可压缩流体的Rayleigh-Taylor和Kelvin-Helmholtz不稳定性

在状态方程为压力是密度的任意单值函数形式情况下，运用小扰动分析和奇异摄动法，给出了流体微扰方程渐近解和界面不稳定性的色散关系. 分析表明：对Rayleigh-Taylor不稳定性，在重力场作用下流体可压缩性形成的密度分布是致稳因素；而扰动流体的膨胀收缩效应助长不稳定性的发展；上层重流体的可压缩性是稳定因素，下层轻流体可压缩性是失稳因素. 而对Kelvin-Helmholtz不稳定性，流体可压缩性助长扰动的发展，是不稳定因素.     

流体可压缩性对Rayleigh-Taylor不稳定性影响机理分析

在等熵方程为压力是密度的任意单值函数形式情况下 ,分析了R T(Rayleigh Taylor)不稳定性中流体可压缩性的作用。在没有边界效应的条件下所作的分析表明 :在重力场作用下流体可压缩性形成的密度分布是R T不稳定性中的致稳因素 ,而扰动流体的膨胀 (收缩 )效应助长R T不稳定性的发展 ;上层重流体的可压缩性是稳定因素 ,而下层轻流体的可压缩性是失稳因素。从扰动发展驱动力和扰动带动的等效质量两个方面对该结论的物理机制进行了分析。     

粘性液体中浮体的非线性稳定理论

本文应用连续系统稳定性理论,处理粘性不可压缩流体所支持的平衡浮体的非线性稳定问题,其中考虑到浮体的方位角和质心位置以及流体速度的非线性扰动,给出了各种尺度的非线性稳定、渐近稳定判据及不稳定判据。     

密封间隙内纳米磁性流体与被密封液体相对运动速度分析

在磁性流体动密封液体中,不相溶的两液体相对运动速度是影响其界面稳定性的主要因素。应用流体运动理论,结合MATLAB仿真,确定了两液体沿旋转轴径向速度分布规律和相对运动速度差的大小。研究结果表明:影响该相对运动速度的因素主要是磁性流体的屈服应力、粘性系数、非牛顿影响系数、旋转轴转速和径向半径,其中非牛顿影响系数和转速最明显,而轴径影响很小;磁性流体与被密封液体相对运动速度差沿轴径呈抛物线分布,说明应用于密封液体的磁性流体具有相应的表观粘度,就能达到与被密封液体的相对运动速度差在界面稳定的阈值范围内。这对深入研究磁性流体与被密封液体的界面稳定性判据及外加磁场的设计具有重要的指导意义。     

薄膜沿加热平板下落的稳定性分布

本文分析了薄膜沿加热平板下落的稳定性。在时间模式下，发现流动的不稳定性是由表面波不稳定和加毛细不稳定构成的，同时当流体的热扩散越大以及界面热量损失越小时，热毛细不稳定越剧烈，在时空模式下，流动随着Marangoni数的增大。流动有可能从对流不稳定过渡到绝对不稳定，这一结论尚待实验验证。     

基于FTM的Kelvin-Helmholtz不稳定性衍化数值分析

采用FTM研究了两相流体界面中的K-H不稳定性,分析了初始振幅、波数、表面张力、密度比、速度梯度、韦伯数We对K-H不稳定性发展的影响。结果表明:增大初始扰动对K-H不稳定性具有促进作用,扰动越强,K-H波浪翻卷高度越高;波数的增加能加快K-H不稳定性的衍化过程,但对K-H波浪高度的发展影响较小;减小表面张力或密度比都能使不稳定性的发展速度增加;初始速度梯度对不稳定性的发展有较大影响,梯度越大,K-H波浪翻卷高度越高;We对K-H波浪的对称性影响较大,We越小,对称程度越高。     

瞬态加速液柱的流体力学问题研究

介绍了用激波和压缩气体加速液柱时的流体动力现象的实验研究,实验中采用了高速摄影技术。研究分为两部分:第一部分,液柱在被加速后在管内的气/液两相流的发展以及流出管外后喷雾流的形成,喷雾流自下而上产生;第二部分,气/液界面上的流体力学不稳定性,即Rayleigh Taylor(RT)不稳定性及Richt myer Meshkov(RM)不稳定性,液柱自上而下运动。实验发现,用此方法产生的喷雾具有流量大、射程远、覆盖面积大等特点。液柱在管内的加速过程中,上端面保持平面,下端面在经历了初始的不稳定性之后形成弹状流。在本实验的驱动压力及马赫数的范围内,RT和RM不稳定性的后期的发展过程比较接近,尽管两者的增长率不同。在RT不稳定性的初始阶段,高密度流体的尖钉先伸入低密度流体中;但是,在RM不稳定性的初始阶段,低密度的气泡先伸入高密度流体中。     

An important fundamental concept of °uid mechanics

不可压缩流体是流体力学的一个重要基本概念,但在流体力学教学的过程中,不可压缩流体与不可压缩均质流体这两个概念经常被混淆,在一些流体力学的教科书中,这两个概念也常被混为一谈,其关键是对物质(随体)导数这个概念理解不正确. 本文对不可压缩流体与不可压缩均质流体这两个重要的流体力学概念进行了辨析,并以此为切入点,介绍了如何理解物质(随体)导数、时间导数、空间导数等概念的区别与关系,澄清了一些教科书中的错误论述.     

二层流体中波动问题的Hamilton正则方程

研究了两种常密度不可压缩理想流体组成的垂直分层的二流体系统的无旋等熵流动,考虑了上层流体与空气及两层流体间的表面张力。流动区域在水平方向无限伸展,上层流体有限深度,下层流体无限深。利用自由面及分界面相对于静止时平衡位置的偏移以及两层流体的速度势构造了Hamilton函数。为导出Hamilton正则方程引用了Euler描述下的流体运动的变分原理。自由面的位移是Hamilton意义下的正则变量,其对偶变量是上层流体在自由面上取值的速度势与密度的乘积。另一个正则变量是分界面的位移,其对偶变量是下层流体的密度与下层流体速度势在分界面上所取值的乘积减去上层流体密度与上层流体速度势在分界面上所取值的相应乘积。导出的Hamilton结构对分析分层流动中表面波与内波的相互作用是重要的。     

黏弹性流体纯弹性不稳定现象研究综述

近年来粘弹性流体流动的弹性不稳定性现象引起了越来越多学者的关注与研究,与牛顿流体惯性不稳定现象不同,这种现象是由粘弹性流体流动中的弹性应力和粘性力之间相互作用,使得在较低的雷诺数下即可产生复杂的流动分岔不稳定现象。当流动中的弹性数（表现为 Deborah 数 De 与Reynolds 数Re 的比值,其中 De 数定义为粘弹性流体的松弛时间和流动的特征时间的比值,Re 数表征流动中惯性力与粘性力之比）较大时,在 Re<相似文献   

Perturbation solution of Poiseuille flow of a weakly compressible Oldroyd-B fluid

The isothermal, planar Poiseuille flow of a weakly compressible Oldroyd-B fluid is considered under the assumption that the density of the fluid obeys a linear equation of state. A perturbation analysis for all the primary flow variables is carried out with the isothermal compressibility serving as the perturbation parameter. The sequence of partial differential equations which results from the perturbation procedure is solved analytically up to second order. The effects of the compressibility parameter, the aspect ratio, and the Weissenberg number are discussed. In particular, it is demonstrated that compressibility has a significant effect on the transverse velocity and the first normal stress difference.     

Perturbation solutions of weakly compressible Newtonian Poiseuille flows with Navier slip at the wall

We consider both the planar and axisymmetric steady, laminar Poiseuille flows of a weakly compressible Newtonian fluid assuming that slip occurs along the wall following Navier’s slip equation and that the density obeys a linear equation of state. A perturbation analysis is performed in terms of the primary flow variables using the dimensionless isothermal compressibility as the perturbation parameter. Solutions up to the second order are derived and compared with available analytical results. The combined effects of slip, compressibility, and inertia are discussed with emphasis on the required pressure drop and the average Darcy friction factor.     

Laminar axisymmetric flow of a weakly compressible viscoelastic fluid

The combined effects of weak compressibility and viscoelasticity in steady, isothermal, laminar axisymmetric Poiseuille flow are investigated. Viscoelasticity is taken into account by employing the Oldroyd-B constitutive model. The fluid is assumed to be weakly compressible with a density that varies linearly with pressure. The flow problem is solved using a regular perturbation scheme in terms of the dimensionless isothermal compressibility parameter. The sequence of partial differential equations resulting from the perturbation procedure is solved analytically up to second order. The two-dimensional solution reveals the effects of compressibility and the other dimensionless numbers and parameters in the flow. Expressions for the average pressure drop, the volumetric flow rate, the total axial stress, as well as for the skin friction factor are also derived and discussed. The validity of other techniques used to obtain approximate solutions of weakly compressible flows is also discussed in conjunction with the present results.     

Numerical simulation of mold filling in foam reaction injection molding

A numerical simulation of reaction injection molding (RIM) of polymeric foam is developed, using a finite volume method (FVM). In this study we predict mold filling with a variable‐density fluid that fills a mold by self‐expansion. We deal with two‐dimensional, isothermal cases. With the assumptions of ideal mixing and rapid bubble nucleation, the foam is modelled as a continuum with a time‐dependent density. The continuum is assumed to be a Newtonian fluid. We develop a pressure‐based FVM for unstructured meshes that includes the SIMPLE algorithm with treatment of fluid compressibility. Cell‐based, co‐located storage is used for all physical variables. To treat the moving interface, an explicit high‐resolution interface capturing method is used. Foam flow in a slit is investigated, and the numerical calculations are in good agreement with an approximate analytic solution. For fountain flow in a rectangular cavity, the shape of the flow front is flatter and the traces of the particles are more complicated for an expanding foam than for a constant‐density fluid. An example of mold filling by an expanding foam demonstrates the geometric flexibility of the method. Copyright © 2003 John Wiley & Sons, Ltd.     

Effect of weak compressibility of a fluid on bubble-bubble interaction in strong acoustic fields

The effect of weak compressibility of a fluid on the interaction between spherical bubbles in a strong acoustic field is considered. A small parameter ɛ which represents the ratio of the characteristic velocity of radial oscillations of the bubbles to the speed of sound in the fluid is used as a parameter characterizing the fluid compressibility. The equations governing the interaction between two bubbles are derived with an accuracy O(ɛ) in the case in which the ratio of the characteristic velocities of their translational and radial motions is of the order of ɛ. It is shown that neglecting the fluid compressibility effect due to the bubble interaction can lead to either enhancement or attenuation of their radial oscillations following the main compression stage, variation in the oscillation frequency, the bubble approach velocity, and the velocity of the spatial motion of the coupled pair, and the bubble approach and collision rather than their moving away from one another with the formation of a coupled pair.     

STUDY ON THE DYNAMIC BEHAVIOR OF AXIALLY MOVING RECTANGULAR PLATES PARTIALLY SUBMERSED IN FLUID

The natural frequencies, complex modes and critical speeds of an axially moving rectangular plate, which is partially immersed in a fluid and subjected to a pretension, are investigated. The effects of free surface waves, compressibility and viscidity of the fluid are neglected in the analysis. The subsection functions are used to describe the discontinuous characteristics of the system due to partial immersion. The classical thin plate theory is adopted to formulate the equations of motion of a vibrating plate. The velocity potential and Bernoulli's equation are used to describe the fluid pressure acting on the moving plate. The effect of fluid on the vibrations of the plate may be equivalent to the added mass on the plate. The effects of distance ratio, moving speed, immersed-depth ratio, boundary conditions, stiffness ratio and aspect ratio of the plate as well as the fluid-plate density ratios on the free vibrations of the moving plate-fluid system are investigated.     

One-Dimensional Matrix-Fracture Transfer in Dual Porosity Systems with Variable Block Size Distribution

Most of the developed models for fractured reservoirs assume ideal matrix block size distribution. This assumption may not be valid in reality for naturally fractured reservoirs and possibly lead to errors in prediction of production from the naturally fractured reservoirs especially during a transient period or early time production from the matrix blocks. In this study, we investigate the effect of variable block size distribution on one- dimensional flow of compressible fluids in fractured reservoirs. The effect of different matrix block size distributions on the single phase matrix-fracture transfer is studied using a recently developed semi-analytical approach. The proposed model is able to simulate fluid exchange between matrix and fracture for continuous or discrete block size distributions using probability density functions or structural information of a fractured formation. The presented semi-analytical model demonstrates a good accuracy compared to the numerical results. There have been recent attempts to consider the effect of variable block size distribution in naturally fractured reservoir modeling for slightly compressible fluids with a constant viscosity and compressibility. The main objective of this study is to consider the effect of variable block size distribution on a one-dimensional matrix-fracture transfer function for single-phase flow of a compressible fluid in fractured porous media. In the proposed semi-analytical model, the pressure variability of viscosity and isothermal compressibility is considered by solving the nonlinear partial differential equation of compressible fluid flow in the fractured media. The closed form solution provided can be applied to flow of compressible fluids with variable matrix block size distribution in naturally fractured gas reservoirs.     

同轴气流式液体射流分裂液滴粒径研究

针对同轴气流式液体射流分裂液滴粒径预测模型缺乏的现状,结合射流线性稳定性理论,建立了基于临界模数的同轴气流式黏性液体射流分裂液滴粒径表达式,在此基础上,分别研究了气流旋拧(气流同时存在轴向和周向运动)及流体物性(气体可压缩性、液体黏性、气液密度比和表面张力)对液滴粒径的影响规律.研究发现:周围气流轴向引射作用和同轴旋转...