A Vaporization Model for Continuous Surface Force Approaches and Subcooled Configurations

IF 1.8 Q3 MECHANICS Fluids Pub Date : 2023-08-19 DOI:10.3390/fluids8080233

Charles Brissot, Léa Cailly-Brandstäter, Elie Hachem, Rudy Valette

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Abstract

The integration of phase change phenomena through an interface is a numerical challenge that requires proper attention. Solutions to properly ensure mass and energy conservation were developed for finite difference and finite volume methods, but not for Finite Element methods. We propose a Finite Element phase change model based on an Eulerian framework with a Continuous Surface Force (CSF) approach. It handles both momentum and energy conservation at the interface for anisotropic meshes in a light an efficient way. To do so, a model based on the Level Set method is developed. A thick interface is considered to fit with the CSF approach. To properly compute the energy conservation, heat fluxes are extended through this interface thanks to the resolution of a transport equation. A dedicated pseudo compressible Navier–Stokes solver is added to compute velocity jumps with a source term at the interface in the velocity divergence equation. Several 1D and 2D benchmarks are considered with increasing complexity to highlight the performances of each feature of the framework. This stresses the capacity of the model to properly tackle phase change problems.

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连续表面力方法和过冷结构的汽化模型

相变现象通过界面的积分是一个数值难题，需要引起适当的重视。为有限差分法和有限体积法制定了适当保证质量和能量守恒的解决方案，但没有为有限元法制定。我们提出了一个基于欧拉框架的有限元相变模型与连续表面力(CSF)方法。它以一种简单有效的方式处理各向异性网格界面上的动量和能量守恒。为此，建立了一个基于水平集方法的模型。厚的界面被认为适合CSF入路。为了正确地计算能量守恒，通过对输运方程的解析，将热通量通过该界面进行扩展。增加了专用的伪可压缩Navier-Stokes解算器，用于计算速度散度方程中在界面处带源项的速度跳变。几个1D和2D基准被认为是越来越复杂的，以突出框架的每个特征的性能。这强调了模型正确处理相变问题的能力。

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