%0 Generic %A Bauer, Christian %A Sakai, Yoshiyuki %A Uhlmann, Markus %D 2024 %T Data underlying the publication: Direct numerical simulation of turbulent open channel flow %U %R 10.4121/88678f02-2a34-4452-8534-6361fc34d06b.v2 %K direct numerical simulation %K DNS %K turbulent open channel flow %K OCF %K plane channel flow %K CCF %K free-slip boundary %K turbulence statistics %K velocity profile %K correlations %X <p>==============================================================================</p><p>DNS DATA OF TURBULENT CLOSED AND OPEN CHANNEL FLOW</p><p>IN BOXES OF Lx/h = 12pi, Lz/h = 4pi </p><p>FOR Re_tau = 200,400,600,900 </p><p>==============================================================================</p><p>Authors: C. Bauer, Y. Sakai & M. Uhlmann </p><p>correspondence: christian.bauer@dlr.de</p><p>Reference: <em>Direct numerical simulation of turbulent open channel flow: Streamwise turbulence intensity scaling and its relation to large-scale coherent motions,</em> proceedings of the 10th iTi conference on turbulence, 2023 </p><p>Numerical Method: Kim, Moin & Moser, 1987, J. Fluid Mech. vol 177, 133-166 </p><p>----------------------------------------------------------------------------------------------------------------------------</p><p> The data was obtained from direct numerical simulations of open and closed channel flow using a pseudo-spectral method which solves the wall-normal velocity/vorticity formulation of the Navier-Stokes equation introduced by Kim et al (1987). The flow domain contains Nx*Ny*Nz grid points with equidistant grid spacing in x and z direction and a Chebyshev-Gauss-Lobatto (CGL) grid in y direction. Note that the open channel flow simulations feature a grid refinement towards both the no-slip and the free-slip boundary condition.</p><p>----------------------------------------------------------------------------------------------------------------------------</p><p>For detailed information see data-sheet-ocf.pdf and data-sheet-ccf.pdf</p> %I 4TU.ResearchData