Stability of fluid flow past a membrane

V. Kumaran, L. Srivatsan
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引用次数: 15

Abstract

Abstract:The stability of the flow of a fluid past a solid membrane of infinitesimal thickness is investigated using a linear stability analysis. The system consists of two fluids of thicknesses R and H R and bounded by rigid walls moving with velocities Va and Vb, and separated by a membrane of infinitesimal thickness which is flat in the unperturbed state. The fluids are described by the Navier-Stokes equations, while the constitutive equation for the membrane incorporates the surface tension, and the effect of curvature elasticity is also examined for a membrane with no surface tension. The stability of the system depends on the dimensionless strain rates Λa and Λb in the two fluids, which are defined as (Vaη/Γ) and (‒Vbη/ΓH) for a membrane with surface tension Γ, and (VaR2η/K) and (VbR2η/KH) for a membrane with zero surface tension and curvature elasticity K. In the absence of fluid inertia, the perturbations are always stable. In the limit k → 0, the decay rate of the perturbations is O(k3) smaller than the frequency of the fluctuations. The effect of fluid inertia in this limit is incorporated using a small wave number k ≪ 1 asymptotic analysis, and it is found that there is a correction of O(kRe) smaller than the leading order frequency due to inertial effects. This correction causes long wave fluctuations to be unstable for certain values of the ratio of strain rates Λr =(Λb/Λa) and ratio of thicknesses H. The stability of the system at finite Reynolds number was calculated using numerical techniques for the case where the strain rate in one of the fluids is zero. The stability depends on the Reynolds number for the fluid with the non-zero strain rate, and the parameter Σ = (ρΓR/η2), where Γ is the surface tension of the membrane. It is found that the Reynolds number for the transition from stable to unstable modes, Ret, first increases with Σ, undergoes a turning point and a further increase in the Ret results in a decrease in Σ. This indicates that there are unstable perturbations only in a finite domain in the Σ ‒ Ret plane, and perturbations are always stable outside this domain.
流体流过膜的稳定性
摘要:利用线性稳定性分析方法研究了流体通过无限小厚度固体膜时的稳定性。该系统由厚度为R和hr的两种流体组成,以速度为Va和Vb的刚性壁为界,由一层厚度无穷小的膜隔开,该膜在无摄动状态下是平坦的。流体由Navier-Stokes方程描述,而膜的本构方程包含了表面张力,并研究了曲率弹性对无表面张力膜的影响。系统的稳定性取决于两种流体中的无量纲应变率Λa和Λb,对于表面张力为Γ的膜,定义为(Vaη/Γ)和(-Vbη /ΓH),对于零表面张力和曲率弹性K的膜,定义为(VaR2η/K)和(VbR2η/KH)。在没有流体惯性的情况下,扰动始终稳定。在极限k→0时,扰动的衰减率小于波动的频率O(k3)。利用小波数k≪1渐近分析将流体惯量的影响纳入这一极限,发现由于惯性效应,存在小于主阶频率的修正量O(kRe)。这种修正导致长波波动在应变率之比Λr =(Λb/Λa)和厚度之比h的某些值下是不稳定的。对于其中一种流体的应变率为零的情况,使用数值技术计算了系统在有限雷诺数下的稳定性。稳定性取决于非零应变速率流体的雷诺数和参数Σ = (ρΓR/η2),其中Γ为膜的表面张力。研究发现,从稳定模式向不稳定模式转变的雷诺数Ret首先随着Σ的增加而增加,然后经历一个转折点,Ret的进一步增加导致Σ的减小。这表明在Σ - Ret平面的有限域内存在不稳定扰动,而在该域外扰动总是稳定的。
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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