爆炸冲击作用下加筋板结构变形研究

为了预报加筋板结构在爆炸冲击载荷作用下的变形程度,将加筋板的变形分为整体变形和局部变形,借助数值计算拟合了两者能量分配关系,进而提出了爆炸冲击作用下加筋板结构变形的理论计算方法,并与实验结果进行比较,结果吻合较好。     

基于数值模拟的弹药地面库整库燃爆冲击波毁伤风险评估

弹药燃爆事故是我军后方仓库安全管理工作防护的重点,对弹药燃爆事故危害度进行评估,是武器装备安全风险评估体系的重要组成部分.选取地面库整库弹药燃爆事故为研究对象,应用AUTODYN计算程序,建立了弹药地面库的三维空间有限元仿真模型,并对弹药地面库整库爆炸的冲击波传播过程进行了数值模拟,得到了在冲击波不同毁伤等级下人员、建筑物的毁伤区域,为燃爆事故危害度风险评估提供了数据支持.     

馈能型悬挂综合性能评价研究

以提高车辆馈能型悬挂综合性能评价的有效性为目的,在分析悬挂减振性能评价和馈能型悬挂能耗特性的基础上,提出了一种考虑乘坐舒适性、操纵稳定性以及悬挂能耗的馈能型悬挂综合性能评价指标和方法。分别以线性和非线性悬挂为研究对象,对其性能进行了综合评价实例分析,验证了该评价指标和方法的有效性。     

高g值加速度计动态校准的实现方法

针对高g值加速度计动态校准要求激励信号的频率大于加速度计谐振频率的需要,采用小型Hopkinson杆和激光干涉仪构成动态校准系统,对某型高g值加速度传感器进行了校准实验。结果表明:该系统能产生脉宽10滋s以下的窄脉冲加速度激励信号,对一阶谐振频率大于100 k Hz的高g值加速度计可以实现动态校准。     

等截面隔离段中激波串结构的数值模拟

采用二阶TVD格式的有限体积法偶合Baldwin Lomax代数湍流模型求解雷诺平均Navier stokes方程 ,数值模拟了二维矩形等截面隔离段中的流动现象 ,很好地模拟出由激波 /附面层干扰所形成的复杂的激波串流场结构。计算结果与国外有关文献的结果进行了比较。     

一种新型近红外脉冲强光辐射源的探索

探索了一种产生近红外脉冲强光辐射的新途径。用冲击大电流使铜丝爆炸产生圆柱式内爆冲击波 ,冲击压缩惰性气体 ,产生等离子体辐射近红外脉冲强光。实验表明 ,用这种方法已经得到了总功率为MW量级 ,脉宽为 1 0 μs量级的近红外脉冲强光辐射     

长坑道中防护门上的化爆冲击波压力研究

为了对坑道中的防护门抗化爆冲击波进行有效的设计,先需确切知道作用在防护门上的反射压力。首先基于Hopkinson比例定律,用LS-DYNA动力有限元软件模拟了常规炸药在坑道入口外爆炸情况下,长坑道中自由场冲击波峰值压力的衰减规律,并由此确定作用在防护门上的反射压力。计算结果与其他经验方法的预测结果进行了比较。可供防护门的设计及动力响应研究参考。     

发射井内弹-筒系统抗爆减震设计

为提高井下冷发射导弹的生存能力,对其开展了抗爆减震设计研究,建立了弹-筒系统在不同减震方式下的有限元仿真模型,计算了弹-筒系统在爆炸地冲击作用下的动态响应,比较了悬吊式、下支承式、斜吊式等多种减震系统的减震效果,并分析了减震器刚度和阻尼对减震效果的影响。结果表明：悬吊式减震系统的减震效果略好于下支承式,斜吊式最差,合理减小减震器刚度和阻尼可以明显提升悬吊式减震系统的减震效果。     

Two novel critical shock models based on Markov renewal processes

In this paper, we investigate systems subject to random shocks that are classified into critical and noncritical categories, and develop two novel critical shock models. Classical extreme shock models and run shock models are special cases of our developed models. The system fails when the total number of critical shocks reaches a predetermined threshold, or when the system stays in an environment that induces critical shocks for a preset threshold time, corresponding to failure mechanisms of the developed two critical shock models respectively. Markov renewal processes are employed to capture the magnitude and interarrival time dependency of environment-induced shocks. Explicit formulas for systems under the two critical shock models are derived, including the reliability function, the mean time to failure and so on. Furthermore, the two critical shock models are extended to the random threshold case and the integrated case where formulas of the reliability indexes of the systems are provided. Finally, a case study of a lithium-ion battery system is conducted to illustrate the proposed models and the obtained results.     

Cell-type continuous electromagnetic radiation system generating millimeter waves for active denial system applications

The cell-type continuous electromagnetic radiation system is a demonstration device capable of generating high-power millimeter electromagnetic waves of a specific wavelength and observing their effects on living organisms. It irradiates a biological sample placed in a 30 × 30 × 50 cm³ cell with electromagnetic waves in the 3.15-mm-wavelength region (with an output of ≥1 W) and analyzes the temperature change of the sample. A vacuum electronic device-based coupled-cavity backward-wave oscillator converts the electron energy of the electron beam into radiofrequency (RF) energy and radiates it to the target through an antenna, increasing the temperature through the absorption of RF energy in the skin. The system causes pain and ultimately reduces combat power. A cell-type continuous electromagnetic radiation system consisting of four parts—an electromagnetic-wave generator, a high-voltage power supply, a test cell, and a system controller—generates an RF signal of ≥1 W in a continuous waveform at a 95-GHz center frequency, as well as a chemical solution with a dielectric constant similar to that of the skin of a living organism. An increase of 5 °C lasting approximately 10 s was confirmed through an experiment.