photoelectron spectroscopy (XPS),showing the presence of iron and multiple iron-based compounds oxides with contents influenced by the experimental conditions.In particular,pure FeO(OH) nanoparticles were obtained using electric explosion of iron wire with energy input of 1125 J at charging voltage of 15 kV.Analysis of discharge current and resistive voltage data indicate that the high energy input induced by strong plasma discharge at high charging voltage is a key factor to form FeO(OH).This study presents a one-step method to synthesize FeO(OH) nanoparticles using electric explosion of iron wire.