Difference between revisions of "Ecfd:ecfd 3rd edition"
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* [[media:ecfd3_avbp_roadmap_HPC.pdf | Roadmap AVBP (HPC)]] | * [[media:ecfd3_avbp_roadmap_HPC.pdf | Roadmap AVBP (HPC)]] | ||
* [[media:ecfd3_yales2_roadmap.pdf | Roadmap YALES2]] | * [[media:ecfd3_yales2_roadmap.pdf | Roadmap YALES2]] | ||
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+ | == Booklet == | ||
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+ | * [[media:ecfd3_template.pdf | Template]] | ||
Revision as of 10:17, 31 January 2020
ECFD workshop, 3rd edition, 2020
Contents
- 1 Sponsors
- 2 Participants
- 3 Flyer
- 4 Presentations
- 5 Booklet
- 6 Project achievements
- 6.1 Project #1: Hackathon GENCI/ATOS/AMD/CERFACS on AVBP
- 6.2 Project #2: Hackathon GENCI/ATOS/AMD/CORIA on YALES2
- 6.3 Project #3: Implementation of a secondary atomization model in YALES2
- 6.4 Project #4: Application to combustion and lubrication applications
- 6.5 Project #5: Jet-in-crossflow par une méthode d’interface diffuse
- 6.6 Project #6: Accurate numerical prediction of vortical flows using AMR
- 6.7 Project #7: Modélisation de parois pour la simulation des grandes échelles
- 6.8 Project #8: Implémentation du calcul de la distance à une interface liquide-gaz proche d’une paroi sur maillage non structuré 3D avec YALES2
- 6.9 Project #9: Remeshed particle method at high Schmidt and Reynolds number
- 6.10 Project #10: Adaptive mesh refinement for turbulent premixed combustion
- 6.11 Project #11: Multiphysics coupling for wind turbine wake modeling
- 6.12 Project #12: Stability of a semi-implicit compressible cavitation solver
- 6.13 Project #13: Validations and comparisons of Diffuse / Sharp interface methods in a structured DNS solver (Titan)
- 6.14 Project #14: Méthode d'ordre élevé
- 6.15 Project #15: Utilisation d’éléments finis du second ordre dans le SMS
- 6.16 Project #16: Development of a RANS solver in YALES2
- 6.17 Project #17: COUPLING OF A FLUID PLASMA SOLVER WITH A LAGRANGIAN SOLVER FOR THE MODELING OF DUSTY
- 6.18 Project #18: L’Evaporo O Maıtre
- 6.19 Project #19: The Clone Wars
- 6.20 Project #20: Stiff complex fluid simulation with YALES2
- 6.21 Project #21: AVBP Dense Gases
- 6.22 Project #22: Numerical prediction of wind turbine wakes using AMR
Sponsors
Participants
Flyer
Presentations
Booklet
Project achievements
Project #1: Hackathon GENCI/ATOS/AMD/CERFACS on AVBP
C. Piechurski (GENCI), S. Jauré (ATOS), B. Pajot (ATOS), P.-A. Harraud (AMD), P. Mohanamuraly (CERFACS), G. Staffelbach (CERFACS), J. Legaux (CERFACS)
We ported the AVBP solver to the AMD Rome system available at GENCI -TGCC ( IRENE Joliot Curie). Characterisation of the application on the architecture showed a 1/3 performance dependency to bandwidth and 2/3 to compute. Strong scaling performance up to 130k cores was measured with openmpi and provided an acceleration of 75% without optimisations. Weak scaling up to 32k MPI ranks suggests that decimation of the processes by a factor 2 improves computational efficiency by up to 30%. This suggests a trade off between mpi imbalance and decimation is possible if imbalance is higher than 30% to improve time to solution.
Currently Openmpi offers the best perfofrmance, intelmpi is still a bit unstable.
During the Hackathon we also introduced colour based cache blocking using ColPack in the code in order to use OpenMP without critical sections. On a 2x18 core Skylake processor the new implementation offered similar speedup using full threading versus full MPI with the best trade off being 4 MPI and 9 threads per MPI. On AMD Rome, Full threading did not offer much acceleration and needs to be inversigated but 8 MPI and 16 threads per MPI seem quite promising.
Final presentation of project #1
Project #2: Hackathon GENCI/ATOS/AMD/CORIA on YALES2
C. Piechurski (GENCI), S. Jauré (ATOS), P.-A. Harraud (AMD), P. Mohanamuraly (CERFACS), G.Lartigue (CORIA), F. Gava (CORIA), P. Begou (LEGI)
Final presentation of project #2
Project #3: Implementation of a secondary atomization model in YALES2
C. G. Guillamon (Safran Tech), L .Voivenel (Safran Tech), R. Mercier (Safran Tech)
In Lagrangian simulations, droplets are transported following a ballistic motion in an eulerian mesh. For non-reactive environments, droplets might undergo secondary atomization due to the aerodynamic interaction. In this work, we implement in YALES2 a breakup model known as Taylor-Analogy Breakup (TAB). This model is based on the analogy between a droplet and a second-order mechanical system, hence making possible to determine the breakup behaviour by means of Newton's second law.
Another model, the stochastic breakup model by Gorokhovski, is also suggested for future work and will be implemented in YALES2.
Final presentation of project #3
Project #4: Application to combustion and lubrication applications
Final presentation of project #4
Project #5: Jet-in-crossflow par une méthode d’interface diffuse
Final presentation of project #5
Project #6: Accurate numerical prediction of vortical flows using AMR
Final presentation of project #6
Project #7: Modélisation de parois pour la simulation des grandes échelles
Final presentation of project #7
Project #8: Implémentation du calcul de la distance à une interface liquide-gaz proche d’une paroi sur maillage non structuré 3D avec YALES2
Final presentation of project #8
Project #9: Remeshed particle method at high Schmidt and Reynolds number
S. Santoso (LJK), J.-B. Lagaert (Math Orsay), G.Balarac (LEGI)
We study the advection of a scalar function in turbulent flows with a multimesh method. The finite volume method is used to solve Navier-Stokes equations on an unstructured mesh (YALES2). The advection equation is solved with remeshed particle method on a cartesian mesh. In the context of parallel computing, we face a very unbalanced problem since a large number of particles are created in a very fine meshed zone. Our strategy to load-balance the problem is to give a weight to every element group which is equal to the density of particle.
Final presentation of project #9
Project #10: Adaptive mesh refinement for turbulent premixed combustion
W. Agostinelli, O. Dounia, , T. Jaravel, O. Vermorel
The objective of the project was to evaluate the potential of adaptive mesh refinement (AMR) for premixed combustion in unsteady systems. Three target cases were identified: a semi-vented deflagration with laminar to turbulent transition, a planar detonation wave, and a bluff-body stabilized burner subjected to thermoacoustic oscillations. The simulations were performed with AVBP and coupled to the AMR implementation of YALES2. Several metrics and remeshing criterions were developed to identify and correctly resolve both the combustion wave front and the turbulent flow. The comparison of numerical results with reference simulations showed that the main features of the physics could be recovered with a significant speed-up in term of computational cost.
Final presentation of project #10
Project #11: Multiphysics coupling for wind turbine wake modeling
F.Houtin-Mongrolle (CORIA), B. Duboc (SGRE), P. Benard (CORIA)
The goal of this project was to evaluate the coupling of YALES2 (flow solver) and BHawC(Aero-Servo-Elastic solver).
Final presentation of project #11
Project #12: Stability of a semi-implicit compressible cavitation solver
Final presentation of project #12
Project #13: Validations and comparisons of Diffuse / Sharp interface methods in a structured DNS solver (Titan)
V. Boniou (EM2C), J.M. Dupays (EM2C), M. Pelletier (EM2C), T. Schmitt (EM2C), A. Vié (EM2C)
The objective of this workshop was to do the first validation test cases on droplet dynamic using our new in-house two-phase flow solver Titan. Titan code contains both diffuse interface methods and sharp interface methods.
Final presentation of project #13
Project #14: Méthode d'ordre élevé
M. Bernard (LEGI), G. Lartigue (CORIA), G. Balarac (LEGI), V. Moureau (CORIA)
Final presentation of project #14
Project #15: Utilisation d’éléments finis du second ordre dans le SMS
T. Fabbri (LEGI), G. Lartigue (CORIA), G. Balarac (LEGI), V. Moureau (CORIA)
Final presentation of project #15
Project #16: Development of a RANS solver in YALES2
G. Sahut (LEGI), G. Balarac (LEGI), V. Moureau (CORIA), G. Lartigue (CORIA), P. Bénard (CORIA), A. Grenouilloux (CORIA)
While the accuracy of LES usually approaches the one of DNS, LES are still too time-consuming for daily use in industrial applications. In this context, we started the development of a RANS solver in YALES2. We are first only interested in the steady state of the solution. In order to remove the CFL constraint, we developed, implemented and validated an implicit projection method for the resolution of the Navier-Stokes equations without turbulence models. The method is based on the implicitation of the velocity predictor ; the Poisson equation and the correction step of the velocity are then solved and applied as in the explicit incompressible solver. We validated the method on a stationary 2D Poiseuille flow with periodic boundary conditions: the simulation runs fine for CFL and Fourier numbers which are inaccessible with the explicit incompressible solver. The advection-diffusion equation for scalars has also been implicited and will be used to add turbulence models to the new implicit incompressible solver developped during this Workshop. More complex boundary conditions will also be addressed in a near future.
Final presentation of project #16
Project #17: COUPLING OF A FLUID PLASMA SOLVER WITH A LAGRANGIAN SOLVER FOR THE MODELING OF DUSTY
Final presentation of project #17
Project #18: L’Evaporo O Maıtre
Final presentation of project #18
Project #19: The Clone Wars
Final presentation of project #19
Project #20: Stiff complex fluid simulation with YALES2
Sam Whitmore, Yves Dubief, M2CE, University of Vermont
The objective was to simulate (1) ionized gases and (2) polymer solutions in flows using YALES2. Both problems are challenging owing to their stiff thermodynamics (1) or polymer dynamics (2). Significant gains were achieved in the implementation of the respective models thanks to the stiff integrator library CVODE. The plasma flow demonstrated an increase in time step of two orders of magnitude compared to previous implementation of the plasma chemistry in the variable density solver. Polymer models are notoriously prone to numerical instability. Again the use of CVODE showed equivalent if not superior stability of the solution at a fraction of the cost of commonly employed algorithms designed to address the stiffness of the problem.
Final presentation of project #20
Project #21: AVBP Dense Gases
Final presentation of project #21