碳纤维/环氧树脂复合材料3.0～6.5 km/s超高速撞击成坑特性研究

为研究碳纤维/环氧树脂复合材料在超高速撞击下的成坑特性,利用二级轻气炮开展了直径为1.00～3.05 mm的铝球以3.0～6.5 km/s的速度正撞击尺寸为100 mm×100 mm×20 mm的碳纤维/环氧树脂复合材料靶板的实验,获得了碳纤维/环氧复合材料靶板的成坑形貌特征,并测量了坑深、成坑表面积、表面损伤面积等尺寸。结合文献数据分析了靶板的无量纲成坑深度p/d_p、无量纲坑径系数D_h/d_p、表面损伤面积等效直径D_e等随撞击速度、撞击能量的变化规律。结果表明:碳纤维/环氧树脂复合材料的无量纲成坑深度p/d_p和无量纲坑径系数D_h/d_p均与撞击速度呈2/3次幂关系;表面损伤面积等效直径D_e与弹丸撞击能量E呈幂函数关系;成坑深度大于成坑半径。     

弹体侵彻厚混凝土靶迎弹面成坑效应

为研究弹体侵彻厚混凝土靶的迎弹面成坑效应,总结了侵彻实验中的成坑现象,分析了经验公式对成坑深度、成坑直径和成坑角等成坑效应的预测效果;考虑了撞击速度、靶板强度、配筋以及弹体直径和质量等因素的影响,采用量纲分析方法建立了新型成坑效应计算公式及成坑阶段耗能计算公式;基于新型成坑效应计算公式,对成坑效应的影响因素和成坑耗能进行了参数化分析。结果表明:无量纲成坑深度受靶板强度、配筋率和弹体质量的影响较大;对于钢筋混凝土,成坑深度随撞击速度提升呈先增大后减小再增大的变化规律;在常见的侵彻速度和质量范围内,成坑角为15°～24°,质量对成坑角影响较小;迎弹面成坑耗能占弹体总动能的10%～25%,且配筋率和靶板强度对成坑耗能比例的影响较小;弹体质量越小,成坑阶段耗能占比越大。新型成坑效应计算公式对成坑深度、直径和角度的计算结果与实验数据吻合较好,可为侵彻弹体设计和工程防护提供参考。     

镁合金弹丸10km/s撞击铝靶成坑特性实验

为获得10 km/s超高速撞击成坑特性,采用内爆发射器开展了长径比l/d_p为1/2、直径d_p为0.8 cm的镁合金弹丸撞击厚5 cm铝靶的超高速撞击实验,获得了铝靶的撞击成坑尺寸和形貌特性,结合文献数据,分析了成坑形貌与8 km/s以下速度撞击坑的差异和弹丸长径比、速度、动能对成坑尺寸的影响。结果表明:典型的撞击坑不仅包含中心成坑区,还包含了破坏区,成坑区近似半球形弹坑,破坏区为自由表面剥落形成的浅坑;坑深P_c/d_p为1.5～2.0,坑径d_c/d_p为3～3.5,坑形系数P_c/d_c为0.50,成坑效率E/V_c均值为3.74 kJ/cm3;对于l/d_p≤1的弹丸,采用等效直径对坑深进行归一化,归一化后坑深与长径比无关,与速度的2/3次幂成线性关系。     

依兰陨石坑形成过程数值模拟研究

基于iSALE-2D仿真代码对依兰陨石坑的形成过程进行了研究,采用欧拉算法开展数值模拟,探讨了依兰陨石坑的撞击条件,统计分析了成坑过程中熔化层的形成与分布规律,结合点源成坑相似律模型,拟合得到强度机制下的成坑半径关系式。研究结果表明一颗直径120 m、撞击速度12 km/s的花岗岩质小行星垂直撞击地表形成一个与依兰陨石坑形态相似的陨石坑,再现了成坑形成的3个阶段：接触与压缩阶段、开坑阶段、后期调整阶段。大部分熔体在坑底呈分层堆叠分布,少量熔体随抛射物沉积在靶体表面,呈离散状分布,完全熔化材料质量约为撞击体质量的24倍。直径120 m、撞击速度12 km/s工况模拟结果与拟合的成坑半径关系式结果相对误差10.3%。     

大应变、高应变率及高压强条件下混凝土的计算模型

给出了混凝土在高速撞击条件下一种新的计算模型 ,同以前的工作相比 ,它可以很好地模拟在撞击过程中混凝土靶的成坑、层裂情况以及混凝土靶内出现的断裂现象。计算的结果同以前的模型计算结果和实验数据进行了比较。     

93W杆式弹超高速撞击多层Q345钢靶毁伤及微观分析

为了解杆式弹超高速撞击多层薄钢靶的破坏过程及毁伤机理,开展了克级93W杆式弹正撞击多层Q345钢靶实验及数值模拟研究,通过扫描电子显微镜（scanning electron microscope,SEM）及金相显微镜,分析了超高速撞击实验后靶板材料的微观组织及成分。结果表明,超高速撞击作用下,靶板呈现出“翻唇”穿孔变形、花瓣状塑性变形、撕裂、撞击成坑及鼓包等破坏模式。靶板前3层毁伤以超高速穿孔为主,孔洞数目多但面积小,后几层靶板毁伤孔洞数目少且孔径呈先增大后减小趋势。微观分析表明靶材在强冲击压力下发生晶粒碎化、熔化及再结晶,撞击过程中会形成微孔聚集与微裂纹,可见靶板失效主要是熔融混合物冷却过程中产生的热应力与切应力下的剪切撕裂综合作用的结果。     

钨合金弹体对混凝土靶的超高速侵彻机理

为研究钨合金弹体超高速侵彻混凝土靶的相关机理,构建了适用于超高速撞击的金属强度模型、失效模型和混凝土的本构模型,对93钨合金弹体超高速撞击混凝土靶问题进行了数值模拟。开展了钨合金弹体超高速撞击混凝土靶实验,分析了靶板成坑特性,研究了侵彻总深度和残余弹体长度随撞击速度的变化规律,理论分析了长杆钨弹超高速撞击混凝土的侵彻模型和混凝土靶内的应力波传播。得到以下主要结论:（1）利用金属及混凝土的新本构模型获得的超高速撞击混凝土靶的破坏形貌数值模拟结果与实验结果一致;（2）超高速撞击条件下混凝土靶成坑为“弹坑＋弹洞”形,成坑体积与弹体动能近似成正比;（3）超高速撞击条件下,侵彻深度随弹速提高呈现先增大后减小的现象,高速段侵深降低是弹体经历销蚀侵彻后“刚体侵彻阶段”减少造成的;（4）建立的钨合金超高速撞击混凝土侵彻分析模型,可用来预估侵彻深度、残余弹长、蘑菇头直径等参数;（5）采用建立的超高速撞击混凝土靶内应力波传播理论模型得到的计算结果与实验结果吻合较好。     

不同壁面条件下液滴撞击铺展特性的模拟研究

液滴撞击不同润湿性壁面的传热流动问题在自然界和工业生产中广泛存在。研究采用CLSVOF方法,引入描述壁面润湿特性的动态接触角,并考虑液滴物性参数随温度的变化,建立液滴撞壁模型,模拟研究液滴撞击流动行为,通过与实验对比验证,确定模型有效性。在此基础上,对传热作用下考虑壁面润湿性的液滴撞击问题展开研究,探讨壁面传热作用对液滴撞击铺展特性的影响。研究表明,在撞击过程中,液滴先铺展后逐渐收缩,与静态接触角模型相比,采用动态接触角模型所得的液滴流动特性与实验结果更加吻合;随着接触角增大,液滴在撞壁初期不易铺展,随后则易于收缩;虽然固液传热作用会影响液滴铺展直径,但不改变液滴的运动趋势。     

近地小天体对地撞击成坑模型研究进展

近地小天体对地撞击成坑是行星研究的前沿问题之一。本文中介绍了陨石坑成坑过程与类型、实验室模拟成坑现象和陨石坑成坑模型律，分析了近地小天体对地撞击成坑机理和点源模型的不足，指出了近地小天体对地撞击成坑未来研究的发展趋势。     

超高速撞击厚靶过程的能量分配研究

超高速撞击过程的能量分配研究,对于解决动能撞击、发展导弹拦截技术、判定空间飞行器被撞事件及评估碰撞破坏程度具有重要的理论意义。本文在总结前人关于超高速撞击过程能量分配的基础上,将超高速撞击厚靶过程中弹丸的动能分配归纳为靶板的变形能、弹丸与靶板作用过程应力波传播使靶板内能的增加、撞击产生碎片的崩溅能和产生电磁辐射的辐射能,并结合理论推导、实验和数值模拟对撞击速度为2.61km/s且正碰撞2A12铝靶的能量分配进行了定量计算。研究结果表明：无论在弹坑的形貌、尺寸还是辐射温度等方面,实验测量结果、理论推导结果与数值模拟的结果均基本吻合。该研究成果在解决行驶中的车辆碰撞问题以及航空飞行器遭遇鸟撞等领域亦有重要的参考价值。     

Impact of liquid drops on a rough surface comprising microgrooves

Impact of water drops on a stainless steel surface comprising rectangular shaped parallel grooves is studied experimentally. Geometric parameters of the surface groove structure such as groove depth, groove width and solid pillar width separating any two successive grooves were kept at 7.5, 136 and 66 μm, respectively. The study was confined to the impact of drops in inertia dominated flow regime with Weber number in the range 15–257. Experimental results of drop impact process obtained for the grooved surface were compared with those obtained for a smooth surface to elucidate the influence of surface grooves on the impact process. The grooves definitely influence both spreading and receding processes of impacting liquid drops. A more striking observation from this study is that the receding process of impacting liquid drops is dramatically changed by the groove structure for all droplet Weber number.     

Influence of liquid layers on energy absorption during particle impact

The influence of the thickness of a covering liquid layer and its viscosity as well as the impact velocity on energy loss during the normal impact on a flat steel wall of spherical granules with a liquid layer was studied. Free-fall experiments were performed to obtain the restitution coefficient of elastic-plastic γ- Al2O3 granules by impact on the liquid layer, using aqueous solutions of hydroxypropyl methylcellulose with different concentrations for variation of viscosity （1-300 mPa s）, In the presence of a liquid layer, increase of liquid viscosity decreases the restitution coefficient and the minimum thickness of the liquid layer at which the granule sticks to the wall. The measured restitution coefficients were compared with experiments performed without liquid layer. In contrast to the dry restitution coefficient, due to viscous losses at lower impact velocity, higher energy dissipation was obtained, A rational explanation for the effects obtained was given by results of numerically solved force and energy balances for a granule impact on a liquid layer on the wall. The model takes into account forces acting on the granule including viscous, surface tension, capillary, contact, drag, buoyancy and gravitational forces. Good agreement between simulations and experiments has been achieved.     

Study of the impacts of droplets deposited from the gas core onto a gas-sheared liquid film

The results of an experimental study on droplet impactions in the flow of a gas-sheared liquid film are presented. In contrast to most similar studies, the impacting droplets were entrained from film surface by the gas stream. The measurements provide film thickness data, resolved in both longitudinal and transverse coordinates and in time together with the images of droplets above the interface and images of gas bubbles entrapped by liquid film. The parameters of impacting droplets were measured together with the local liquid film thickness. Two main scenarios of droplet-film interaction, based on type of film perturbation, are identified; the parameter identifying which scenario occurs is identified as the angle of impingement. At large angles an asymmetric crater appears on film surface; at shallow angles a long, narrow furrow appears. The most significant difference between the two scenarios is related to possible impact outcome: craters may lead to creation secondary droplets, whereas furrows are accompanied by entrapment of gas bubbles into the liquid film. In addition, occurrence of partial survival of impacting droplet is reported.     

Phase Doppler measurements of spray impact onto rigid walls

In this work, an experimental study of spray impact onto a horizontal flat and rigid surface is presented. The phase Doppler technique has been used to characterize both the impacting and the secondary spray in terms of mass and number flux, size distribution and velocities of the droplets above the target. A high-resolution CCD camera has been used to measure the average liquid film thickness formed due to spray impact, whereas a high-speed CMOS camera has been used to characterize the splashing droplets from the wall. This visualization of the splashing phenomenon and the knowledge about the liquid film thickness are used to formulate a new physical model of the crown evolution. Furthermore, information about the incident-to-ejected mass fraction and number fraction are novel contributions of this study. Considerable data are provided comparing the impact of single drops onto a liquid film to impact of drops in a spray, and the significance of the observed differences for modelling efforts is discussed. The measurements of this study are also shown to be rather sensitive to the placement of the phase Doppler measurement volume above the surface and to the operating parameters of the instrument. These effects have been documented and discussed for this particular measurement situation.     

Effect of solidification on drop fragmentation in liquid–liquid media

 This paper presents results of experimental and analytical investigation on molten alloy drop fragmentation in water pool. Emphasis is directed towards delineating the roles which melt to coolant heat transfer and melt solidification play in the fragmentation process. The strong impact of coolant temperature upon fragmentation process is addressed. A set of 23 drop fragmentation experiments were performed, in which 8 experiments employed a low melting point alloy, cerrobend-70 and 15 experiments using Pb–Bi eutectic alloy as drop fluid. The results show strong impact of coolant temperature on particle size distribution of the fragmented drops. A linear stability analysis of the interface between the two liquid fluids with thin crust growing between them, is performed. A modified dimensionless Aeroelastic number, for Kelvin–Helmholtz instability, is obtained and used as a criteria for fragmentation of molten drops penetrating into another liquid coolant media with lower temperature. The nondimensionalized mean diameter of the fragmented particles is correlated with the Aeroelastic number. Received on 26 March 2000     

长飞片撞击薄靶板结构的定位技术及实验研究

出于防护机匣被发动机破碎叶片破坏的需求,利用一级轻气炮实验装置对长飞片高速撞击薄靶板结构进行冲击实验和测试方法的研究.实验中使用对靶定位控制技术保证长飞片对靶板撞击的位置准确定位,同时碰撞平面度误差小于10毫弧度,得到了不同撞击参数下薄板击穿性能的实验数据.实验结果表明:薄板的破坏失效模式为隆起-剪切破坏,裂纹出现及发展也主要由于剪切应力造成.本研究可为进一步的相关结构冲击实验及测试方法提供参考.