On the liquid film instability of an internally coated horizontal tube

TL;DR

This study investigates the stability of a viscous liquid film inside a horizontal tube, showing how surface tension and inertia influence the suppression of instabilities, with implications for predicting flow behavior.

Contribution

It provides a combined numerical and theoretical analysis of liquid film stability in a horizontal tube, highlighting the stabilizing effects of capillary forces at certain Bond numbers.

Findings

Large Bond numbers suppress Rayleigh-Plateau instability.

Transient growth does not significantly amplify initial perturbations.

Theoretical predictions align with experimental stabilization thresholds.

Abstract

We study numerically and theoretically the gravity-driven flow of a viscous liquid film coating the inner side of a horizontal cylindrical tube and surrounding a shear-free dynamically inert gaseous core. The liquid-gas interface is prone to the Rayleigh-Plateau and Rayleigh-Taylor instabilities. Here, we focus on the limit of low and intermediate Bond numbers, Bo, where the capillary and gravitational forces are comparable and the Rayleigh-Taylor instability is known to be suppressed. We first study the evolution of the axially invariant draining flow, initiating from a uniform film thickness until reaching a quasi-static regime as the bubble approaches the upper tube wall. We then investigate the flow linear stability within two frameworks: frozen time-frame (quasi-steady) stability analysis and transient growth analysis. We explore the effect of the surface tension (Bo) and inertia (measured by the Ohnesorge number, Oh) on the flow and its stability. The linear stability analysis suggests that the interface deformation at large Bo results in the suppression of the Rayleigh-Plateau instability in the asymptotic long-time limit. Furthermore, the transient growth analysis suggests that the initial flow evolution does not lead to any considerable additional amplification of initial interface perturbations, a posteriori rationalising the quasi-steady assumption. The present study yields a satisfactory prediction of the stabilisation threshold found experimentally by Duclaux et al. [15].