Difference between revisions of "The stationary droplet by Lionel Gamet"
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=[https://github.com/jnmlujnmlu/OpenFOAMTeaching/tree/master/LionelGamet The stationary droplet]= | =[https://github.com/jnmlujnmlu/OpenFOAMTeaching/tree/master/LionelGamet The stationary droplet]= | ||
− | + | The starting cases case can be downloaded here: | |
− | + | * [https://github.com/jnmlujnmlu/OpenFOAMTeaching/blob/master/LionelGamet/2D.tar 2D case]. | |
+ | * [https://github.com/jnmlujnmlu/OpenFOAMTeaching/blob/master/LionelGamet/2D_uns.tar Unsteady 2D case]. | ||
+ | * [https://github.com/jnmlujnmlu/OpenFOAMTeaching/blob/master/LionelGamet/3D.tar 3D case]. | ||
+ | * [https://github.com/jnmlujnmlu/OpenFOAMTeaching/blob/master/LionelGamet/3D_uns.tar Unsteady 3D case]. | ||
− | + | Reference OpenFOAM results of the stationary droplet can be found [https://github.com/jnmlujnmlu/OpenFOAMTeaching/blob/master/LionelGamet/StationaryDroplet_Results.tar.gz here]. | |
==Introduction== | ==Introduction== | ||
+ | |||
+ | This case is a reference test case for Volume-of-Fluid (VoF) simulations. This benchmark configuration allows for quantitative measurements of the spurious currents appearing in VoF simulations. The case consists in a single static droplet in a quiescent liquid under zero gravity. It is a widely used test case in the literature, described by Popinet [1]. More details can be found in the iterature [1,2,3,4,5] and in the article in press of Gamet et al. [6]. | ||
+ | |||
+ | [[File:StDrop2D_scheme.png|540px|right|Configuration and boundary conditions for 2D static droplet case under zero gravity.] | ||
==References== | ==References== |
Revision as of 05:14, 17 September 2020
- contributor: Lionel Gamet
- affiliation: IFP Energies nouvelles, France
- contact: click here for email address
- OpenFOAM version: v2006
- Published under: CC BY-NC-SA license (creative commons licenses)
Go back to Multiphase modeling.
The stationary droplet
The starting cases case can be downloaded here:
Reference OpenFOAM results of the stationary droplet can be found here.
Introduction
This case is a reference test case for Volume-of-Fluid (VoF) simulations. This benchmark configuration allows for quantitative measurements of the spurious currents appearing in VoF simulations. The case consists in a single static droplet in a quiescent liquid under zero gravity. It is a widely used test case in the literature, described by Popinet [1]. More details can be found in the iterature [1,2,3,4,5] and in the article in press of Gamet et al. [6].
[[File:StDrop2D_scheme.png|540px|right|Configuration and boundary conditions for 2D static droplet case under zero gravity.]
References
[1] S. Popinet: An accurate adaptive solver for surface-tension-driven interfacial flows," Journal of Computational Physics, vol. 228, no. 16, pp. 5838-5866, 2009.
[2] M. M. Francois, S. J. Cummins, E. D. Dendy, D. B. Kothe, J. M. Sicilian, and M. W. Williams: A balanced-force algorithm for continuous and sharp interfacial surface tension models within a volume tracking framework," Journal of Computational Physics, vol. 213, no. 1, pp. 141-173, 2006.
[3] S. Popinet: A quadtree-adaptive multigrid solver for the serre-green-naghdi equations," Journal of Computational Physics, vol. 302, pp. 336-358, 2015.
[4] --: Numerical models of surface tension," Annual Review of Fluid Mechanics, vol. 50, pp. 49-75, 2018.
[5] T. Abadie, J. Aubin, and D. Legendre: On the combined effects of surface tension force calculation and interface advection on spurious currents within volume of fluid and level set frameworks," Journal of Computational Physics, vol. 297, pp. 611-636, 2015.
[6] L. Gamet, M. Scala, J. Roenby, H. Scheufler, and J.-L. Pierson: Validation of volume-of-Fluid OpenFOAM isoAdvector solvers using single bubble benchmarks," Submitted to Computers and Fluids, 2020.
[7] H. Scheufler and J. Roenby: Accurate and effcient surface reconstruction from volume fraction data on general meshes," J. Comp. Phys., vol. 383, pp. 1 - 23, 2019.