Stress waves propagation in solids under high-speed liquid impact

An experiment of impact between 450 m/s water jets and polymethylme- thacrylate (PMMA) materials with complex surface geometry was conducted. The testing surfaces were a corner, step change, surface-breaking notch, inclined surface, etc. Stress waves propagation in the solid such as reflection, interference and diffraction was observed using polarized optics and an Imacon high speed camera (operating at both of 106 and 5×105 framing rates per second, fps). A damage test by the impact of the side jetting of an 850 m/s water jet was also carried out. It was found that stress waves propagation in solids depends not only on the surface geometry but also on the contact situation between liquid and solid. It was shown that the side jetting has sufficient damage potential although its head may consist of finer droplets. The results of this paper are useful to further analyze the dynamic stress state of solids under high-speed liquid impact.

EXPERIMENTAL INVESTIGATION AND COMPUTER SIMULATION ON DYNAMIC BUCKLING BEHAVIOR OF LIQUID-FILLED CYLINDRICAL SHELLS UNDER AXIAL IMPACT

This article reports an experimental investigation on the axial impact buckling of thin metallic cylindrical shells fully filled with water. Low velocity impact tests are carried out by DHR-9401 drop hammer rig. The whole process of dynamic buckling is simulated using LS-DYNA computer code. The consistency between experimental observation and numerical simulation is quite satisfactory. The investigation indicates that quite high internal hydrodynamic pressure occurs inside the shell during the impact process. Under the combined action of the high internal pressure and axial compression plastic buckling occurs easily in the thin-walled shells and buckling modes take on regular and axisymmetric wrinkles.

Study on Nonlinear Coupling Wave Model for Liquid Droplet-Solid Impact

In order to investigate the material corrosion by liquid droplet solid impact, a nonlinear coupling wave model adopted to analyze the impact between the spherical liquid droplet and an elastic solid plane has been developed. Many usable results such as the dimensionless pressure in the contact plane of liquid solid and inside the liquid droplet, the equivalent stress distribution inside the solid, the effect of solid elasticity on the impact, and the locations of the maximum equivalent stress in different...

Mechanism of drilling rate improvement using high-pressure liquid nitrogen jet

To address the high rock strength and low drilling rate issues in deep oil/gas and geothermal exploitation, we performed mechanical property tests on three kinds of rock samples(granite, shale and sandstone) subjected to liquid nitrogen(LN2) cooling and conducted rock-breaking experiments using LN2 jet. Rock-breaking characteristics and mechanisms of LN2 jet, heat transfer features between LN2 and rock and thermal stress evolution in rock were analyzed. A novel high-pressure LN2 jet assisted drilling method was proposed accordingly. The study results show that LN2 thermal shock can significantly reduce uniaxial compression strength and elastic modulus of rock. Rock damage and corresponding mechanical deterioration become more pronounced with increasing rock temperature. The LN2 jet has merits of high rock-breaking efficiency and low threshold rock-breaking pressure. Rock failure under LN2 jet impact is characterized by large volume breakage and the rock-breaking performance becomes more significant with increase of rock temperature. Under the impact of LN2 jet, the damage of granite is the most remarkable among the three rock samples. Thus, this method works better for high temperature granite formations. It has a good application prospect in speeding up drilling rate in deep hot dry rock geothermal reservoirs.

新型液阻式泵阀冲击特性研究

为了降低阀芯与阀座冲击应力减小二者间冲击磨损,提出一种液阻式新型泵阀。采用数值仿真方法对泵阀液阻结构参数进行了优化,并仿真计算了阀芯与阀座的冲击速度和泵阀碰撞冲击的压力接触情况。对比分析了液阻泵阀和传统泵阀的运动特征及冲击应力结果,并搭建试验台架对仿真模型结果进行验证。结果表明,在阀芯下落阶段,带液阻结构的泵阀的回落速度明显小于传统泵阀,传统泵阀阀芯与阀座相接触的速度达到了0.118 m/s,而带液阻结构泵阀的阀芯与阀座相接触的速度仅为传统泵阀的1/6左右,约为0.02 m/s;带液阻结构的泵阀只发生了1次碰撞,而传统泵阀发生了2次碰撞,在碰撞时,带液阻结构的泵阀阀芯与阀座上的最大接触应力约为260 MPa,而传统泵阀第1次碰撞为190 MPa,第2次为270 MPa;液阻式泵阀能明显降低阀芯与阀座相接触的速度,降低冲击应力,从而减小泵阀的冲击磨损。研究结果可为液阻式泵阀的设计和应用提供参考。

Spray Atomization and Structure of Supersonic Liquid Jet with Various Viscosities of Non-Newtonian Fluids

These experimental investigations are designed to study shock wave characteristics and spray structure. Supersonic liq- uid jets injected into ambient fields are empirically studied using projectile impacts in a two-stage light gas gun. This study looks primarily at the design of the nozzle assembly, the tip velocity of the high speed jet, the structure of the spray jet and the shock wave generation process. The supersonic liquid jets were visualized using an ultra high-speed camera and the schlieren system for visualization to quantitatively analyze the shock wave angle. The experimental re- sults with straight cone nozzle types and various non-Newtonian fluid viscosities are presented in this paper. The effects of nozzle geometry on the jet behavior are described. The characteristics of the shock wave generation and spray jet structure were found to be significantly related to the nozzle geometry. The expansion gases accelerated the projectile, which had a mass of 6 grams, from 250 m/s. As a result, it was found that the maximum jet velocity appeared in the liquid jet with high viscosity properties. Supersonic liquid jets, which occurred at the leading edge the shock waves and the compression waves in front of the jets, were observed. Also, the shock waves significantly affected the atomization process for each spray droplet.

滨海核电厂液态流出物间歇排放数值模拟分析

应用非结构化网格MIKE 21水动力模型及对流扩散模块,针对某滨海核电厂工程海域建立液态流出物排放数学模型,对核电厂运营期间液态流出物中核素在等浓度排放条件下4种不同典型潮时(涨憩、落急、落憩、涨急)起始的间歇排放进行数值模拟,并与连续排放进行比较,给出了不同工况下液态流出物在环境水域中全潮平均相对浓度分布及影响范围、不同半径海域内核素的平均相对浓度以及取水相对浓度特征值。对比分析显示,滨海核电液态流出物在受纳水体中的输移、扩散主要受潮流影响。落急时刻起始的间歇排放方式总体上在环境影响和取水浓度方面均具有显著优势。计算结果可为核电厂液态流出物排放方式的优化及海洋环境影响评价提供了依据。

冲击式水轮机转轮水斗汛期泥沙磨损特性分析

泥沙磨损是冲击式水轮机水力部件失效的主要原因之一,特别是在汛期时,过机泥沙含量会大幅增加,而转轮水斗表面的挟沙三相流动过程复杂,其磨损问题会更为严重。本文以规划建设的西藏紫霞电站冲击式水轮机为研究对象,根据设计院提供的电站实测泥沙特性数据,采用Mansouri磨损模型和欧拉-拉格朗日方法对泥沙颗粒在转轮水斗表面的流动过程进行了三相流动数值模拟,分析了电站在汛期高泥沙浓度下颗粒的流动特性以及水斗表面的磨损分布。预测的水斗表面磨损分布与文献中实测的较为一致,预测结果表明水斗主要磨损区分布在靠近水斗根部的出水边附近以及缺口边附近;磨损分布和冲击次数的分布相似度最高,冲击次数对泥沙磨损的影响很大。

Marangoni流动对液滴撞击过热液池影响的数值模拟

对液滴撞击过热液池的动态过程进行数值模拟,着重关注由液池表面不均匀温度引起的马兰戈尼效应(Marangoni effect)对液池内的流场和温度场演化过程的影响。当乙醇液滴落入过热油池后,液池表面温度随着液滴的靠近而迅速下降,从而在径向上产生很大的温度梯度。由此引发的沿径向向内的Marangoni力会与沿径向向外的蒸汽剪切应力相抗衡,进而在蒸汽层最薄的位置形成一个“热射流”结构。随着时间的推进,占据主导地位的Marangoni力逐渐将“热射流”向内推动,直至在液滴下方形成下沉羽流。此外,随着液池黏度的增加,液池内由表面蒸汽应力引起的流动将被抑制,进而导致界面附近的换热效率大幅下降。

冲击载荷下蓄液结构动响应及防护机理的研究进展

工程实际中,飞机油箱、船舶液舱、油液储罐等各类蓄液结构可能面临炸药爆炸冲击波、弹丸侵彻等冲击载荷的威胁。在冲击载荷作用下,蓄液结构的动响应受载荷特性、结构形式、充液方式等多种因素影响,相应的结构防护机理涉及多相介质的流固耦合、波在不同介质中的传播、液体介质的空化、结构动态力学特性等多个科学问题。针对冲击载荷下蓄液结构的动响应及防护机理,总结了工程领域中典型的蓄液结构形式,分析了各类蓄液结构在爆炸冲击波、弹体侵彻及其联合作用等载荷下的结构动响应过程、结构破坏模式、载荷耗散过程、能量转化与吸收过程,总结了蓄液结构的冲击动响应特性,归纳了蓄液结构对各类冲击载荷的防护机理,从结构构型、结构动响应、理论研究方法、抗冲击防护技术等方面对蓄液结构抗冲击防护研究进行了展望。

管路液体冲击效应对压力传感器的影响研究

压力传感器作为管路压力测试的主要手段,应用在军用、民用各个领域,硅压阻压力传感器是目前应用最广泛的一种压力传感器,其特点是精度高、稳定性好、价格低、适于批量生产。在一些特定的环境下,被测管路内的液体工质会由于外部的振动、冲击、噪声等力学环境,使管路内部产生一个动态的异常冲击压力,这种冲击压力的幅频特性与管路的长短粗细、工质的特性、外部的激发量级、工质的温度等都相关,很难用理论公式准确地计算出结果。这种动态冲击信号往往会对压力传感器产生一定的机械损伤,本文介绍了特定条件下的管路内液体冲击压力的形成以及其对于传感器的影响,并经过试验进行了验证,为后续的工程应用提供一定的借鉴作用。

活性破片撞击液箱毁伤行为仿真研究

显著不同于传统惰性金属破片,活性破片在撞击液箱时,能够利用动能撞击和爆燃反应等双重机理实现侵、爆耦合作用液箱毁伤模式。文章利用AUTODYN有限元分析软件,研究了活性破片撞击液箱的结构毁伤增强行为。研究结果表明,在撞击液箱过程中,活性破片进入液体后将在化学能释放作用下形成类椭圆形空穴,且对液箱侧壁面造成的冲击更为严重;随着液箱前板厚度增加,空穴体积和前板最大隆起呈现先增大后减小趋势,前板侵孔直径则呈现逐渐增大趋势;随着撞击速度加快,活性破片激活率增加且动能增大,空穴体积和前板最大隆起逐渐增大,前板侵孔直径逐渐减小;随着注水率逐渐下降,箱体受到的冲击强度逐渐减小,前板最大隆起减小,且前板变形逐渐集中在一侧,但前板侵孔直径变化不明显。

单液滴撞击平面液膜飞溅过程的CLSVOF模拟

采用CLSVOF(coupled level set and volume of fluid)方法对单液滴撞击平面液膜初期的飞溅过程进行了数值模拟,探讨了撞击速度和液膜厚度对撞击后形成冠状水花形态及扩展直径的影响。结果显示,扩展直径随撞击速度的增大而增大,随液膜厚度的增大而减小,CLSVOF方法可较好地用于液滴撞击过程的数值计算。

建筑工人流动性影响因子分析研究

为了有效降低建筑业的安全事故发生率,需要从改善建筑工人的高流动性入手,分析建筑工人流动性产生的关键影响因素。基于行为心理学理论,将建筑工人流动行为的产生分为三个阶段,分别分析各个阶段的影响因素,并结合前人的研究提取出12个影响因子;通过现场调研获得数据,采用决策试验和评价实验室(DEMATEL)方法计算各个因子的原因度、中心度和影响度,得到影响因子间的综合影响矩阵,由此分析出工作收入、自身规划、生存压力和领导对流动性的态度对建筑工人的流动性影响最为重要,此外政府监管通过影响领导对流动性的态度和现场管理对流动性产生有较大的间接影响。结果表明:工作收入对建筑工人的流动性影响最大,领导对流动性的态度对劳务企业的流动性状况有较大影响。

汽轮机末级叶片纳米涂层抗水蚀性能研究

采用高压脉冲水射流试验装置对不锈钢、司太立合金及CNx/TiN纳米复合涂层的性能进行测试,并采用扫描电镜对材料的失效破坏形貌及机理进行了分析。结果表明,纳米涂层具有优异的抗水蚀性能,可以作为汽轮机末级叶片抗水蚀用涂层。

液固撞击的非线性波动模型的研究

推导了可用于研究液固撞击问题的非线性波动模型 ,并将其应用于水锤过程及球形液滴与刚性固体平面法向撞击过程的数值分析 .通过对水锤过程的模拟分析 ,给出了液固接触面压力随时间的分布 ;对球形液滴与刚性固体平面撞击过程的模拟 ,给出了不同时间液固接触面上无量纲压力分布 ,以及液滴内无量纲压力的等值线 .结果表明 ,非线性波动模型可以给出详细的液固撞击过程的各物理参量 ,为液滴侵蚀固体表面问题的研究提供了可靠的依据 .结果与精确解吻合良好 ,从而对非线性波动模型进行了验证 .

电液压脉冲技术在油田集输管网清垢中的应用

在油田集输管网清垢中,电液压脉冲技术的应用是以电液压脉冲技术体外冲击波碎石的实践和先进的振荡脉冲射流喷嘴理论为基础,利用电液压脉冲清除管道内表面垢层。为产生电液压效应,需满足4个必要条件:①具有辅助间隙;②电流幅值大;③电流升高陡度幅度大;④波尾短。提出了液中放电产生压力波波前压力简化计算公式及电液压脉冲技术基本应用方案。

SPH方法在液固撞击数值模拟中的应用

对液滴分别采用光滑粒子流体动力学(SPH)和任意拉格朗日-欧拉(ALE)两种方法模拟液滴高速冲击有机玻璃(PMMA)过程中液滴的变形、固体结构的损伤.结果表明:两种算法中结构表面的损伤情况与Brunton实验数据吻合,证明了数值分析方法的可行性和精确性;此外,对比发现SPH方法模拟液固撞击过程更具有优势.利用SPH方法分析实际工程问题,验证了两种工程处理技术可以有效地提高螺旋桨抗雨水的冲击能力.

单液滴撞击球面液膜水花形成特征分析

应用VOF(volume of fluid)方法对液滴撞击球面液膜的飞溅过程进行数值模拟,由计算结果分析了不同液滴撞击速度和液膜厚度对撞击产生的水花形态、高度和直径的影响。结果表明:随着液滴撞击速度和液膜厚度的增加,水花高度增大;随着液滴撞击速度增加,水花直径增大,但当液膜厚度增加时,水花直径减小。

液固高速撞击时材料表面损伤的数值模拟

为了研究液固撞击的机理,采用光滑粒子流体动力学方法(SPH)与有限单元法(FEM)建立了考虑流固耦合效应的高速液固撞击数值模型,详细分析了直径为2 mm、撞击速度为1 000 m/s的液滴和射流对有机玻璃(PMMA)的三维撞击和破坏状况.分析表明:射流与液滴在撞击初始时刻的前缘变形和内部压力分布几乎是完全相同的;液滴撞击固体的最大压力值出现在0.20μs时,但此时材料内部最大等效应力只有104 MPa,材料还不足以发生破坏;产生于液固撞击瞬时后0.32μs、速度高达2 925 m/s的侧向射流是使固体表面产生破坏的主要原因,因此撞击最初的破坏位于以撞击中心为圆心的一个圆环区域处.所得材料表面损伤情况与Brunton的实验数据吻合良好,证明了数值模型的可行性和精确性.