CFD
This page is currently a work in progress by Nik Lebedenko - if you want to ask questions / see a mistake / request more details to be added to this page, feel free to email me or message me on slack.
Fluid-structure interaction (FSI)
This technique allows complex interactions between flexible structures and fluid flows. This has been used to predict fin flutter at hypersonic speeds for Griffin 1.
Simulations of this kind are achievable with the combination of the following free open-source software packages:
- OpenFOAM (website, install on Ubuntu) - a C/C++ library for the solution of fluid mechanics problems formulated with the Finite Volume Method (FVM),
- Important: there are two main versions of OpenFOAM, provided at OpenFOAM.com and OpenFOAM.org. I have only used the .com version, but everything here should also be possible with the .org version.
- FEniCS (website, install on Ubuntu) - a Python interface to the DOLFIN C++ library for the solution of solid mechanics problems formulated with the Finite Element Method (FEM), and
- preCICE (website, install on Ubuntu) - a very powerful library which allows the coupling of arbitrary solvers using human-readable syntax.
- Note: in order to use OpenFOAM and FEniCS with preCICE, it is also necessary to download their respective adapters. See this page for OpenFOAM and this page for FEniCS from the preCICE website for further information.
Step-by-step instructions
IMPORTANT: Although I include the links to the official websites for Ubuntu installation instructions, I recommend you follow my instructions for installation (unless you are a masochist), since the official instructions contain some mistakes and omissions.
- Install Ubuntu. If you are running a Windows machine (Windows 10 or above), I recommend installing Windows Subsystem for Linux (WSL - use WSL1, discussion of WSL2 below) instead of setting up a dual-boot partition.
- Note: there is a choice between WSL1 and WSL2, with the main difference being that WSL2 has significantly improved read-write speeds compared with WSL1 while staying within the Linux file system, but WSL2 has significantly worse read-write speeds when moving between the Linux and Windows file systems. In practical terms, this means that the Linux-based software (OpenFOAM, FEniCS) will read and write faster, at the expense of Windows-based ParaView installations loading results much slower when post-processing. Since OpenFOAM spends significantly more time solving equations than reading and writing files, and gigabytes of data need to be loaded across file systems for post-processing in Windows, I recommend sticking with WSL1. If you prefer WSL2, you can install ParaView on Ubuntu, installing XMing to view the GUI (see this page and this page for further information)
- Install OpenFOAM on Ubuntu. The Ubuntu installation instructions as of 31/12/2021 are summarised below:Ensure that your ~/.bashrc file has the following line appended (with XXXX replaced with your version number):
curl -s https://dl.openfoam.com/add-debian-repo.sh | sudo bash sudo apt-get install openfoam2012-default
Restart your Ubuntu. Now check the installation completed correctly by running a tutorial case:source /usr/lib/openfoam/openfoamXXXX/etc/bashrc
Note: I use OpenFOAMv2012, but later versions should also work.cd ~ mkdir -p OpenFOAM-sims/tutorials cp -r $FOAM_TUTORIALS/incompressible OpenFOAM-sims/tutorials cd OpenFOAM-sims/tutorials/incompressible/icoFoam/cavity/cavity/ blockMesh > log.blockMesh icoFoam > log.icoFoam
- Install FEniCS on Ubuntu. The Ubuntu installation instructions as of 31/12/2021 are summarised below:
sudo apt-get install software-properties-common sudo add-apt-repository ppa:fenics-packages/fenics sudo apt-get update sudo apt-get install fenics
- Install preCICE on Ubuntu. The Ubuntu installation instructions as of 31/12/2021 are summarised below: Now either install the Ubuntu package directly with the instructions below (which did not work for me)...
sudo apt update sudo apt install build-essential cmake libeigen3-dev libxml2-dev libboost-all-dev petsc-dev python3-dev python3-numpy cd ~ mkdir FSI cd FSI
... or install from source:wget https://github.com/precice/precice/releases/download/v2.3.0/libprecice2_2.3.0_focal.deb sudo apt install ./libprecice2_2.3.0_focal.deb
Test that the cmake command worked as expected:tar -xzf v2.3.0.tar.gz cd precice-2.3.0 mkdir build cd build cmake -DBUILD_SHARED_LIBS=ON -DCMAKE_BUILD_TYPE=Release -DCMAKE_INSTALL_PREFIX=~/FSI/precice-2.3.0 -DPRECICE_MPICommunication=ON .. ### IMPORTANT! INCLUDE THE TWO DOTS! make -j 4
If no errors were shown, install the software and test it worked:cd ~/FSI/precice-2.3.0/build ctest --output-on-failure
Note: I used preCICE v2.3.0, but later versions should also work.make install make test_install
- Install the OpenFOAM-preCICE adapter. The Ubuntu installation instructions as of 31/12/2021 are summarised below:Note: this is for OpenFOAMv2012. Please see the preCICE website for information on adapters for later versions.
cd ~/FSI wget https://github.com/precice/openfoam-adapter/releases/download/v1.0.0/openfoam-adapter_v1.0.0_OpenFOAMv1812-v2012.tar.gz tar -xzf openfoam-adapter_v1.0.0_OpenFOAMv1812-v2012.tar.gz cd openfoam-adapter_v1.0.0_OpenFOAMv1812-v2012/ export LD_LIBRARY_PATH=/usr/lib/x86_64-linux-gnu:$LD_LIBRARY_PATH ### This line may-or-may-not be needed. YMMV. ./Allwmake
- Install the FEniCS-preCICE adapter. The Ubuntu installation instructions as of 31/12/2021 are summarised below (requires Python3, should already be installed if you followed my previous instructions):
(optional, should not need this line) python3 -m pip install scipy python3 -m pip install --user fenicsprecice
- Test the installation ran correctly (by running this tutorial case): The command line output should have paused after this output. If it did not pause, something went wrong.
cd ~/FSI git clone --branch=master --depth 1 https://github.com/precice/tutorials.git cd ~/FSI/tutorials/perpendicular-flap/fluid-openfoam ./run.sh
Now open another Ubuntu terminal, and run these commands:---[precice] I am participant "Fluid" ---[precice] Setting up master communication to coupling partner/s
Both terminals should now have log outputs flying. After around 1 minute of computation, both terminals should finish at (roughly) the same time. You can view the results with the following commands, assuming you have installed ParaView on Windows and added the folder containing its .exe file to the Windows PATH environment variable:cd ~/FSI/tutorials/perpendicular-flap/solid-fenics ./run.sh
cd ~/FSI/tutorials/perpendicular-flap/fluid-openfoam paraview.exe fluid-openfoam.foam
Congratulations! You should now have a functional FSI installation.
Note that as of 31/12/2021, the unmodified FEniCS-preCICE adapter only works in 2D, so you will have to edit the adapter (or download my edited version, TODO add link here) in order to add 3D FSI functionality. Or just wait a few months until I get around to submitting a pull request for my version.
TODO:
- ParaView install instructions
- Resources for learning CFD and FEM
- A complete line-by-line breakdown of simpleFoam
- rhoCentralFoam resources
- Tips and Tricks from experience
- How to do 3D hypersonic fin flutter