Mathematical and Computational Applications (Mar 2023)

A Generalized Finite Difference Scheme for Multiphase Flow

  • Johannes C. Joubert,
  • Daniel N. Wilke,
  • Patrick Pizette

DOI
https://doi.org/10.3390/mca28020051
Journal volume & issue
Vol. 28, no. 2
p. 51

Abstract

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This paper presents a GPU-based, incompressible, multiphase generalized finite difference solver for simulating multiphase flow. The method includes a dampening scheme that allows for large density ratio cases to be simulated. Two verification studies are performed by simulating the relaxation of a square droplet surrounded by a light fluid and a bubble rising in a denser fluid. The scheme is also used to simulate the collision of binary droplets at moderate Reynolds numbers (250–550). The effects of the surface tension and density ratio are explored in this work by considering cases with Weber numbers of 8 and 180 and density ratios of 2:1 and 1000:1. The robustness of the multiphase scheme is highlighted when resolving thin fluid structures arising in both high and low density ratio cases at We = 180.

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