Gravity-driven fingering simulations for a thin liquid film flowing down the outside of a vertical cylinder


Autoria(s): Mayo, Lisa C.; McCue, Scott W.; Moroney, Timothy J.
Data(s)

2013

Resumo

A numerical study is presented to examine the fingering instability of a gravity-driven thin liquid film flowing down the outer wall of a vertical cylinder. The lubrication approximation is employed to derive an evolution equation for the height of the film, which is dependent on a single parameter, the dimensionless cylinder radius. This equation is identified as a special case of that which describes thin film flow down an inclined plane. Fully three-dimensional simulations of the film depict a fingering pattern at the advancing contact line. We find the number of fingers observed in our simulations to be in excellent agreement with experimental observations and a linear stability analysis reported recently by Smolka & SeGall (Phys Fluids 23, 092103 (2011)). As the radius of the cylinder decreases, the modes of perturbation have an increased growth rate, thus increasing cylinder curvature partially acts to encourage the contact line instability. In direct competition with this behaviour, a decrease in cylinder radius means that fewer fingers are able to form around the circumference of the cylinder. Indeed, for a sufficiently small radius, a transition is observed, at which point the contact line is stable to transverse perturbations of all wavenumbers. In this regime, free surface instabilities lead to the development of wave patterns in the axial direction, and the flow features become perfectly analogous to the two-dimensional flow of a thin film down an inverted plane as studied by Lin & Kondic (Phys Fluids 22, 052105 (2010)). Finally, we simulate the flow of a single drop down the outside of the cylinder. Our results show that for drops with low volume, the cylinder curvature has the effect of increasing drop speed and hence promoting the phenomenon of pearling. On the other hand, drops with much larger volume evolve to form single long rivulets with a similar shape to a finger formed in the aforementioned simulations.

Formato

application/pdf

Identificador

http://eprints.qut.edu.au/59839/

Publicador

American Physical Society

Relação

http://eprints.qut.edu.au/59839/1/MayoMcCueMoroney.pdf

DOI:10.1103/PhysRevE.87.053018

Mayo, Lisa C., McCue, Scott W., & Moroney, Timothy J. (2013) Gravity-driven fingering simulations for a thin liquid film flowing down the outside of a vertical cylinder. Physical Review E (Statistical, Nonlinear, and Soft Matter Physics), 87(5), pp. 1-16.

Direitos

Copyright 2013 American Physical Society

Fonte

Institute for Future Environments; School of Mathematical Sciences; Science & Engineering Faculty

Palavras-Chave #010207 Theoretical and Applied Mechanics #020303 Fluid Physics #thin film flow #contact line instability #viscous fingering #pattern formation #drops #pearling #numerical simulation #ADI method #travelling wave #linear stability #rivulets
Tipo

Journal Article