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Main Authors: Saleem, Muhammad Saeed, Versluis, Michel, Lajoinie, Guillaume
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.17457
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author Saleem, Muhammad Saeed
Versluis, Michel
Lajoinie, Guillaume
author_facet Saleem, Muhammad Saeed
Versluis, Michel
Lajoinie, Guillaume
contents The study of vapor bubble growth following droplet vaporization in a superheated liquid involves research areas such as hydrodynamics, heat transfer, mass transfer, and thermodynamics. The interplay between these multiscale aspects is strongly dependent on the geometry, the thermodynamic response, and the local physical properties of the system. To understand the role of each aspect of this complex mechanism we model super-heated droplet vaporization by coupling the equation of motion for bubble growth with the thermodynamics of phase change and heat transfer through the convection-diffusion equation. The semi-analytical model is validated with the analytical description for vapor bubble growth dominated either by inertia (Rayleigh) or by thermal diffusion (Plesset-Zwick), depending on droplet radius and degree of superheat. The effect of a mismatch of the thermal properties between the host liquid and the droplet is shown to be relevant only for low superheating, above which an increase in thermal diffusivity leads to a reduction in the rate of vaporization. At medium to high superheating, the droplet vaporizes completely without relying on thermal diffusion. At the point of complete vaporization, the potential energy within the system drives the bubble overshoots, which vary based on the droplet size and degree of superheat.
format Preprint
id arxiv_https___arxiv_org_abs_2404_17457
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Vaporization dynamics of a super-heated water-in-oil droplet: modeling and numerical solution
Saleem, Muhammad Saeed
Versluis, Michel
Lajoinie, Guillaume
Fluid Dynamics
The study of vapor bubble growth following droplet vaporization in a superheated liquid involves research areas such as hydrodynamics, heat transfer, mass transfer, and thermodynamics. The interplay between these multiscale aspects is strongly dependent on the geometry, the thermodynamic response, and the local physical properties of the system. To understand the role of each aspect of this complex mechanism we model super-heated droplet vaporization by coupling the equation of motion for bubble growth with the thermodynamics of phase change and heat transfer through the convection-diffusion equation. The semi-analytical model is validated with the analytical description for vapor bubble growth dominated either by inertia (Rayleigh) or by thermal diffusion (Plesset-Zwick), depending on droplet radius and degree of superheat. The effect of a mismatch of the thermal properties between the host liquid and the droplet is shown to be relevant only for low superheating, above which an increase in thermal diffusivity leads to a reduction in the rate of vaporization. At medium to high superheating, the droplet vaporizes completely without relying on thermal diffusion. At the point of complete vaporization, the potential energy within the system drives the bubble overshoots, which vary based on the droplet size and degree of superheat.
title Vaporization dynamics of a super-heated water-in-oil droplet: modeling and numerical solution
topic Fluid Dynamics
url https://arxiv.org/abs/2404.17457