Turbulent energy scale budget equations in a fully developed channel flow

L. DANAILA; F. ANSELMET; T. ZHOU; R. A. ANTONIA

doi:10.1017/S0022112000002767

Abstract

Kolmogorov's equation, which relates second- and third-order moments of the velocity increment, provides a simple method for estimating the mean energy dissipation rate 〈ε〉 for homogeneous and isotropic turbulence. However, this equation is usually not verified in small to moderate Reynolds number flows. This is due partly to the lack of isotropy in either sheared or non-sheared flows, and, more importantly, to the influence, which is flow specific, of the inhomogeneous and anisotropic large scales. These shortcomings are examined in the context of the central region of a turbulent channel flow. In this case, we propose a generalized form of Kolmogorov's equation, which includes some additional terms reflecting the large-scale turbulent diffusion acting from the walls through to the centreline of the channel. For moderate Reynolds numbers, the mean turbulent energy transferred at a scale r also contains a large-scale contribution, reflecting the non-homogeneity of these scales. There is reasonable agreement between the new equation and hot-wire measurements in the central region of a fully developed channel flow.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Danaila, L. and Mydlarski, L. 2001. Effect of gradient production on scalar fluctuations in decaying grid turbulence. Physical Review E, Vol. 64, Issue. 1,

Danaila, L. Anselmet, F. and Antonia, R. A. 2002. An overview of the effect of large-scale inhomogeneities on small-scale turbulence. Physics of Fluids, Vol. 14, Issue. 7, p. 2475.

Gotoh, Toshiyuki Fukayama, Daigen and Nakano, Tohru 2002. Velocity field statistics in homogeneous steady turbulence obtained using a high-resolution direct numerical simulation. Physics of Fluids, Vol. 14, Issue. 3, p. 1065.

Danaila, L Antonia, R A and Burattini, P 2004. Progress in studying small-scale turbulence using exact two-point equations. New Journal of Physics, Vol. 6, Issue. , p. 128.

Burattini, P. Antonia, R. A. and Danaila, L. 2005. Scale-by-scale energy budget on the axis of a turbulent round jet. Journal of Turbulence, Vol. 6, Issue. , p. N19.

Gotoh, Toshiyuki and Watanabe, Takeshi 2005. Statistics of transfer fluxes of the kinetic energy and scalar variance. Journal of Turbulence, Vol. 6, Issue. , p. N33.

Mouri, Hideaki Takaoka, Masanori Hori, Akihiro and Kawashima, Yoshihide 2006. On Landau’s prediction for large-scale fluctuation of turbulence energy dissipation. Physics of Fluids, Vol. 18, Issue. 1,

Rincon, François 2006. Theories of convection and the spectrum of turbulence in the solar photosphere. Proceedings of the International Astronomical Union, Vol. 2, Issue. S239, p. 58.

Kramm, Gerhard and Herbert, Fritz 2006. The Structure Functions of the Velocity and Temperature Fields from the Perspective of Dimensional Scaling. Flow, Turbulence and Combustion, Vol. 76, Issue. 1, p. 23.

Hill, Reginald J. 2006. Opportunities for use of exact statistical equations. Journal of Turbulence, Vol. 7, Issue. , p. N43.

Takaoka, Masanori Mouri, Hideaki Hori, Akihiro and Kawashima, Yoshihide 2007. Isotropy and the Kármán-Howarth-Kolmogorov relation in experimental and numerical turbulence. Physical Review E, Vol. 76, Issue. 6,

CASCIOLA, C. M. and DE ANGELIS, E. 2007. Energy transfer in turbulent polymer solutions. Journal of Fluid Mechanics, Vol. 581, Issue. , p. 419.

Sorriso-Valvo, L. Marino, R. Carbone, V. Noullez, A. Lepreti, F. Veltri, P. Bruno, R. Bavassano, B. and Pietropaolo, E. 2007. Observation of Inertial Energy Cascade in Interplanetary Space Plasma. Physical Review Letters, Vol. 99, Issue. 11,

Gkioulekas, Eleftherios 2007. On the elimination of the sweeping interactions from theories of hydrodynamic turbulence. Physica D: Nonlinear Phenomena, Vol. 226, Issue. 2, p. 151.

Marino, R. Sorriso-Valvo, L. Carbone, V. Noullez, A. Bruno, R. and Bavassano, B. 2008. Heating the Solar Wind by a Magnetohydrodynamic Turbulent Energy Cascade. The Astrophysical Journal, Vol. 677, Issue. 1, p. L71.

Servidio, Sergio Primavera, Leonardo Carbone, Vincenzo Noullez, Alain and Rypdal, Kristoffer 2008. A model for two-dimensional bursty turbulence in magnetized plasmas. Physics of Plasmas, Vol. 15, Issue. 1,

Marino, R. Sorriso-Valvo, L. Carbone, V. Noullez, A. Bruno, R. and Bavassano, B. 2009. The Energy Cascade in Solar Wind MHD Turbulence. Earth, Moon, and Planets, Vol. 104, Issue. 1-4, p. 115.

Lepreti, F. Carbone, V. Spolaore, M. Antoni, V. Cavazzana, R. Martines, E. Serianni, G. Veltri, P. Vianello, N. and Zuin, M. 2009. Yaglom law for electrostatic turbulence in laboratory magnetized plasmas. EPL (Europhysics Letters), Vol. 86, Issue. 2, p. 25001.

Thiesset, F Danaila, L Antonia, R, A and Zhou, T 2011. Scale-by-scale energy budgets which account for the coherent motion. Journal of Physics: Conference Series, Vol. 318, Issue. 5, p. 052040.

Schaefer, P. Gampert, M. Goebbert, J. H. Gauding, M. and Peters, N. 2011. Asymptotic analysis of homogeneous isotropic decaying turbulence with unknown initial conditions. Journal of Turbulence, Vol. 12, Issue. , p. N30.

Download full list

Article contents

Turbulent energy scale budget equations in a fully developed channel flow

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Turbulent energy scale budget equations in a fully developed channel flow

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests