Difference between revisions of "Main Page"
Line 16: | Line 16: | ||
Three different low-Mach DNS solvers have been used for this study, demonstrating that the final accuracy of the DNS simulations is of the order of 1% for all quantities considered. | Three different low-Mach DNS solvers have been used for this study, demonstrating that the final accuracy of the DNS simulations is of the order of 1% for all quantities considered. | ||
− | The website is organised in | + | The website is organised in four major parts: |
+ | * A short description of the three codes used for the Benchmark: [https://www.coria-cfd.fr/index.php/YALES2 YALES2], [http://www.lss.ovgu.de/lss/en/Research/Computational+Fluid+Dynamics.html DINO] and [http://nek5000.mcs.anl.gov Nek5000]. | ||
* The [[description]] of the test cases | * The [[description]] of the test cases | ||
* The [[results]] of the test cases | * The [[results]] of the test cases |
Revision as of 05:51, 27 July 2020
The Taylor-Green Vortex as a Benchmark for High-Fidelity Combustion Codes
Verification and validation are crucial steps for the development of any numerical model.
While suitable processes have been established for commercial Computational Fluid Dynamics (CFD) codes, more difficult challenges must be faced for high-fidelity solvers.
Benchmarks have been proposed in a series of dedicated conferences for non-reacting configurations. However, to our knowledge, no suitable approach has been published up to now regarding turbulent reacting flows.
The purpose of this website is to present a full verification and validation chain for high-resolution codes employed to simulate turbulent reacting flows, first for Direct Numerical Simulation (DNS) of turbulent combustion in the limit of low Mach numbers.
The selected configuration builds on top of the Taylor-Green vortex. Verification takes place by comparison with the analytical solution in two dimensions. Validation of the single-component flow is ensured by comparisons with published results obtained with a spectral code. Mixing without reaction is then considered, before computing finally a hydrogen-oxygen flame interacting with a 3-D Taylor-Green vortex. Three different low-Mach DNS solvers have been used for this study, demonstrating that the final accuracy of the DNS simulations is of the order of 1% for all quantities considered.
The website is organised in four major parts:
- A short description of the three codes used for the Benchmark: YALES2, DINO and Nek5000.
- The description of the test cases
- The results of the test cases
- An attempt to give a few guidelines on the performances that could be expected on the 3D test-cases.
Put some images / videos here