Difference between revisions of "Step 2"

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(Step 2 Description)
(Step 2 Description)
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The next step in the benchmark is to simulate the Taylor-Green Vortex configuration in 3-D, still for a single-component incompressible flow.  
 
The next step in the benchmark is to simulate the Taylor-Green Vortex configuration in 3-D, still for a single-component incompressible flow.  
For this configuration, a reference solution obtained with a pseudo-spectral solver is available in the scientific literature<ref name="vanrees2011" /> ~\cite{vanrees2011} and can be used for validation by a direct comparison.
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For this configuration, a reference solution obtained with a pseudo-spectral solver is available in the scientific literature<ref name="vanrees2011">W.M. van Rees, A. Leonard, D.I. Pullin, and P. Koumoutsakos. A comparison of vortex and pseudo-spectral
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methods for the simulation of periodic vortical flows at high Reynolds numbers. J. Comput. Phys., 230:2794–2805, 2011.</ref> and can be used for validation by a direct comparison.
  
 
The domain size has been set to $L = 2 \pi L_0$ in each direction, where $L_0 = 1\; \mathrm{m}$ is an arbitrarily-chosen reference length scale for dimensional codes. As in the previous section, periodic boundary conditions are used in all three spatial directions.
 
The domain size has been set to $L = 2 \pi L_0$ in each direction, where $L_0 = 1\; \mathrm{m}$ is an arbitrarily-chosen reference length scale for dimensional codes. As in the previous section, periodic boundary conditions are used in all three spatial directions.

Revision as of 19:49, 4 August 2020

Step 2 Description

The next step in the benchmark is to simulate the Taylor-Green Vortex configuration in 3-D, still for a single-component incompressible flow. For this configuration, a reference solution obtained with a pseudo-spectral solver is available in the scientific literature[1] and can be used for validation by a direct comparison.

The domain size has been set to $L = 2 \pi L_0$ in each direction, where $L_0 = 1\; \mathrm{m}$ is an arbitrarily-chosen reference length scale for dimensional codes. As in the previous section, periodic boundary conditions are used in all three spatial directions.

The initial conditions for 3-D TGV are given by the following set of equations: \begin{eqnarray} u(x,y,z,0) &=& +u_0 \times \sin(x/L_0) \times \cos(y/L_0) \times \cos(z/L_0), \nonumber \\ v(x,y,z,0) &=& -u_0 \times \cos(x/L_0) \times \sin(y/L_0) \times \cos(z/L_0), \nonumber \\ w(x,y,z,0) &=& 0, \label{eq:2-D-tgv_init} \end{eqnarray}

The reference velocity magnitude is set again to $u_0 = 1 \; \mathrm{m/s}$. The desired Reynolds number is again Re$={u_0 L_0}/{\nu}=1,600$, as in the previous section, since this value has been used as well in the reference study employed for comparison~\cite{vanrees2011}. To obtain the proper value of Re, the kinematic viscosity is set once again to $\nu = 6.25 \times 10^{-4} \; \mathrm{m^2/s}$. With this set of parameters, the reference time scale is $\tau_\mathrm{ref}=L_0/u_0 = 1 \; \mathrm{s}$. The flow simulation must be carried out for a physical time of $t=20 \; \tau_\mathrm{ref}$.

Regarding spatial discretization, a resolution of at least $512$ nodes (or cells) in each direction is recommended. This value leads to an over-resolved simulation during the first few $\tau_\mathrm{ref}$ but is necessary to capture properly the transition to turbulence that should occur between 10 and 15 $\tau_\mathrm{ref}$. As a point of comparison, the reference solution from~\cite{vanrees2011} has been obtained with a spectral code on a $512^3$ grid. The timestep should be chosen to ensure that the maximum values of the Courant-Friedrichs-Lewy (CFL) and Fourier (Fo) numbers remain below $0.3$ and $0.2$, respectively. This values are actually quite conservative since the focus of this study is set on accuracy comparisons and not on pure computational performance.

Aside Suggestion

Check mesh convergence and time integration independence.

Check that -dKE/dt = \int Sij:Sij = \int Enstrophy


References

  • van Rees WM, Leonard A, Pullin D, Koumoutsakos P. A comparison of vortex and pseudo-spectral methods for the simulation of periodic vortical flows at high reynolds numbers. J Comput Phys. 2011;230(8):2794-2805.
  • Carton de Wiart C, Hillewaert K, Duponcheel M, Winckelmans G. Assessment of a discontinuous galerkin method for the simulation of vortical flows at high reynolds number. Int J Numer Meth Fluids. 2014;74(7):469-493.
  • Duponcheel M, Orlandi P, Winckelmans G. Time-reversibility of the euler equations as a benchmark for energy conserving schemes. J Comput Phys. 2008;227(19):8736-8752.
  • Bricteux, L, Zeoli, S, Bourgeois, N. Validation and scalability of an open source parallel flow solver. Concurrency Computat: Pract Exper. 2017; 29:e4330. https://doi.org/10.1002/cpe.4330
  • W.M. van Rees, A. Leonard, D.I. Pullin, and P. Koumoutsakos. A comparison of vortex and pseudo-spectral methods for the simulation of periodic vortical flows at high Reynolds numbers. J. Comput. Phys., 230:2794–2805, 2011.