# A volume of fluid framework for interface-resolved simulations of   vaporizing liquid-gas flows

**Authors:** John Palmore Jr, Olivier Desjardins

arXiv: 1906.04565 · 2023-07-21

## TL;DR

This paper presents a comprehensive computational framework for simulating vaporizing liquid-gas flows, accurately capturing interface dynamics and phase change processes using advanced numerical techniques.

## Contribution

It introduces a novel, divergence-free velocity extrapolation and sharp interface treatments within a volume of fluid framework for vaporization simulations.

## Key findings

- Framework achieves first-order convergence in accuracy.
- Successfully simulates unsteady droplet vaporization.
- Handles large density ratios and complex interface phenomena.

## Abstract

This work demonstrates a computational framework for simulating vaporizing, liquid-gas flows. It is developed for the general vaporization problem which solves the vaporization rate based as from the local thermodynamic equilibrium of the liquid-gas system. This includes the commonly studied vaporization regimes of film boiling and isothermal evaporation. The framework is built upon a Cartesian grid solver for low-Mach, turbulent flows which has been modified to handle multiphase flows with large density ratios. Interface transport is performed using an unsplit volume of fluid solver. A novel, divergence-free extrapolation technique is used to create a velocity field that is suitable for interface transport. Sharp treatments are used for the vapor mass fractions and temperature fields. The pressure Poisson equation is treated using the Ghost Fluid Method. Interface equilibrium at the interface is computed using the Clausius-Clapeyron relation, and is coupled to the flow solver using a monotone, unconditionally stable scheme.   It will be shown that correct prediction of the interface properties is fundamental to accurate simulations of the vaporization process. The convergence and accuracy of the proposed numerical framework is verified against solutions in one, two, and three dimensions. The simulations recover first order convergence under temporal and spatial refinement for the general vaporization problem. The work is concluded with a demonstration of unsteady vaporization of a droplet at intermediate Reynolds number.

## Full text

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## Figures

71 figures with captions in the complete paper: https://tomesphere.com/paper/1906.04565/full.md

## References

29 references — full list in the complete paper: https://tomesphere.com/paper/1906.04565/full.md

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Source: https://tomesphere.com/paper/1906.04565