Lagrangian studies in convective turbulence. - In: Physical review. Statistical, nonlinear, and soft matter physics / American Physical Society. - College Park, Md. : APS, January 1993-December 2015 , ISSN: 1550-2376 , ZDB-ID: 1472725-0, ISSN 1550-2376, Bd. 79 (2009), 5, S. 056301, insges. 13 S.
http://dx.doi.org/10.1103/PhysRevE.79.056301
Turbulent channel flow with 2D wedges of random height on one wall. - In: International journal of heat and fluid flow, ISSN 1879-2278, Bd. 30 (2009), 5, S. 1007-1015
Direct numerical simulations (DNS) of a turbulent channel flow with 2D wedges of random height on the bottom wall have been performed. In addition, two other simulations have been carried out to assess the effect of the geometry on the overlying flow. In the first simulation, the four smallest elements were removed while in the other, a uniform distribution of wedges with the same area was used. Two Reynolds numbers were studied, Reb = 2500 and Reb = 5000 which correspond in case of smooth walls to Rer = 180 and 300, respectively. Roughness on the wall induces separated regions, the reattachment occurring on the walls of the wedges or on the bottom wall. The pressure gradients on the walls increase the ejections and inrushes towards the wall. As a consequence the flow is more isotropic. The mechanism inducing an improved isotropy has been explained in term of the spectra and budgets of Reynolds stress. The comparison of the 3 surfaces has shown that near the wall, the uniformly distributed roughness represents only a poor approximation of the surface with wedges of random height. The Reynolds stresses, pressure distribution and spectra on the modified wall agree well with those on the random surface. Energy spectra show the pitch to height ratio of the largest elements to be the more appropriate geometrical parameter to describe the geometry.
https://doi.org/10.1016/j.ijheatfluidflow.2009.03.017
Velocity gradient statistics in a turbulent channel flow. - In: Advances in turbulence XII, (2009), S. 633-636
Turbulent heat transfer and large-scale flow in convection cells with aspect ratio [Gamma] > 1. - In: Advances in turbulence XII, (2009), S. 517-520
Lagrangian analysis of turbulent convection. - In: Advances in turbulence XII, (2009), S. 15-18
Energy dissipation rates in low-Rm MHD turbulence with mean shear: results for channel flow with spanwise field. - In: Magnetohydrodynamics, ISSN 0024-998X, Bd. 45 (2009), 2, S. 155-164
Measurement of local dissipation scales in turbulent pipe flow. - In: Physical review letters, ISSN 1079-7114, Bd. 103 (2009), 1, 014502, insges. 4 S.
https://doi.org/10.1103/PhysRevLett.103.014502
MHD turbulence in a channel with spanwise field. - In: Proceedings in applied mathematics and mechanics, ISSN 1617-7061, Bd. 8 (2008), 1, S. 10955-10956
http://dx.doi.org/10.1002/pamm.200810955
Temperature derivatives and thermal dissipation in turbulent Rayleigh-Bénard convection. - In: CD-ROM proceedings, ISBN 978-0-9805142-1-6, (2008), insges. 2 S.
Turbulent MHD channel flow with spanwise magnetic field. - In: CD-ROM proceedings, ISBN 978-0-9805142-1-6, (2008), insges. 2 S.