Difference between revisions of "Day 2"
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Go back to [https://wiki.openfoam.com/index.php?title=%223_weeks%22_series "3 weeks" series]. | Go back to [https://wiki.openfoam.com/index.php?title=%223_weeks%22_series "3 weeks" series]. | ||
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=[https://wiki.openfoam.com/index.php?title=Grid_convergence_by_Jozsef_Nagy Grid convergence]= | =[https://wiki.openfoam.com/index.php?title=Grid_convergence_by_Jozsef_Nagy Grid convergence]= | ||
− | By now, you should be familiar to the basics of OpenFOAM. Let us continue with some general CFD topics, still covered in OpenFOAM. In this video you will learn the importance of grid resolution and its effect onto your results. | + | By now, you should be familiar to the basics of OpenFOAM. Let us continue with some general CFD topics, still covered in OpenFOAM. In this video you will learn the importance of grid resolution and its effect onto your results. The pdf version can be found [https://wiki.openfoam.com/Grid_Convergence_by_Bahram_Haddadi here]. |
* field initialization with setFields | * field initialization with setFields | ||
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=[https://wiki.openfoam.com/index.php?title=Transport_equation_by_Jozsef_Nagy Transport equation]= | =[https://wiki.openfoam.com/index.php?title=Transport_equation_by_Jozsef_Nagy Transport equation]= | ||
− | Another important general topic is the general transport equation. Here, you will get a basic idea on the structure of the equations, which are solved in CFD and also in OpenFOAM. | + | Another important general topic is the general transport equation. Here, you will get a basic idea on the structure of the equations, which are solved in CFD and also in OpenFOAM. The pdf version can be found [https://wiki.openfoam.com/Transport_Equation_by_Bahram_Haddadi here]. |
* the solver | * the solver | ||
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* post processing | * post processing | ||
− | =[https://wiki.openfoam.com/index.php?title= | + | =[https://wiki.openfoam.com/index.php?title=Taylor_Couette_flow_by_Andras_Horvath Taylor Couette flow]= |
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+ | In this short tutorial you will experience your first steady state simulation, where you can directly compare your results with experiments from literature. Here the focus will be on: | ||
− | + | * case, geometry and mesh setup | |
+ | * boundary conditions | ||
+ | * steady state simulation | ||
+ | * solution evaluation and post processing | ||
+ | * comparison with theory and experiments from literature | ||
− | + | =[https://wiki.openfoam.com/T-junction_by_Bahram_Haddadi_and_colleagues Residence time distribution]= | |
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− | =[https://wiki.openfoam.com/index.php?title=Visualization_by_Joel_Guerrero | + | Use the simpleFoam and scalarTransportFoam to simulate the flow through a square cross section T pipe and calculate RTD (Residence Time Distribution) for both inlets using a step function injection. |
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+ | * Understanding RTD calculation using OpenFOAM | ||
+ | * Using multiple solver for a simulation | ||
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+ | =[https://wiki.openfoam.com/index.php?title=Visualization_by_Joel_Guerrero Scientific visualization with paraview]= | ||
In this tutorial you will get a deep understanding on the scientific postprocessing and visualization of results in Paraview. | In this tutorial you will get a deep understanding on the scientific postprocessing and visualization of results in Paraview. | ||
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* Scientific visualization with paraFoam/ParaView | * Scientific visualization with paraFoam/ParaView | ||
− | =[https://wiki.openfoam.com/ | + | =[https://wiki.openfoam.com/Sampling_by_Bahram_Haddadi_and_colleagues Sampling]= |
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+ | Simulate the flow along a shock tube for 0.007 s and use OpenFOAM sampling utility for extracting the data along a line during the simulation and after the simulation. | ||
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+ | * Understand the function of sampling and how to use the sampling utility | ||
− | + | =[https://wiki.openfoam.com/Swak4Foam_and_PyFoam_by_Bruno_Santos Auxiliary Postprocessing]= | |
− | + | In this tutorial your will find useful information on how to postprocess your simulation results with the tools swak4Foam and PyFoam. | |
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=End of Day 2= | =End of Day 2= |
Revision as of 22:05, 3 October 2018
Welcome back to Day 2. Today is all about widening and extending our experience in OpenFOAM. Yesterday we learned a lot about the basic work flow and simple mesh creation, today we will start going into the depth of OpenFOAM and go through the entire CFD workflow until postprocessing. We will focus in
- more detailed understanding of the work flow
- further short and fun simulations
- grid convergence
- transport equations
- detailed scientific visualization of results
Go back to "3 weeks" series.
Contents
Grid convergence
By now, you should be familiar to the basics of OpenFOAM. Let us continue with some general CFD topics, still covered in OpenFOAM. In this video you will learn the importance of grid resolution and its effect onto your results. The pdf version can be found here.
- field initialization with setFields
- mesh refinement with blockMesh
- simulation of a 1D shock tube case
- influence of mesh refinement on the simulation results
- postprocessing
Transport equation
Another important general topic is the general transport equation. Here, you will get a basic idea on the structure of the equations, which are solved in CFD and also in OpenFOAM. The pdf version can be found here.
- the solver
- case setup
- transport phenomena like convection and diffusion
- influence of constants
- simulation of scalar transport
- post processing
Taylor Couette flow
In this short tutorial you will experience your first steady state simulation, where you can directly compare your results with experiments from literature. Here the focus will be on:
- case, geometry and mesh setup
- boundary conditions
- steady state simulation
- solution evaluation and post processing
- comparison with theory and experiments from literature
Residence time distribution
Use the simpleFoam and scalarTransportFoam to simulate the flow through a square cross section T pipe and calculate RTD (Residence Time Distribution) for both inlets using a step function injection.
- Understanding RTD calculation using OpenFOAM
- Using multiple solver for a simulation
Scientific visualization with paraview
In this tutorial you will get a deep understanding on the scientific postprocessing and visualization of results in Paraview.
The following topics will be covered:
- Postprocessing
- ParaView in a nutshell
- ParaView vs. paraFoam
- ParaView GUI overview
- Basic usage – Sources and filters
- Scientific visualization with paraFoam/ParaView
Sampling
Simulate the flow along a shock tube for 0.007 s and use OpenFOAM sampling utility for extracting the data along a line during the simulation and after the simulation.
- Understand the function of sampling and how to use the sampling utility
Auxiliary Postprocessing
In this tutorial your will find useful information on how to postprocess your simulation results with the tools swak4Foam and PyFoam.
End of Day 2
Thank you for finishing the second day. We hope, that you are still having fun. Let's continue tomorrow with Day 3.
Now let's take a rest.