Linear and nonlinear instability in vertical counter-current laminar gas-liquid flows

TL;DR

This paper investigates the stability and dynamics of interfacial waves in vertical gas-liquid flows, combining linear stability analysis and numerical simulations to understand the onset and evolution of instabilities.

Contribution

It provides a comprehensive analysis of linear and nonlinear interfacial instabilities in counter-current laminar flows, highlighting the effects of flow parameters and density contrast.

Findings

Multiple unstable modes coexist at high density contrast.

Linear theory accurately predicts the onset of flow reversal.

Nonlinear simulations show chaotic wave behavior and overturning at high density contrast.

Abstract

We consider the genesis and dynamics of interfacial instability in gas-liquid flows, using as a model the two-dimensional channel flow of a thin falling film sheared by counter-current gas. The methodology is linear stability theory (Orr-Sommerfeld analysis) together with direct numerical simulation of the two-phase flow in the case of nonlinear disturbances. We investigate the influence of three main flow parameters (density contrast between liquid and gas, film thickness, pressure drop applied to drive the gas stream) on the interfacial dynamics. Energy budget analyses based on the Orr-Sommerfeld theory reveal various coexisting unstable modes (interfacial, shear, internal) in the case of high density contrasts, which results in mode coalescence and mode competition, but only one dynamically relevant unstable internal mode for low density contrast. The same linear stability approach provides a quantitative prediction for the onset of (partial) liquid flow reversal in terms of the gas and liquid flow rates. A study of absolute and convective instability for low density contrast shows that the system is absolutely unstable for all but two narrow regions of the investigated parameter space. Direct numerical simulations of the same system (low density contrast) show that linear theory holds up remarkably well upon the onset of large-amplitude waves as well as the existence of weakly nonlinear waves. In comparison, for high density contrasts corresponding more closely to an air-water-type system, although the linear stability theory is successful at determining the most-dominant features in the interfacial wave dynamics at early-to-intermediate times, the short waves selected by the linear theory undergo secondary instability and the wave train is no longer regular but rather exhibits chaotic dynamics and eventually, wave overturning.