Difference between revisions of "Collection of turbulence modeling"
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* [https://wiki.openfoam.com/The_DrivAer_case_by_Gavin_Tabor '''Flow around a car'''] - Here you will learn about the flow around a car. | * [https://wiki.openfoam.com/The_DrivAer_case_by_Gavin_Tabor '''Flow around a car'''] - Here you will learn about the flow around a car. |
Revision as of 12:45, 12 February 2019
Turbulence modeling is in several cases a very important topic in a simulation project. These tutorials explain, how you can utilize them in OpenFOAM.
Go back to Collection by topic.
Turbulence modeling
Theory
- Detailed theory on turbulence modeling - In this tutorial you find the basic theory of turbulence modeling.
- Steady-state turbulence modeling - Here you will find a basic 2D hands-on tutorial to understand the theory of steady-state turbulence modeling.
- Turbulence – Steady state - Use simpleFoam solver, run a steady state simulation with following turbulence models: kEpsilon (RAS), kOmega (RAS) and LRR (RAS).
- Transient turbulence modeling - Here you will find a basic 2D hands-on tutorial to understand the theory of transient turbulence modeling.
- Turbulence – Transient - Use the pisoFoam solver, run a backward facing step case for 0.2 s with different turbulence models: Smagorinsky (LES), kEqn (LES) and kEpsilon (RAS).
Application cases
- Flow around a car - Here you will learn about the flow around a car.
- Flow around a circular cylinder - 2D case - This tutorial describes the flow around a 2D circular cylinder.
- Flow around a square cylinder - 3D case - This tutorial describes the flow around a 3D square cylinder.
- Flow around a hemisphere - This tutorial gives you an extensive introduction to the flow around a hemisphere, which can be seen as one of the simplest case of an external flow.
Further reading
Publications
- S. Jakirlic, L. Kutej, P. Unterlechner and C. Tropea: Critical Assessment of Some Popular Scale-Resolving Turbulence Models for Vehicle Aerodynamics, SAE Int. J. Passeng. Cars - Mech. Syst., Volume 10(1), p. 235-250, 2017, doi:10.4271/2017-01-1532.
- M. Islam, F. Decker, E. de Villiers, A. Jackson, J. Gines, T. Grahs, A. Gitt–Gehrke and J. Comas i Font: Application of Detached–Eddy Simulation for Automotive Aerodynamics Development, SAE International, 2009-01-0333, 2009.