高速摄影法测定爆炸快门的性能

爆炸快门是高速摄影机中的一种重要部件,它要在10^-6秒左右闸断光路以防止感光材料的重复曝光。快门的关闭速度与快门的通光口径和引爆雷管的个数及爆速有关。不同型式的高速摄影机要求不同速度和通光口径的爆炸快门。例如普通转镜分幅或扫描相机用的爆炸快门直径在40—50毫米时,通光孔切断时间约为10—15微秒,而转镜网格显微相机则要求通光孔径为5毫米,闸光时间越短越好,例如0.6微秒或更小。     

微型雷管药高比对输出威力的影响

为了适应MEMS引信微型传爆序列的需求,针对微型雷管装药高度比对输出威力的影响开展了专门研究。改变装药直径为0.9 mm、装药高度为3 mm的微型雷管中起爆药与猛炸药装药高度比,用猛铜压阻传感器对爆轰输出压力进行测定,得到微型雷管中起爆药的临界高度为0.36 mm。当起爆药高度为1.65 mm时,微型雷管爆轰压力值最大,为10.3 GPa;当起爆药高度小于1.65 mm,HMX炸药高度大于1.35 mm时,随着起爆药高度的减小,猛炸药高度的增加,微型雷管的爆压值减小;当起爆药高度大于1.65 mm、HMX炸药高度小于1.35 mm时,随着起爆药高度的增加,猛炸药高度的减小,微型雷管的爆压值也减小。初步得出了羧铅起爆药和猛炸药的最佳高度比范围为0.69~2.26。     

雷管引爆过程光学测量

雷管动态输出通常以其在铅板中产生的凹痕深度穿孔直径的方法表示,但它不能给出雷管输出随时间的变化关系。当用扫描和分幅相机,辅以光学技术,辅助照明技术,便得到金属丝在空气中爆炸冲击波,等离子体,及金属丝引爆2~#药全过程的三维扫描图象。     

多元混合炸药爆轰驱动圆筒膨胀规律的理论确定方法

为快速预估任意配比的多元混合炸药爆轰产物的JWL(Jones-Wilkins-Lee)参数,提出了快速确定多元混合炸药爆轰驱动圆筒膨胀规律的理论方法,即在给定各组分爆轰产物JWL参数的前提下,根据能量守恒定律,采用Gurney模型,确定圆筒试验中多元混合炸药爆轰驱动圆筒膨胀距离随时间变化的曲线。同时,利用能量守恒原理以及经典爆轰理论中通过常γ状态方程得到的爆速、爆压和爆热之间的关系式,提出了确定多元混合炸药爆速和爆压的方法。采用该理论方法,分别计算了多元混合炸药PBXC03和PBXC10爆轰驱动圆筒膨胀规律及爆速和爆压,计算结果与前人的实验结果符合较好,验证了该理论方法的可行性和有效性。     

爆速对纳米铝粉爆炸烧结性能的影响

为了掌握纳米金属粉烧结成型技术,将纳米铝粉置于改良设计的可泄压式爆炸烧结装置中,得到了密实度达98%以上的纳米铝棒。通过改变铵梯炸药和木粉的比例调节炸药的爆速,研究了不同爆速下烧结铝棒的性能。利用金相显微镜观察烧结棒的微观结构,并对烧结棒的密实度、硬度等性能进行测量。结果表明:通过降低爆速可以减小马赫孔的产生,但爆速过低,会导致烧结棒的密实度和硬度等性能降低;当采用爆速为2 158m/s的炸药时,可制得无马赫孔、高硬度、高密实度、晶粒细小的均质烧结棒。     

硝化纤维素生成焓、键离解能及爆轰性能的理论研究

运用密度泛函理论方法结合等键反应,研究了硝化纤维素(NC)单体的生成热及其不同位置上氧硝基键(ONO2)的键离解能,基于半经验的Kamlet-Jacobs方程估算了其爆速与爆压。结果表明:B3LYP和B3P86两种方法得到的计算结果较为接近,生成热均为负值,其大小与氧硝基的数目有关,与氧硝基的取代位置无关。理论计算得到的氧硝基键的键离解能与含氮量无关,而是与实际断裂的氧硝基键的数目相关。爆速和爆压的计算表明,NC单体中所含氧硝基的数量增多,会降低其爆速和爆压。     

玻璃微球基乳化炸药及其在爆炸焊接中的应用

爆速是爆炸复合的主要参数之一。采用玻璃微球作为敏化剂和稀释剂,研究玻璃微球尺寸、含量对乳化炸药爆速的影响,然后调配爆速为2.230km/s的低爆速乳化炸药,利用铝蜂窝板配置蜂窝结构炸药,进行铝-钢复合板的爆炸焊接。试验结果表明:炸药密度随着玻璃微球含量的增加而减小;小尺寸玻璃微球含量(质量分数)小于2%或者大于35%时,乳化炸药发生拒爆现象;玻璃微球含量大于7%且小于35%时,炸药爆速随着玻璃微球含量的增大而减小。小尺寸(5~100μm)玻璃微球的敏化效果和调节爆速效果比大尺寸(70~200μm)玻璃微球好,铝蜂窝结构炸药用于铝-钢爆炸焊接可以获得良好的结合质量。     

条形爆炸逻辑器件之功能研究

通过敞式观察条纹技术(OVST)和火花隙或者多条纹技术(MST)相配合,可以较为简单地让条形起爆逻辑器件(这里是指一种8管条形同步引信)理想引爆,随之使传爆药栓点火并妥善传爆到总管烈性炸药。     

强点火条件下RP-3航空煤油燃爆特性实验研究

为进一步探究影响RP-3航空煤油燃爆特性参数的因素,在内径为200mm、高度为5 400mm的立式激波管中,采用强点火方式,测定了其在不同浓度下的临界起爆能以及不同起爆能量、浓度当量比、喷雾压力下RP-3航空煤油的爆速和爆压。实验结果表明:航空煤油的临界起爆能随浓度当量比的增加先急剧降低,达到最小值后又缓慢上升,基本呈"L"形变化;在喷雾压力为0.20~0.60MPa、同一浓度条件下,RP-3航空煤油的爆速、爆压随喷雾压力的变化曲线呈倒"U"形;随着起爆能量升高,爆速、爆压均呈直线上升趋势,并且当起爆能量小于1.68MJ/m~2时,煤油未达到直接爆轰状态;燃料的爆速、爆压随浓度当量比的增加先上升后下降,其变化趋势也基本呈倒"U"形。     

顶爆作用下裂隙对锚固洞室振动速度的影响

基于相似模型试验,利用数值分析方法研究了含裂隙锚固洞室在顶爆作用下质点峰值振速的分布规律,并探讨了裂隙倾角和长度对峰值振速的影响。结果表明:裂隙和洞室表面在迎爆侧存在振速放大效应,洞室两侧和底部振速远小于拱顶;随着裂隙长度的增加,锚固洞室拱顶、拱脚和两帮峰值振速先减小后增加再减小,除了长度较短的情况,裂隙的存在使锚固洞室拱顶的峰值振速增加;随着裂隙向右倾斜的倾角增加,拱脚和两帮的峰值振速出现不对称,洞室右边的拱脚和侧帮峰值振速大于左边;拱顶峰值振速先减小后增加,倾角为45°时拱顶峰值振速最小,相较无裂隙洞室降低了48.2%,有效减弱了结构的动力响应。     

爆炸丝线起爆装置研制及应用

为实现低密度粉末炸药的线同步起爆,研制了一种爆炸丝线起爆系统。储能装置采用3个低感电容并联,总容量为12μF;采用200kV/100kA场畸变开关作为放电开关;触发器产生1.5kV脉冲经过高压脉冲变压器输出幅度大于40kV的高压脉冲触发开关。在储能电容器充电40kV下,电爆炸丝负载上获得了73kA的脉冲电流。采用高速分幅相机观测了爆炸丝爆炸过程图像,结果表明爆炸丝膨胀过程的同步性较好。该线起爆系统已成功应用于爆炸膨胀环实验。     

Response of PETN detonators to elevated temperatures

In the present study, commercially available detonators with pentaerythritol tetranitrate (PETN) were subjected to elevated temperatures. The detonators were thermally ignited over a range of heating rates to measure ignition delay time and assess detonator violence. The violence of the detonator was quantified by measuring the velocity of the detonator closure disc (or “flyer”). The maximum flyer velocity of a thermally ignited detonator was comparable in magnitude to that obtained by initiating a room temperature pristine detonator with an exploding bridge wire (under the same confinement); however, the high flyer velocity was not an indication of deflagration to detonation transition (DDT) in the thermally ignited detonator. The detonator responded more violently than a thermally ignited detonator when initiated at 95% of the ignition delay time. Inoperability thresholds were also measured by varying the detonator temperature and the threshold was found to be sensitive at detonator temperatures below the melting point of PETN.     

Homogeneous electrical explosion of tungsten wire in vacuum

Experimental results on Joule energy deposition upon initiation of a fast electrical explosion of 16-μm tungsten wire in vacuum at current densities of more than 10⁸ A/cm² are reported. We have found that explosion with a fast current rise time (～170 A/ns into a short) results in homogeneous and enhanced deposition of electrical energy into the tungsten before surface flashover. The maximum tungsten wire resistivity reaches a value of up to ～185 μΩ cm before surface flashover that significantly exceeds the melting boundary and corresponds to a temperature of ～1 eV. The highest values for light radiation and expansion velocity of wire ～1 km/s were observed for the fast explosion. For the explosion mode with a slower current rise time (～22 A/ns into a short), we observed the existence of an “energy deposition barrier” for tungsten wire. In the slow explosion mode, the current is reconnected to the surface shunting discharge before melting. The maximum tungsten wire resistivity in this case reaches the value of ～120 μΩ cm, which is less than indicative of melting. Also, the energy deposition along the wire is strongly inhomogeneous, and wire is disintegrated into parts. We attribute the early reconnection of the current to the surface discharge for the slow explosion to high electron emission from the wire surface, which starts before melting.     

Formation of extended directional breakdown channels produced by a copper wire exploding in the atmosphere

Experimental data for switching initiated by the electrical breakdown of air gaps up to 1.9 m long with an arbitrary geometry that are produced by an exploding copper wire 90 μm in diameter are presented. At an initial voltage of 11 kV, the stored energy equals 100–2100 J. Two channel formation conditions are possible: explosion of a wire without electrical breakdown and electrical breakdown in a channel produced by an exploding wire with a delay (current pause) no longer than 250 μs. Current and voltage waveforms across the discharge gap, as well as the resistivity values, under the electrical breakdown conditions are shown. Mechanisms and conditions for streamer initiation at a mean electric field strength in the discharge gap of 5.3–17.0 kV/m are discussed. The geometrical dimensions of plasma objects in the forming channel, the run of the electrical current under breakdown, and the formation mechanism of wire explosion products are found from color microphotographs. The formation mechanism of large aerosols in the form of tiny spherical copper and copper oxide (CuO, Cu₂O) particles under wire explosion conditions is discussed.     

真空中铝单丝电爆炸的实验研究

开展了铝单丝在负极性电流脉冲作用下电爆炸特性的研究.利用皮秒激光探针,搭建了阴影、纹影和干涉的光学诊断平台,得到了不镀膜铝丝典型的能量沉积过程,在电压崩溃时刻其沉积能量为2.4 eV/atom.为了增加金属丝内的沉积能量,开展了相同电参数及金属丝尺寸下的镀膜铝丝电爆炸实验,其沉积能量可达到5 eV/atom,实现了在电压崩溃之前铝丝完全气化(完全气化所需能量为4 eV/atom).阴影图像展示了高密度丝核区域的膨胀过程,不镀膜铝丝平均膨胀速度为2.2 km/s,而镀膜铝丝因为沉积能量大,其膨胀速度约为不镀膜铝丝的2.3倍,高密度区域膨胀速度为5 km/s.由于阴影不能反映低密度等离子体的膨胀,开展了平行双丝实验,通过测量自发光辐射,估算了低密度等离子体的膨胀速度.利用条纹相机拍摄了不镀膜铝丝电爆炸过程中自发光区域的图像.纹影图像清晰地展示了不镀膜铝丝在电爆炸过程中形成的核冕结构,而镀膜铝丝电爆炸过程中核冕结构得到了一定程度的抑制.从干涉图像计算了相移,在轴对称假设下对相移进行阿贝尔逆变换,重构了三维的铝原子数密度分布.     

电爆炸法制备Fe3O4纳米颗粒及其物相研究

搭建了电爆炸金属丝实验平台,在空气中电爆炸铁丝来制备纳米金属颗粒。利用电阻分压器与Rogowski线圈来测量电爆炸过程中铁丝上的负载电压与电流。将负载电压与电流之积进行时间积分来估算沉积在铁丝上的能量。使用光电探测器对电爆炸过程中产生的等离子体发光信号进行探测。对铁丝电爆炸后形成的产物使用高倍显微镜、扫描电镜（SEM）、透射电镜（TEM）、能谱分析仪（EDS）以及X射线衍射仪（XRD）进行观测,来研究其物相特性。实验结果表明:电爆炸过程中,当铁丝由液相变为气相时,其电阻急剧增加,因此电流几乎不能流过铁丝,同时铁丝上的负载电压会趋近于电容器的初始充电电压。随着能量的持续积累,等离子体在爆炸腔中形成。由于原本被阻断的电流能够从低电阻等离子体中流过,因此电压电流波形变为欠阻尼波形。电爆炸铁丝所得的产物为Fe3O4纳米颗粒,其中大部分呈规则的球形。Fe3O4纳米颗粒的粒径主要分布在30~60 nm之间,并且符合对数正态分布。     

并联金属丝提高电爆炸丝沉积能量的数值模拟

对于低气压或真空环境中的电爆炸丝,因丝沿面击穿会过早终止能量沉积过程,使丝中沉积能量(Ed)大大低于金属丝完全汽化时所需能量(Es).本文提出并联金属丝法延缓沿面击穿时刻以提高电爆炸丝沉积能量.对电流上升时间为几十纳秒、幅值约为1 kA级作用下的金属丝电爆炸过程进行了数值模拟.结果表明,在电爆炸丝两端并联一定尺寸的金属丝可降低爆炸丝端电压上升率,从而推迟电压上升过程中沿面击穿时刻,显著提高丝中沉积能量和过热系数.     

Corona-free electrical explosion of polyimide-coated tungsten wire in vacuum

We present experimental evidence of corona-free electrical explosion of dielectric-coated W wire in vacuum. A fast current rise of approximately 150 A/ns and a coating of 2 microm polyimide are both needed to achieve the corona-free regime of explosion. Breakdown is absent in corona-free explosion; the wire remains resistive, and this allows anomalously high energy deposition (approximately 20 times atomization enthalpy). MHD simulations reproduce the main differences between corona and corona-free explosions. A corona-free explosion of a wire can be useful for the generation of a hot plasma column by direct energy deposition.     

丝电爆过程的电流导入机理

丝电爆制备纳米粉时, 电流从电极导入金属丝的过程直接影响电极烧损和粉末中微米级大颗粒产生. 分别通过接触和气体放电两种方式导入电流进行电爆试验. 结果表明, 光测量装置检测到的丝端部光电流几乎与回路放电电流同时产生, 而中间位置的光电流则要滞后一段时间; 由探针收集的产物确定, 金属丝端部主要形成熔融粒子, 中间部分主要形成气相粒子. 分析可知, 接触方式导入电流时, 丝端部也存在气体放电现象, 大电流主要通过气体放电形成的等离子体导入. 等离子体对电流的旁路作用会阻碍能量向金属丝沉积, 这是产生微米级大颗粒和"积瘤"主要原因. 通过气体放电方式导入电流时, 电极烧损明显减轻, 并可以避免"积瘤"产生.     

Numerical calculation of the current specific action integral at the electrical explosion of wires

The electrical explosion of aluminum wires is numerically simulated in the magnetohydrodynamic approximation for the current density ranging from 10⁷ to 10¹⁰ A/cm² and times to explosion varying from 10^?10 to 10^?6 s. It is shown that, at current densities of 10⁸?10⁹ A/cm², low-temperature explosion conditions change to high-temperature ones, when inertial forces preventing the wire dispersion play a decisive role. This transition is accompanied by a sharp change in the thermodynamic parameters (the temperature and the energy deposited into the wire by the instant of explosion increase by several times), and the action integral for this transition increases smoothly approximately threefold as the explosion characteristics (current density and time to explosion) change by two orders of magnitude. The instant of transition from the low-temperature explosion to the high-temperature one depends on the radial dimensions of an exploding wire and does not depend on the properties of the environment.