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。     

洞库口部的水雾热红外伪装性能分析

洞库口部与背景的红外辐射差异是红外热成像仪探测洞库口部的基础。介绍了人工水雾及其红外伪装原理,同时,将水雾设备作用于实际洞库口部。通过红外热成像仪采集数据,测试和比较了水雾开启前和开启1,2 min时洞库口部的红外热图,并结合红外图像信息处理软件进行定线温度分析。结果表明:人工水雾在洞库口部的红外伪装方面起到了很好的遮蔽效果。     

不锈钢面板与铝面板泡沫铝夹芯梁的抗爆性能

为考查泡沫铝夹芯梁的抗爆性能及面板材料对其抗爆性能的影响，采用数值模拟方法分析了面板材料分别为工业纯铝与304号不锈钢，芯材为Alporas泡沫铝共同组成相同质量泡沫铝夹芯梁在不同爆炸荷载作用下的跨中位移与芯材压缩应变的差异。研究结果显示：在爆炸冲量分别为1．82，3．77，6．08，7．0kN·s的作用下，工业纯铝面板泡沫铝夹芯梁跨中位移分别为304号不锈钢面板泡沫铝夹芯梁跨中位移的68％，83％，84％及86％，较304号不锈钢面板泡沫铝夹芯梁具有更好地抵抗爆炸冲击波的能力，面板材料对泡沫铝夹芯梁的压缩应变影响较小。     

命中角对防护结构口部爆炸毁伤影响的数值分析

为研究装药命中角对防护结构口部爆炸毁伤的影响规律,对直墙拱结构进行了一系列爆炸模拟分析,得到了直墙拱结构拱顶、拱脚和直墙底3个位置的爆炸应力和位移时程曲线。通过分析这3个位置的应力峰值和位移峰值,发现随着装药命中角的增大,拱顶处竖直方向荷载减小,而拱脚处水平方向荷载增大;随着装药命中角的增大,拱顶处竖直方向位移变形减小,而拱脚处水平方向位移变形增大。模拟分析得到的命中角对防护结构口部爆炸毁伤的影响规律,可供防护工程设计时参考。     

T型坑道中爆炸冲击波传播规律的数值模拟

为了确定地下坑道中防护门上的冲击波荷载,首先需要弄清爆炸冲击波在坑道中的传播衰减规律.在模型坑道爆炸实验数据验证的基础上,应用数值模拟方法研究了T型坑道中爆炸冲击波的传播衰减规律.通过大量不同模型尺寸、不同炸药药量的数值模拟,得到了T型坑道中平面冲击波的形成位置,提出了爆炸冲击波通过T型坑道拐弯时新的冲击波压力衰减系数...     

UHMWPE复合材料抗爆实验研究

运用定制的聚偏四氟乙烯(PVDF)压电传感器,直接测量爆炸载荷下UHMWPE层叠无纬布和PU基体的UHMWPE复合材料内部冲击波压力峰值,对其冲击波衰减特性进行了实验研究。实验结果表明:UHMWPE复合材料对爆炸冲击波有很好的衰减作用,含有PU基体的UHMWPE复合材料比UHMWPE层叠无纬布对爆炸冲击波有更好的衰减效果。UHMWPE复合材料具有轻质、吸收冲击波效率高等特性,在爆炸冲击波防护领域有很好的应用前景。     

冲击波在多层结构中的传播

对水下冲击载荷在多层结构中的传播规律进行了理论分析,根据分界面上的应力和速度连续性条件得到透射波强度的解析表达式.从理论分析可以看出,舰船结构的多层防护体系对于减少爆炸冲击的损伤具有重要的作用,防护结构的波阻抗越大,防护的效果越好,这种方法可应用于多层防护结构在远场爆炸冲击波作用下的毁伤或防护方面的预测.     

特种防护舱抗爆性能试验研究

为探讨特种防护舱抗爆性能,进行了舱内爆炸原型试验,研究不同装药量下开闭盖状态防护舱内爆炸时的空气冲击波超压和舱体位移过程。结果表明:同药量下闭盖状态的空气冲击波超压明显高于开盖状态,即封闭舱内偶然爆炸时空气冲击波超压更高;随装药量的增大,舱壁的空气冲击波超压也在增大;舱体侧壁经过多次正反射作用均未发生碎片反应,顶盖泄爆措施对降低底板的空气冲击波超压十分有利;距爆心较近处的位移均比距爆心较远处的位移大。原型试验舱体完全破坏,但结构未发生崩溃式破坏,并无碎片及内爆的二次破片飞出,舱体具有一定的抗爆性能和较好的防破片能力。     

爆炸冲击波作用下板架结构响应研究综述

板架结构是飞机和水面舰艇主要的组成单元,研究其在爆炸冲击波作用下的变形和破坏对目标结构的防护设计具有重要意义。国内外学者对板架结构在冲击波载荷作用下的变形与破坏进行了大量研究,形成了诸多成果。本文中从理论分析、实验研究和数值模拟3个方面总结了爆炸冲击波载荷作用下板架结构响应领域的研究现状,并对未来研究方向提出一些建议,为相关结构的抗爆设计以及战时毁伤评估提供参考。     

波纹型泡沫混凝土耗能层的抗爆性能

为了研究耗能层类型改变对复合防护结构防护能力的影响,利用LS-DYNA有限元软件,对采用波纹型泡沫混凝土作为耗能层的复合防护结构在爆炸荷载作用下的动力响应进行了模拟,从压力、合成位移、合成加速度和合成速度4个方面考察其防护能力,发现波纹型泡沫混凝土防护能力明显优于平板型泡沫混凝土;并对波纹周期分别为6,8,10 cm的情况进行比较,发现其抗爆效果基本符合波纹周期越小,防护效果越好的规律。     

Mitigation of the blast load effects on a building structure using newly composite structural configurations

In this study, a nonlinear three-dimensional hydrocode numerical simulation was carried out using AUTODYN-3D to investigate the effect of blasting of a high explosive material (TNT) against several configurations of the composite structure. Several numerical models were carried out to study the effect of varying the thickness of the walls and the effect of adding an air layer or aluminum foam layer inside two layers of concrete in mitigating the effect of blast waves on the structure walls. The results showed that increasing the thickness of walls has a good effect on mitigating the effect of blast waves. When a layer of air was added, the effect of blast waves was exaggerated, while when a layer of aluminum foam was added the blast wave effects were mitigated with a reasonable percentage.     

Effects of material of metallic frame on the penetration resistances of ceramic-metal hybrid structures

The effects of metallic material on the penetration resistances of ceramic-metal hybrid structures against vertical long-rod tungsten projectiles were studied by artillery-launched experiments and numerical simulation. Hybrid structures with rectangular cores in transverse orthogonal arrangement and slide-fitting ceramic inserts of zirconia toughened alumina prisms were fabricated with titanium alloy TC4 (Ti6Al4V), AISI 4340 steel and 7075 aluminum alloy panels, respectively. The results showed that the hybrid structure of Ti6Al4V exhibited the highest penetration resistance, followed by that of 7075 aluminum alloy with the same area density. The penetration resistance of the hybrid structure of AISI 4340 steel was the lowest. The underlying mechanisms showed that the metallic material of a ceramic-metal hybrid structure can directly affect its energy absorption from the impact projectile, which further affects its penetration resistance. Different metallic frames exhibited different failure characteristics, resulting in different constraint conditions or support conditions for ceramic prisms. The high penetration resistance of the Ti6Al4V hybrid structure was due to its stronger back support to ceramic prisms as compared with that of AISI 4340 steel hybrid structure, and better constraint condition for ceramic prisms by metallic webs as compared with that of 7075 aluminum alloy hybrid structure. The results of mass efficiency and thickness efficiency showed that the Ti6Al4V hybrid structure has advantages in reducing both the thickness and the mass of protective structure. In addition, because the ceramic-metal hybrid structures in the present work were heterogeneous, impact position has slight influence on their penetration resistances.     

金属泡沫复合材料夹芯结构的压痕响应实验

金属泡沫夹芯结构是近年来新出现的一种明显具有结构和功能一体化特点的新型轻质材料,它在临近空间飞行器、航海及汽车等领域有着广阔的应用前景。以以纤维增强复合材料面板、闭孔泡沫铝芯子为特征的复合材料夹芯结构为研究对象,对其在球形压头作用下的压痕响应、损伤模式、变形机制和失效机理进行理论分析和实验研究。研究发现,泡沫铝复合材料夹芯结构的压痕响应是夹芯结构的各个组成部分的响应、相互作用以及压头属性的综合作用结果。泡沫铝复合材料夹芯结构在球压头作用下的损伤模式为基体开裂、纤维断裂、层间分层、泡沫铝的屈服及剪切断裂五种失效模式。     

Dynamic parameters of multi-cabin protective structure subjected to low-impact load – Numerical and experimental investigations

The dynamic response of a multi-cabin protective structure subjected to impact load directly affects the protective performance of materials; thus, studying the dynamic response and communication law of wave effect of the load plays an important role in the prediction of protective performance. In this study, the protection experiments of box-structure under air- and/or water-medium are conducted, the dynamic response of the structure subjected to low-impact load is analyzed, and the corresponding numerical simulations are analyzed using the theory of finite element method (FEM). Combined with experimental and FEM simulations, the shock strain distribution, acceleration attenuation, and signal energy in defensive materials are determined. Based on the results, the metal structure exhibits good absorption characteristics for shock vibration. Using the experimental data, we also show that the attenuation of shock wave in water medium should be significantly better than that in air medium, and the protective structure should be designed for a combination of water and air mediums. Meanwhile, the numerical simulation can provide a quantitative analysis process for dynamic analysis of defensive materials.     

金属泡沫断裂韧性的试验研究

金属泡沫在其实际应用中,断裂性能和断裂韧性对于承载的多孔金属泡沫有着重要的意义。基于美国试验材料学会相关标准,采用三点弯曲试样测定了铝泡沫的I型断裂韧性。研究表明,金属泡沫的断裂为脆性断裂,在裂纹尖端附近,孔壁最薄弱的区域最容易发生变形;随着进一步加载,一些孔壁发生断裂,微裂纹在断裂尖端附近出现。随着载荷的增加,主裂纹在缺口根部形成或由微裂纹合并而成,并开始在多孔结构内传播。裂纹沿着结构最薄弱处传播,并产生次生裂纹和裂纹桥。裂纹总的扩展方式还是I型断裂。根据试验P-V曲线特点,取最大载荷点对应的力与位移求解出铝泡沫的裂纹尖端临界张开位移的平均值为0.051 mm。     

铝合金-纯铝-钢复合板爆炸焊接试验及性能研究

通过设计爆炸焊接试验复合了铝合金-纯铝-钢爆炸复合板,对其界面形态、显微硬度及力学性能进行了研究。结果表明,铝合金-纯铝界面纯规则正弦波形,纯铝-钢复合板界面波形较小,铝合金-纯铝-钢复合板的界面剪切强度在75 MPa以上,爆炸复合过程中,纯铝与钢界面生成了金属间化合物,其界面处基体金属发生强烈的塑性变形。复合板变形及组织变化的结果造成复合板界面处的显微硬度最高,随着距界面距离的增加,两侧基体金属的硬度逐渐降低。     

Partial penetration of annular grooved projectiles impacting ductile metal targets

Changing and optimizing the projectile nose shape is an important way to achieve specific ballistic performance. One special ballistic performance is the embedding effect, which can achieve a delayed high-explosive reaction on the target surface. This embedding effect includes a rebound phase that is significantly different from the traditional penetration process. To better study embedment behavior, this study proposed a novel nose shape called an annular grooved projectile and defined its interaction process with the ductile metal plate as partial penetration. Specifically, we conducted a series of low-velocity-ballistic tests in which these steel projectiles were used to strike 16-mm-thick target plates made with 2024-O aluminum alloy. We observed the dynamic evolution characteristics of this aluminum alloy near the impact craters and analyzed these characteristics by corresponding cross-sectional views and numerical simulations. The results indicated that the penetration resistance had a brief decrease that was influenced by its groove structure, but then it increased significantly-that is, the fluctuation of penetration resistance was affected by the irregular nose shape. Moreover, we visualized the distribution of the material in the groove and its inflow process through the rheology lines in microscopic tests and the highlighted mesh lines in simulations. The combination of these phenomena revealed the embed-ment mechanism of the annular grooved projectile and optimized the design of the groove shape to achieve a more firm embedment performance. The embedment was achieved primarily by the target material filled in the groove structure. Therefore, preventing the shear failure that occurred on the filling material was key to achieving this embedding effect.     

917低磁钢与铝合金爆炸焊接复合实验研究

采用异种金属爆炸焊接复合技术 ,研制了 91 7低磁钢与LF5、LF2 1、LF1 1等铝合金的爆炸焊接复合板 ,并对该铝—钢复合板力学性能进行了实验研究 ,对复合界面进行了金相分析 .实验结果表明 ,该铝—钢复合板复合界面物理结合良好 ,其抗剪和抗弯强度满足实船使用要求     

榴弹攻击下铝质结构抗爆能力的数值评估

在静爆试验的基础上,结合有限元数值方法对小口径(30 mm)燃烧榴弹舷侧接触爆炸攻击下铝质艇体结构的毁伤进行评估,着重分析了铝质艇体结构在小口径武器攻击下,弹体的攻击角度、弹体的初始侵彻速度以及爆炸产物等对艇体结构破损和毁伤范围的影响以及榴弹爆炸的破片效应.