On the use of time-dependent fluids for delaying onset of transition to turbulence in the flat plate boundary-layer flow: A passive control of flow

IF 2.7 2区工程技术 Q2 MECHANICS

Journal of Non-Newtonian Fluid Mechanics Pub Date : 2024-01-04 DOI:10.1016/j.jnnfm.2023.105184

Danial Rezaee

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引用次数: 0

Abstract

Inelastic time-dependent fluids display continuous and reversible changes in viscosity when subjected to a constant shear-rate. These alterations arise from the gradual modification of the material’s microstructure due to shear-induced effects, known as shear rejuvenation. When this process generates smaller structural units, it is termed thixotropy; conversely, if it produces larger units, it is labeled anti-thixotropy. Aging is another characteristic of such fluids, denoting the capacity of the material to regain its original structure in the absence of shear, thus reversing the initial time-dependent change. This phenomenon often results from thermally activated Brownian motion prompting the reorganization of the material’s microconstituents. Consequently, attractive forces between these components can instigate the reconstruction of a network-like structure within the material. This study centers on investigating how variations in fluid microstructure impact the onset of transition to turbulence in a flat plate boundary-layer flow. Specifically, the focus is on cases where larger structural units emerge during the breakdown process (anti-thixotropy). To represent such fluids, the Quemada model, an inelastic structural-kinetic model, is employed. This model effectively captures thixotropy and anti-thixotropy by appropriately configuring model parameters. The analysis begins with obtaining a local similarity solution for the generalized Blasius equation, representing the base flow. Subsequently, the stability of this flow is assessed using linear temporal stability theory. This involves introducing infinitesimally-small normal-mode perturbations to the base flow, yielding the generalized Orr–Sommerfeld equation. Solving this equation using the spectral method provides insights into stability. Results from this study indicate that for low Deborah numbers, the shear-thickening behavior prevails, causing destabilization. In contrast, higher Deborah numbers lead to stability. This implies that anti-thixotropy effectively delays the onset of transition to turbulence and could hold practical applications for flow control.

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利用随时间变化的流体延迟平板边界层流动向湍流过渡的开始时间：流动的被动控制

无弹性随时间变化的流体在受到恒定剪切速率作用时，其粘度会发生持续且可逆的变化。这些变化源于剪切诱导效应对材料微观结构的逐渐改变，即剪切再生。当这一过程产生较小的结构单元时，称为触变；反之，如果产生较大的结构单元，则称为反触变。老化是此类流体的另一个特征，表示材料在没有剪切力的情况下恢复其原始结构的能力，从而逆转最初随时间而发生的变化。这种现象通常是由于热激活的布朗运动促使材料的微观成分重组所致。因此，这些成分之间的吸引力会促使材料内部重建网络状结构。本研究的重点是调查流体微观结构的变化如何影响平板边界层流动向湍流过渡的开始。具体来说，重点是在分解过程中出现较大结构单元的情况（反各向异性）。为了表示这类流体，采用了非弹性结构动力学模型 Quemada 模型。通过适当配置模型参数，该模型可有效捕捉触变性和反各向异性。分析首先要获得广义布拉修斯方程的局部相似解，该解代表基流。随后，利用线性时间稳定性理论对该流动的稳定性进行评估。这需要在基流中引入无限小的正态扰动，从而得到广义的奥尔-索默菲尔德方程。使用频谱法求解该方程可深入了解稳定性。研究结果表明，当德博拉数较低时，剪切增厚行为占主导地位，从而导致不稳定。相反，德博拉数越高，稳定性越好。这意味着反各向异性能有效推迟向湍流过渡的开始时间，并可实际应用于流动控制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Non-Newtonian Fluid Mechanics 物理-力学

CiteScore

5.00

自引率

19.40%

发文量

109

审稿时长

61 days

期刊介绍： The Journal of Non-Newtonian Fluid Mechanics publishes research on flowing soft matter systems. Submissions in all areas of flowing complex fluids are welcomed, including polymer melts and solutions, suspensions, colloids, surfactant solutions, biological fluids, gels, liquid crystals and granular materials. Flow problems relevant to microfluidics, lab-on-a-chip, nanofluidics, biological flows, geophysical flows, industrial processes and other applications are of interest. Subjects considered suitable for the journal include the following (not necessarily in order of importance): Theoretical, computational and experimental studies of naturally or technologically relevant flow problems where the non-Newtonian nature of the fluid is important in determining the character of the flow. We seek in particular studies that lend mechanistic insight into flow behavior in complex fluids or highlight flow phenomena unique to complex fluids. Examples include Instabilities, unsteady and turbulent or chaotic flow characteristics in non-Newtonian fluids, Multiphase flows involving complex fluids, Problems involving transport phenomena such as heat and mass transfer and mixing, to the extent that the non-Newtonian flow behavior is central to the transport phenomena, Novel flow situations that suggest the need for further theoretical study, Practical situations of flow that are in need of systematic theoretical and experimental research. Such issues and developments commonly arise, for example, in the polymer processing, petroleum, pharmaceutical, biomedical and consumer product industries.