强冲击波作用下液体抛撒的实验研究

通过强冲击波作用下液体抛撒的系列实验,总结分析了抛撒液体尺寸、爆炸装药量、抛撒液体性质等对液体抛撒运动过程、抛撒半径及液体抛撒作用时间的影响,发现强冲击波作用下液体抛撒速度随时间呈指数衰减,不同的实验参数对衰减系数将产生一定影响。     

竖直下抛液体燃料爆炸抛撒的初步数值研究

对具有轴向初始速度即竖直下抛液体燃料的爆炸抛撒云雾形成过程进行了数值研究。近场的数据来自丁珏等的工作,以此数据作为远场初始参数。远场是燃料液滴与空气、燃料蒸汽、不同尺寸的液滴颗粒组成的多相体系之间的相互作用的过程。液滴的直径比较小,把液滴看成连续介质,且相互作用只考虑液滴的蒸发、破碎、碰撞聚合。轴向初速为0(静爆)时计算结果与实验结果相吻合。这说明本模型可以模拟爆炸抛撒云雾的形成过程,进而可以预估高速运动下云雾的形成过程。用以上模型计算了竖直下抛初速为100m/s、装填5kgPO的FAE装置的爆炸抛撒过程。所得的结果表明,100m/s的初速将影响云雾的最终形状及云雾内部的浓度分布。     

水雾对爆炸冲击波衰减效应的实验研究

为了探究水雾特性与爆炸载荷衰减效果之间的关系，在爆炸驱动的激波管内两种不同特性的水雾环境下进行了不同强度的爆炸实验，并评估了两种水雾对爆炸冲击波超压和比冲量的衰减效果。实验结果表明：喷雾区域内的压力分为两个上升阶段，第一个阶段为透射冲击波的压力，第二个阶段为液滴二次雾化和弛豫过程导致的压力上升；冲击波掠过的喷雾区域越长，水雾对压力峰值和比冲量的衰减效果越好；冲击波强度的增加将削弱水雾对爆炸载荷的衰减效果；Sauter平均直径为136.04μm、体积分数为1.72×10-3的水雾使压力峰值衰减了34.2%～60.9%，使比冲量衰减了9%到54%;Sauter平均直径为255.34μm、体积分数为3.43×10-3的水雾使压力峰值衰减了48.4%～78.6%，使比冲量衰减了14%～66%；冲击波压力峰值的衰减率随着冲击波-雾滴之间的比例交换面积增加而线性减少。     

液体的爆炸抛撒特征

针对液体爆炸抛撒过程设计了实验装置,利用高速摄像仪进行记录。通过研究不同中心装药量和 填充液体的抛撒过程,发现在壳体破裂后,液体沿裂缝处向外飞散。药量较小时,液体分散成树枝状形态,然 后破碎成液滴;药量较大时,则形成液体环状区。对于不同粘度的液体,环状区分别由小液滴及已雾化、汽化 的液体,或大液滴、液体丝及液膜等组成,抛撒过程中其宽度越来越大,大液滴、液体丝及液膜等也逐渐破碎成 细小的液滴。     

爆炸驱动液体分层现象和液滴尺寸模拟

爆炸驱动液体介质外界面的分散和破碎是气溶胶云团形成的重要过程。采用基于维数分裂的欧拉程序和Youngs混合界面处理方法,对中心药爆炸驱动甘油和水介质流场的液体分层现象进行了数值模拟。结合试验结果推断提出了液滴形成过程的三种并存机制:外层射流破碎、内层R-T失稳和中间液层"空化"破碎,分别建立了不同液层破碎液滴的尺寸模拟方法。对比给出抛撒甘油和水装置初级液滴的尺寸分布及最外层理论射流量。     

液氮作用下煤样结构损伤规律研究

为研究液氮浸泡对低渗煤体结构损伤增透的影响,对不同尺寸煤样进行周期性液氮浸泡实验。通过CT扫描观测煤样浸泡前后内部孔隙、裂隙变化情况,采用高倍照相机观测煤样表面形貌,利用超声测速仪测定煤样波速变化,分析液氮浸泡周期对不同尺寸煤样内部结构损伤规律的影响,提出了液氮作用下煤样损伤模型,解释了液氮作用下煤样损伤机理。结果表明:同尺寸煤样,其内部孔隙率、表面裂隙尺寸及波速衰减率随液氮作用周期数的增加而增大,煤样损伤加剧;同周期浸泡条件下,随着煤样尺寸的增大,液氮作用后的煤样孔隙率逐渐降低;液氮作用周期为1T时,煤样孔隙率增加相对显著,损伤效果明显,1T后煤样孔隙率增加幅度逐渐减小;液氮的超低温作用使煤岩基质收缩,煤岩内部产生新微孔隙,多次作用后,微孔隙发育、扩展和贯通使煤岩出现宏观裂纹并发生破坏。     

FAE爆炸抛撒后云雾液滴尺寸的测量

利用Dobbins激光散射的方法建立了一套测量FAE爆炸抛撒后远场云雾液滴尺寸的测量系统,研究了FAE爆炸抛撒后液滴Sauter平均直径在不同空间位置随时间的变化过程。得出的散射光强以及Sauter平均直径随时间的变化表明,云雾区的液滴Sauter平均直径在固定点随时间的增加呈减小的趋势,而云雾区的宽度和云雾区液滴的Sauter平均直径则随距爆心距离的增加而增加。     

液滴在气体介质中剪切破碎的数值模拟研究

液滴变形和破碎是燃料抛撒问题的重要过程.本文将VOF方法和标准k-ε湍流模型组合,建立了计算液滴在气流中变形破碎过程的数值方法.数值模拟了相关的实验,计算得到的液滴破碎过程与实验结果符合较好.在此基础上,分析了几个关键参数(Weber数、Ohnesorge数、液气密度比)对液滴破碎过程的影响.计算结果表明,Weber数...     

高马赫数下激波液滴相互作用的数值模拟研究

本文采用守恒清晰界面多相流数值方法模拟了超声速和高超声速环境下三维液滴的推进、变形和破碎演化过程.数值模拟结果与实验数据的一致性表明了本文所用数值方法和计算程序的准确性, 而网格无关性研究验证了采用的网格分辨率可以捕捉流场和界面的主要特征. 模拟结果验证了高韦伯数下液滴变形破碎过程所遵循的剪切诱导剥离(SIE)破碎机制, 其包含液滴的扁平化和剪切剥离两个主要特征. 而最近发现的SIE破碎机制下的循环破碎机制也在本文得到了验证, 即主液滴从球形液滴破碎为小液滴会经历多个循环重复的破碎阶段, 高韦伯数下液滴的破碎并非一次性剪切剥离的结果, 而是会发生逐层的剪切剥离和破碎. 本文还研究了马赫数对激波冲击液滴加速变形过程的影响. 结果表明, 高韦伯数下不同马赫数的液滴破碎过程具有高度一致性, 并遵循统一的SIE破碎机制.通过对液滴质心位移、速度、加速度和拽力系数的量化统计揭示其运动过程中的统一加速规律. 在激波的驱动下, 液滴并非以一个恒定的加速度做加速运动.在扁平化不明显的前期, 液滴以一个恒定的加速度做加速运动.随着液滴扁平化的发生, 迎风面积的增加导致拽力系数的增大, 进而导致液滴加速度的不断增大.      

激波作用下液体喷射雾化的实验研究

液体在气流作用下的喷射抛撒过程是流体力学研究中令人感兴趣的重要领域,笔者采用改进后的激波管实现了激波作用下液体的喷射抛撒,并通过阴影照相和激光散射法分别对液体的抛撒状态和抛撒液滴的直径进行了测量,研究表明,在喷射过程中,流场中固定位置所测得的液滴Ｓａｒｔｅｒ平均直径随时间的发展而逐渐减小,在开始时时刻液滴直三小较快而最终渐趋平缓;在对不同抛撒距离雾化场的测量中发现,没位置测得的颗粒最大直 隧测得位     

Attenuation of a shock wave passing through a cloud of water droplets

The mitigation of a planar shock wave caused by a cloud of calibrated water droplets was studied both experimentally and numerically. Experiments were carried out, with different shock wave Mach numbers ranging from 1.1 to 1.8, in a vertical shock tube coupled with a droplet generator which produced a well-characterized cloud of droplets of 120, 250 and 500 μm in diameter. By exploiting such an experimental set-up, we successfully measured the attenuation of a normal shock wave when passing through the water droplet cloud. This series of experiments allowed to identify the main parameters of this investigation and a clear dependence between the attenuation of the shock wave and terms governing the regimes of droplet breakup has been found. On the other hand, to support this experimental approach, 1D unsteady calculations were performed in similar configurations. Although the mathematical model based on an Eulerian/Eulerian approach was actually incomplete, the first comparisons between the experiments and the simulations were rather interesting and pointed out the need to improve the physical model, by taking into account the fragmentation and the vaporization of the droplets submitted to the shock wave as well as the size distribution of the water spray.     

Study of the shock-induced acceleration of hexane droplets

An experimental study of the interaction of a shock wave with a hexane droplet is presented. The main goal of the experiments was to record images of the process and measure basic parameters describing movement, dispersion and evaporation of the droplets engulfed by a shock wave propagating in air. A shock tube with a visualization section was used for this research. Photography of the process allowed one to measure the positions, velocities and sizes of mist clouds created by the interaction processes. Analysis of the pictures shows that there is no qualitative difference between cases for different size droplets, but shock Mach number had a significant effect on the process. Quantitative analysis shows that under certain conditions, a catastrophic breakup mechanism of dispersion occurred. The droplets are shattered into a mist cloud before they achieve mechanical equilibrium with the surrounding gas. The approximate time for the complete dispersion and acceleration of the fuel droplet varies from 300 to 500 μs, and depends both on the droplet diameter and shock velocity. The dispersion time is controlled principally by the droplet diameter, and to a lesser extent, the shock Mach number. This paper is based on work that was presented at the 20th International Colloquium on the Dynamics of Explosions and Reactive Systems, Montreal, Canada, July 31–August 5, 2005.     

平面激波冲击并排液滴的三维数值模拟研究

采用三维守恒清晰界面数值方法, 研究平面激波冲击并排液滴的动力学过程. 研究的焦点在于激波接触液滴后的复杂波系结构生成, 以及并排液滴相互耦合作用诱导的单个液滴非对称界面演化. 首先, 分析并排液滴之间界面通道内的波系结构发展, 发现在冲击初期由于反射激波相交而形成新的反射激波以及马赫杆; 这些流动现象与液滴另外一侧 (非通道侧) 由激波反射所形成的弯曲波阵面截然不同, 而且所导致的液滴横向两侧流场差异是中后期冲击过程液滴两侧界面非对称演化的主要原因. 其次, 研究冲击中期时, 特别是入射激波已运动至液滴下游并远离并排液滴, 界面形态的演化过程和规律, 揭示通道下游出口处由于气流膨胀导致的界面闭合、以及随后气流阻塞导致的界面破碎等新的流动现象. 最后, 研究液滴间距对并排液滴相互作用的影响规律, 发现液滴间距大小与通道内压力峰值具有明显的关联关系. 研究表明, 更小的液滴间距不仅带来更大的压力峰值, 而且使得峰值出现的时间更早.      

液滴在激波冲击下的破裂过程

对液滴在入射激波作用下的变形破碎过程进行了实验研究和数值模拟,得知数值模拟结果与实验结果基本吻合,以及在什么情况下两者出现分歧。结果显示,液滴在激波的作用下要经历从压缩变形、RM不稳定性变形、细小液雾剥离到全部雾化破碎等过程。结果还表明,不同液滴直径、入射激波马赫数和液滴介质等参数下的液滴变形破碎的发展趋势是一致的,而其发展速度明显则不同。其中Weber数的增加加速了液滴的破碎,而Ohnesorge数和黏性的增加则抑制了液滴的破碎。     

Shock wave interactions with particles and liquid fuel droplets

Shock waves traveling through a multiphase flow environment are studied numerically using the Flux Corrected Transport (FCT) algorithm. Both solid particles and liquid droplets are used as the dispersed phase with their trajectories being computed using a Lagrangian tracking scheme. The phases are coupled by including source terms which account for mass transfer, momentum, and energy exchange from the dispersed phase in the governing equations of motion for the gas phase. For solid particles, droplet size effects are examined at constant mass loading. Deceleration of the shock wave is observed with effects increasing with decreasing particle size. The equilibrium velocity attained is found to agree with analytical results for an equivalent dense gas with a modified specific heat ratio. For liquid droplets, a droplet breakup model is introduced and the results show a faster attenuation rate than with the solid particle model. The inclusion of vaporization to the breakup model is seen to increase the attenuation rate but does not alter the final equilibrium velocity. When an energy release model is used in the simulations, behavior resembling a detonation is observed under certain conditions, with energy release coupling with and accelerating the shock front. Received 17 July 2000 / Accepted 20 August 2002 / Published online 4 December 2002 Correspondence to: Dr. K. Kailasanath (e-mail: kailas@lcp.nrl.navy.mil)     

竖直振动无黏液滴的法拉第不稳定性分析

由于外部周期性的振动而在液滴表面产生的Faraday不稳定效应广泛存在于超声雾化、喷涂加工等应用中,对Faraday不稳定性进行分析对研究振动液滴的表面动力学有着重要意义.本文将Faraday不稳定性问题从径向振动拓展到竖直振动,研究了竖直振动无黏液滴表面波的不稳定性.竖直方向的振动使得液滴动量方程为含有空间相关项和时...     

煤油液滴直径对两相旋转爆轰发动机流场的影响

为探究煤油液滴不同初始直径对气液两相旋转爆轰发动机流场的影响，假设初始注入的煤油液滴具有均匀直径，考虑雾化破碎、蒸发等过程，建立了非定常两相爆轰的Eulerian-Lagrangian模型，进行了液态煤油/高温空气爆轰的非预混二维数值模拟。结果表明：在初始液滴直径为1～70μm的工况范围，燃烧室内均形成了单个稳定传播的旋转爆轰波；全局当量比为1时，爆轰波前的空气区域大于液滴煤油的蒸气区域，导致波前燃料空气混合不均匀，波前均存在富油区和贫油区，两相速度差导致分离出的空气形成低温条带；当煤油液滴的初始直径较小时，波前的反应物混合过程主要受蒸发的影响，爆轰波可稳定传播；当直径减小至1μm时，煤油液滴在入口处即蒸发，旋转爆轰波表现为气相传播的特性，爆轰波结构平整；当煤油液滴的初始直径较大时，波前的反应物混合过程主要受液滴破碎的影响；对于相同的燃料质量流量，在不同初始煤油液滴直径工况下，煤油液滴最大的停留时间均占爆轰波传播时间尺度的80%以上；爆轰波前燃料预蒸发为气相的占比越高，爆轰波的传播速度越高；初始液滴直径为10～70μm的工况范围内，爆轰波的速度随初始直径的增大先升高后降低。     

Deformation and orientation of single droplets during shear flow: combined effects of confinement and compatibilization

Combined effects of geometrical confinement and compatibilization on the deformation and orientation of single droplets during steady-state shear flow are investigated in a counter-rotating cell by means of microscopic observations. The model system consists of polydimethylsiloxane droplets of varying sizes and viscosities in a polyisobutylene matrix. To this system, a premade polyisobutylene–polydimethylsiloxane block copolymer is added as compatibilizer in different concentrations. For each droplet, the equilibrium interfacial tension is determined by comparing droplet axes with the predictions of the confined Minale model for uncompatibilized droplets at the appropriate degree of confinement. Although large reductions in interfacial tension are seen for all compatibilized droplets, it is shown that the effect of compatibilization on droplet deformation and orientation can efficiently be taken into account in the equilibrium capillary number. This way, for all viscosity ratios and confinement ratios, steady-state data for compatibilized and uncompatibilized droplets coincide, and agree well with the predictions of the confined Minale model at sub-critical conditions. For near-critical capillary numbers, compatibilization slightly reduces droplet deformation and postpones breakup, irrespective of the degree of confinement.     

Shock wave structure in a mixture of gas,vapour and droplets

The structure of the relaxation zone behind a shock wave of moderate strength in a mixture of gas, vapour and droplets is analysed. A model is presented for shock induced evaporation, which is based on wet-bulb equilibrium and on the absence of relative motion between droplets and gas. Experimental and numerical data on heterogeneous condensation induced by an unsteady rarefaction wave and on re-evaporation due to shock wave passage are reported for a mixture of water vapour, nitrogen gas and condensation nuclei. Pressure, temperature, saturation ratio and droplet size are experimentally obtained and are very well predicted by a numerical simulation based on the non-linear quasisteady wet-bulb model for phase transition, as well for the expansion wave as for the shock wave. During expansion, droplet number density decays much faster than predicted, which is not yet satisfactorily explained. Shock induced droplet evaporation is studied for post-shock saturation ratios ranging from 5×10^–3 to 0.2, corresponding to shock Mach numbers of 1.2 to 1.9. The evaporation times are well predicted by the theoretical model. No evidence is found for droplet break-up for Weber numbers up to 13, and droplet radii of the order of 1m.On leave at Institute of Fluid Science, Shock Wave Research Center, Tohoku University, Sendai 980, JapanThis article was processed using Springer-Verlag T_EX Shock Waves macro package 1.0 and the AMS fonts, developed by the American Mathematical Society.