可压缩横流失稳及其控制

边界层流动转捩的预测与控制一直是流体力学研究中的一个重要问题. 三维边界层流动工程中十分常见, 而横流失稳是导致三维边界层流动转捩的主要原因. 本文综述了近些年来三维边界层失稳和转捩方面的研究概况. 从机理上讨论了横流扰动的感受性、首次失稳、二次失稳和转捩控制等方面的研究进展. 在数值计算方面, 简要概述了线性稳定性理论、非线性稳定性理论和直接数值模拟方法在横流失稳和转捩方面的应用.本文对横流失稳研究当前存在的问题进行了讨论, 对今后研究的发展趋势作了相应展望.     

绕椭球的低速流动研究

理解和预测绕椭球的流动对指导飞行器和潜艇等交通工具的设计具有很强的工程意义. 近年来, 针对椭球绕流开展了大量的实验和数值模拟研究. 对有攻角下椭球绕流分离的定性描述和定量研究, 促进了对三维分离的辨识和拓扑研究. 文章对流场特性进行了分析, 介绍了分离对气动力、噪声、尾迹的影响, 以及实验条件对流动的影响. 上述定常流动与非定常机动过程之间存在明显差异, 非定常机动过程不能作为定常或准定常问题处理, 在机动过程中, 分离出现明显延迟, 气动力出现明显变化. 随后介绍了数值模拟在求解绕椭球流动中的进展, 当前求解雷诺平均的N-S方程湍流模式仍然是解决绕椭球大范围分离流动的主要工程方法, 大涡模拟和分离涡模拟等也逐渐得到了广泛应用. 受限于计算能力, 直接数据模拟只能用于较低雷诺数, 在高雷诺数流动中还不适用. 非定常机动过程的数值模拟较定常状态, 与实验结果的差距要大一些. 最后, 介绍了对椭球绕流场转捩的研究进展, 对T-S转捩与横流转捩的机理和辨识已经较为准确, 数值模拟结果与实验结果基本相符, 但对再附转捩的认识还不够清晰, 尤其是迎风面, 因此椭球绕流转捩的研究还需要依靠实验.      

壁流动中的转捩

对壁流动的不同实验结果做了对比,这些实验结果来自于流动显示、热膜测量以及PIV测量, 对比的同时,还总结了与此相应的理论方面的进展.这些进展是在对所选大约120篇文献中内容归纳提炼的基础上给出的.尽管实验中所使用的初始扰动条件不同,但所发现的流动结构几乎是完全一样的. 在对壁流动转捩的认识方面,认为下列所观察到的流动结构是最基本最重要的:在边界层和管流中被称为类孤子相干结构(SCS)的三维非线性涡包、$\Lambda$涡、二次涡环和涡环链.近期的实验中发现了这些结构形成和转捩的动力学过程,具体包括以下内容: (1) $\Lambda$ 涡和二次涡环间持续的相互作用过程.该过程决定了涡环链的产生方式, 总是从壁面区域周期性地形成,并进入到边界层的外部区域; (2)高频涡的生成,这是理解转捩和湍流边界层(以及其他流动)发展的关键问题之一.尽管已经提出了一些解释,但是二次涡环的实验发现将对此提供一个特别清晰的解释.(3)在所有湍流猝发中SCS所起的关键作用.这一点被看做是低雷诺数湍流边界层中湍流产生的关键机制.与猝发直接相关联的是低速条带. 基于SCS的动力学过程, 针对壁流动情况,可以比以前更清晰地解释低速条带的形成机制及其与流动结构的关系.在实验中所观察到的SCS和二次涡环,不仅能使我们重温壁面流动转捩中的经典故事, 同时还开辟一条新的途径,可以基于此建立壁面流动转捩可能具有的普适性的动力学过程.      

高超声速高焓边界层稳定性与转捩研究进展

边界层由层流向湍流的转捩是高超声速飞行器设计面临的重大空气动力学问题. 随着飞行速域与空域的不断拓展, 高超声速高焓边界层中的高温气体效应会使得量热完全气体假设失效, 从而深刻影响流动转捩过程. 相关研究涉及多个学科, 是典型的多物理场耦合问题. 近年来, 随着相关飞行器技术的快速发展, 高超声速高焓边界层转捩问题的重要性越来越得到体现, 相关研究已成为国际上的热点领域. 本文综述相关研究进展, 首先介绍目前常用的高温气体物理模型, 尤其关注热化学非平衡模型, 并介绍激波捕捉、激波装配和边界层方程解等常用的高焓流动求解方法, 以及相关风洞和飞行试验技术的进展. 然后综述高温气体效应对转捩过程中的感受性、模态增长、瞬态增长和非线性作用等的影响的相关研究, 其中流向不稳定性中出现较大增长率的第三模态和超声速模态引起了广泛的研究兴趣. 最后进行总结, 并对未来发展略作展望.      

生理流动与医学听诊

本文介绍人体中的生理流动即主要是循环系统和呼吸系统中，流体运动的层流和湍流状态，转捩条件及转捩现象．讨论了医学听诊的机理以及生理流动的致声效应在医学听诊中的重要意义．     

基于NPLS技术的可压缩湍流机理实验研究新进展

可压缩湍流机理的实验研究是一件难度很大的工作, 其主要的难度在于高时空分辨率的可压缩湍流结构非接触精细测试技术和低噪声的高速风洞设备技术. 近几年来, 由于在低噪声的超声速、高超声速风洞研究和可压缩流动精细结构测量技术研究方面取得的重要进展及其在可压缩湍流机理研究方面的应用, 超声速流动转捩与湍流的机理研究取得了较大的进展. 本文介绍了最近几年高速流动非接触精细测试技术, 尤其是基于纳米粒子的平面激光散射技术(nano-tracer planar laser scattering, NPLS)、背景导向纹影技术(background oriented schlieren, BOS) 和超声速流场的粒子图像测速技术(particle image velocimetry, PIV)的研究进展和发展前景, 以及基于这些技术, 在可压缩湍流机理实验研究方面的进展和发展前景, 其中包括在超声速混合层转捩、超声速绕流与尾流结构、超声速边界层转捩、激波边界层干扰等典型流场的机理研究方面, 以及气动光学机理研究方面的研究进展. 最后, 展望了目前湍流机理实验研究对湍流工程模型研究的可能贡献.      

离心叶轮机械内部流动的研究进展

随着测量技术及数值算法的不断进步,叶轮机械内部流动研究有了很多新的进展.本文就半个世纪以来离心叶轮机械内部流动的实验及数值模拟研究进行了评述,根据作者掌握的文献,着重在以下几方面展开综述:叶轮内部流动、叶顶间隙泄漏流动、扩压器内部流动及叶轮与扩压器相互作用的非稳态流动等等.文中分别阐述了国内外学者在上述流动研究方面的主要成果,指出了这些研究的特点及其不足,分析了我国在这些领域与国际水平的差距,并结合作者自己的研究工作对离心叶轮机械内流研究提出了建议.      

可压缩自由剪切流混合转捩大涡模拟

针对湍流气动光学效应与冲压发动机气体混合机理问题,开展了可压缩混合层流动空间模式大涡模拟和时间模式直接数值模拟研究.通过对流场(包含亚/亚混合、超/亚混合两种情况)失稳、转捩直至完全湍流的空间发展过程的研究表明,对流Mach数0.4状态下流场失稳以二维最不稳定扰动为主;非线性发展中,基频涡对并及展向涡撕裂主控流动转捩,流场发生混合转捩;转捩后脉动流场基本达到局部各向同性,此时,湍流Mach数低于0.3,流动压缩性可近似忽略.     

低压涡轮内部流动及其气动设计研究进展

随着高空无人飞行器研究的不断升温, 高空低雷诺数条件下动力装置的研究越来越受到人们的重视.结合近年来国内外相关领域的研究工作, 对低雷诺数低压涡轮内部复杂流动机理的研究进展进行了介绍, 包括低雷诺数情况下低压涡轮内部非定常流动的特点, 叶片边界层分离及转捩现象机理, 上游周期性尾迹与下游叶片边界层相互作用机理等. 在此基础上给出了适合低雷诺数条件的低压涡轮气动设计方法:尾迹通过与边界层的相互作用, 能够抑制分离, 进而减小叶型损失, 在气动设计中有效引入非定常效应可以大幅度提高低压涡轮的气动负荷或降低气动损失, 最终达到提高性能的目的;数值及实验结果验证了这种设计方法的有效性.      

分离流动数值模拟的几个问题

介绍了分离流动现象.给出了三维定常粘性流动分离识别准则,研究了分离流动的性态.给出了应用于分离流动的六种模型及有关的控制方程.讨论了求解NS方程的数值方法和数值模拟的前景.特别研究了应用于分离流动的Eulcr方程的数值模拟问题.      

多孔介质壁面剪切湍流速度时空关联的研究

作为一个基础统计量,时空关联函数在湍流问题的研究中有着广泛的应用,是研究湍流噪声、湍流中物质扩散和大涡模拟亚格子模型等问题的重要参考.本文通过建立三维多孔结构壁面剪切湍流模型,采用含Darcy-Brinkman-Forchheimer作用力项的格子Boltzmann方程对无穷大多孔介质平行板之间壁湍流进行了数值模拟,进而研究其速度脉动时空关联函数的统计特性.一方面,根据计算得到的流场数据,对比分析了常规槽道湍流与多孔介质壁面槽道湍流的时间关联函数.另一方面,计算并讨论了不同孔隙率和渗透率的多孔介质壁面对速度脉动时空关联性的影响.通过研究表明:多孔结构壁面剪切湍流的时空关联函数等值线与椭圆理论相符;在研究参数范围内,多孔介质壁面的速度时空关联系数随着孔隙率增大而增大,随着渗透率增大而减小.同时发现在槽道壁面的近壁区、过渡区、对数律区和中心区等不同位置处,速度时空关联呈现较大差异性:越远离壁面位置(对数律区和中心区),其时空关联函数所呈现的关联等值线椭圆越细长,高值相关等值线越集中.多孔介质主要改变速度时空关联椭圆图像的椭圆率,说明多孔介质壁面主要影响湍流横扫速度.     

A Dissipation Rate Equation for Low-Reynolds-Number and Near-Wall Turbulence

Two-equation turbulence models are usually formulated for specific flow types and are seldom validated against a variety of flows to account for near-wall and low-Reynolds-number effects simultaneously. In addition to low-Reynolds-number effects, near-wall flows also experience wall blocking, which is absent in free flows. Consequently, near-wall modifications to two-equation models could be quite different from low-Reynolds-number corrections. Besides, it is known that existing two-equation models perform poorly when used to calculate plane wall jets and two-dimensional backstep flows. These problems could be traced to the modeling of the dissipation rate equation. In this paper an attempt is made to improve the modeling of the dissipation rate equation so that it could successfully predict both free and wall-bounded shear flows including plane wall jets and backstep flows. The predictions are compared with experimental and direct numerical simulation data whenever available. Most of the data used are obtained at low Reynolds numbers. Good correlation with data is obtained. Therefore, for the first time, a model capable of correctly predicting free and wall-bounded shear flows, backstep flows, and plane wall jets is available. Received: 12 December 1995 and accepted 12 November 1996     

Experimental validation of a two equation RANS transitional turbulence model for compressible microflows

Laminar-to-turbulent flow transition in microchannels can be useful to enhance mixing and heat transfer in microsystems. Typically, the small characteristic dimensions of these devices hinder in attaining higher Reynolds numbers to limit the total pressure drop. This is true especially in the presence of a liquid as a working medium. On the contrary, due to lower density, Reynolds number larger than 2000 can be easily reached for gas microflows with an acceptable pressure drop. Since microchannels are used as elementary building blocks of micro heat exchangers and micro heat-sinks, it is essential to predict under which conditions, the laminar-to-turbulent flow transition inside such geometries can be expected. In this paper, experimental validation of a two equations transitional turbulence model, capable of predicting the laminar-to-turbulent flow transition for internal flows as proposed by Abraham etal. (2008), is presented for the first time for microchannels. This is done by employing microchannels in which Nitrogen gas is used as a working fluid. Two different cross-sections namely circular and rectangular are utilized for numerical and experimental investigations. The inlet mass flow rate of the gas is varied to cover all the flow regimes from laminar to fully turbulent flow. Pressure loss experiments are performed for both cross-sectional geometries and friction factor results from experiments and numerical simulations are compared. From the analysis of the friction factor as a function of the Reynolds number, the critical value of the Reynolds number linked to the laminar-to-turbulent transition has been determined. The experimental and numerical critical Reynolds number for all the tested microchannels showed a maximum deviation of less than 12%. These results demonstrate that the transitional turbulence model proposed by Abraham etal. (2008) for internal flows can be extended to microchannels and proficiently employed for the design of micro heat exchangers in presence of gas flows.     

The Relaminarization Mechanisms of Turbulent Channel Flow at Low Reynolds Numbers

The mechanisms of laminarization in wall-bounded flows have been investigated by performing direct numerical simulations (DNS) of turbulent channel flows. By decreasing Reynolds numbers systematically, the effects of the low Reynolds number are studied in connection with the near-wall turbulent structure and turbulent statistics. At approximately the critical Reynolds number, the turbulent skin friction is reduced, and the turbulent structure changes qualitatively in the very near-wall region. Instantaneous turbulent structures reveal that streamwise vortices, the cores of which are at y+ 10, disappear, although low speed streaks and Reynolds shear stress are still produced by larger streamwise vortices located in the buffer region y+ > 10. Sweep motions induced by these vortical structures are shifted toward the center of a channel and also significantly deterred, which may heighten the effects of the viscous sublayer over most of the channel section and suppress the regeneration mechanisms of new streamwise vortices in the very near-wall region. To investigate the details of how large-scale coherent vortices affect the viscous sublayer and the relevant small-scale streamwise vortices, a body force is virtually imposed in the wall-normal direction to enhance the large streamwise vortices. As a result, it is found that when they are sufficiently enhanced, the small-scale vortices reappear, and the sweep events are again dominant in the viscous sublayer.     

Study of the Spectral Difference Numerical Dissipation for Turbulent Flows Using Unstructured Grids

In this paper, the numerical dissipation properties of the Spectral Difference (SD) method are studied in the context of vortex dominated flows and wall-bounded turbulence, using uniform and distorted grids. First, the validity of using the SD numerical dissipation as the only source of subgrid dissipation (the so-called Implicit-LES approach) is assessed on regular grids using various polynomial degrees (namely, p = 3, p = 4, p = 5) for the Taylor-Green vortex flow configuration at R e = 5 000. It is shown that the levels of numerical dissipation greatly depend on the order of accuracy chosen and, in turn, lead to an incorrect estimation of the viscous dissipation levels. The influence of grid distortion on the numerical dissipation is then assessed in the context of finite Reynolds number freely-decaying and wall-bounded turbulence. Tests involving different amplitudes of distortion show that highly skewed grids lead to the presence of small-scale, noisy structures, emphasizing the need of explicit subgrid modeling or regularization procedures when considering coarse, high-order SD computations on unstructured grids. Under-resolved, high-order computations of the turbulent channel flow at R e _τ = 1000 using highly-skewed grids are considered as well and present a qualitatively similar agreement to results obtained on a regular grid.     

Spots and turbulent domains in a model of transitional plane Couette flow

A review of the globally subcritical transition to turbulence in shear flows is presented, with an emphasis on the cases of plane and circular Couette flows (pCf and cCf, respectively). A Swift–Hohenberg-like model is next proposed to interpret the behavior of plane Couette flow in the vicinity of its global stability threshold. We present results of numerical simulations supporting this proposal and helping us to raise good questions about the growth and decay of intermittent turbulent domains in this precise context, and more generally about the coexistence of laminar flow and turbulence in other spatio-temporally intermittent flows. PACS 47.27.-i, 47.54.-r, 05.45.-a     

Assessment of the validity of a log-law for wall-bounded turbulent bubbly flows

There has been considerable discussion in recent years concerning whether a log-law exists for wall-bounded, turbulent bubbly flows. Previous studies have argued for the existence of such a log-law, with a modified von Kármán constant, and this is used in various modelling studies. We provide a critique of this idea, and present several theoretical reasons why a log-law need not be expected in general for wall-bounded, turbulent bubbly flows. We then demonstrate using recent data from interface-resolving Direct Numerical Simulations that when the bubbles make a significant contribution to the channel flow dynamics, the mean flow profile of the fluid can deviate significantly from the log-law behaviour that approximately holds for the single-phase case. The departures are not surprising and the basic reason for them is simple, namely that for bubbly flows, the mean flow is affected by a number of additional dynamical parameters, such as the void fraction, that do not play a role for the single-phase case. As a result, the inner/outer asymptotic regimes that form the basis of the derivation of the log-law for single-phase flow do not exist in general for bubbly turbulent flows. Nevertheless, we do find that for some cases, the bubbles do not cause significant departures from the unladen log-law behaviour. Moreover, we show that if departures occur these cannot be understood simply in terms of the averaged void fraction, but that more subtle effects such as the bubble Reynolds number and the competition between the wall-induced turbulence and the bubble-induced turbulence must play a role.     

BY-PASS MECHANISM OF TRANSITION TO TURBULENCE

The by-pass mechanism of transition for a wall-bounded shear layer is explained for the case when an infinite row of convecting vortices migrate over a boundary layer at a specific speed range. Such a mechanism is important for noisy flows over bluff bodies, flows inside turbomachinery and flows over helicopter rotor blades. By solving the Navier–Stokes equation, it is shown that this by-pass transition is a consequence of vortices migrating at convection speeds that are significantly lower than the free-stream speed. This situation is commonly found in flows that are affected by the presence of periodic wakes. Whenever the speed of migrating vortices is in a certain critical range, there is a local instability of the underlying shear layer with a very high-growth rate as compared to the growth of pure Tollmien–Schlichting waves created by wall excitation. The above interpretation is supported by solving the linearized and full Navier–Stokes equation for disturbance quantities under the parallel flow approximation in two dimensions. Various ramifications of such a by-pass route of transition are discussed in this paper.