Difference between revisions of "Taylor Couette flow by Andras Horvath"
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(Added picture from tutorials.) |
Jozsef Nagy (talk | contribs) |
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Go back to [https://wiki.openfoam.com/index.php?title=Day_2 Day 2]. | Go back to [https://wiki.openfoam.com/index.php?title=Day_2 Day 2]. | ||
− | =[ | + | =[https://rheologic.net/sites/default/files/pdf/taylor_couette_tutorial-20160913.pdf Taylor Couette flow]= |
[[File:Taylor_Couette_Flow.png|500px|right|]] | [[File:Taylor_Couette_Flow.png|500px|right|]] | ||
− | In this [ | + | In this [https://rheologic.net/sites/default/files/pdf/taylor_couette_tutorial-20160913.pdf pdf] you will find a compact description of a well known flow from literature. In this tutorial you will run a simple steady-state simulation, where you can directly compare the quality of your results with literature values. |
− | You can download the [ | + | You can download the [https://rheologic.net/sites/default/files/downloads/taylor_couette.tar.gz case files] here. |
In this tutorial we focus on: | In this tutorial we focus on: |
Revision as of 04:45, 3 May 2021
- contributor: Andras Horvath
- affiliation: Rheologic GmbH
- contact: click here for email address
- OpenFOAM version: v1812
- published under: CC BY-ND license (creative commons licenses)
Go back to Day 2.
Taylor Couette flow
In this pdf you will find a compact description of a well known flow from literature. In this tutorial you will run a simple steady-state simulation, where you can directly compare the quality of your results with literature values.
You can download the case files here.
In this tutorial we focus on:
- case, geometry and mesh setup
- boundary conditions
- solution evaluation and post processing
- comparison with theory and experiments from literature