Numerical study of droplet deformation in shear flow using a conservative level-set method

•The physics of droplet in shear is accurately captured.•Mass of the droplet is fully conserved.•The vorticity magnitude inside of the droplet decreases as viscosity ratio increases.•Highly confined droplet exposed to shear flow exhibits fluctuations in deformation.•Two critical viscosity ratios exi...

Full description

Saved in:
Bibliographic Details
Published in:Chemical engineering science 2019-11, Vol.207, p.153-171
Main Authors: Amani, Ahmad, Balcázar, Néstor, Castro, Jesús, Oliva, Assensi
Format: Article
Language:English
Subjects:
Conservative Level-set method
Corbes de nivell, Mètodes de
Critical confinement ratio
Dinàmica de fluids
Droplet deformation and breakup
Emulsification
Emulsions
Enginyeria mecànica
Fluid dynamics
Level set methods
Mecànica de fluids
Shear flow
Simple shear flow
Viscosity ratio
Àrees temàtiques de la UPC
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•The physics of droplet in shear is accurately captured.•Mass of the droplet is fully conserved.•The vorticity magnitude inside of the droplet decreases as viscosity ratio increases.•Highly confined droplet exposed to shear flow exhibits fluctuations in deformation.•Two critical viscosity ratios exists for each confinement ratio. This paper is concerned with a numerical study on the behavior of a single Newtonian droplet suspended in another Newtonian fluid, all subjected to a simple shear flow. Conservative finite-volume approximation on a collocated three-dimensional grid along with a conservative Level-set method are used to solve the governing equations. Four parameters of capillary number (Ca), Viscosity ratio (λ), Reynolds number (Re) and walls confinement ratio are used to physically define the problem. The main focus of the current study is to investigate the effect of viscosity on walls critical confinement ratio. In this paper, the phrase critical is used to specify a state of governing parameters in which divides the parameter space into the subcritical and supercritical regions where droplets attain a steady shape or breakup, respectively. To do so, first, we validate the ability of proposed method on capturing the physics of droplet deformation including: steady-state subcritical deformation of non-confined droplet, breakup of supercritical conditioned droplet, steady-state deformation of moderate confined droplet, subcritical oscillation of highly-confined droplet, and the effect of viscosity ratio on deformation of the droplet. The extracted results are compared with available experimental, analytical and numerical data from the literature. Afterward, for a constant capillary number of 0.3 and a low Reynolds number of 1.0, subcritical (steady-state) and supercritical (breakup) deformations of the droplet for a wide range of walls confinement in different viscosity ratios are studied. The results indicate the existence of two steady-state regions in a viscosity ratio-walls confinement ratio graph which are separated by a breakup region.
ISSN:0009-2509
1873-4405
DOI:10.1016/j.ces.2019.06.014