Wall effects on pressure fluctuations in turbulent channel flow

Abstract

AbstractThe purpose of the present paper is to study the influence of wall echo on pressure fluctuations${p}^{\prime } $, and on statistical correlations containing${p}^{\prime } $, namely, redistribution${\phi }_{ij} $, pressure diffusion${ d}_{ij}^{(p)} $and velocity pressure-gradient${\Pi }_{ij} $. We extend the usual analysis of turbulent correlations containing pressure fluctuations in wall-bounded direct numerical simulations (Kim,J. Fluid Mech., vol. 205, 1989, pp. 421–451), separating${p}^{\prime } $not only into rapid${ p}_{(r)}^{\prime } $and slow${ p}_{(s)}^{\prime } $parts (Chou,Q. Appl. Maths, vol. 3, 1945, pp. 38–54), but also further into volume (${ p}_{(r; \mathfrak{V})}^{\prime } $and${ p}_{(s; \mathfrak{V})}^{\prime } $) and surface (wall echo,${ p}_{(r; w)}^{\prime } $and${ p}_{(s; w)}^{\prime } $) terms. An algorithm, based on a Green’s function approach, is developed to compute the above splittings for various correlations containing pressure fluctuations (redistribution, pressure diffusion, velocity pressure-gradient), in fully developed turbulent plane channel flow. This exact analysis confirms previous results based on a method-of-images approximation (Manceau, Wang & Laurence,J. Fluid Mech., vol. 438, 2001, pp. 307–338) showing that, at the wall,${ p}_{(\mathfrak{V})}^{\prime } $and${ p}_{(w)}^{\prime } $are usually of the same sign and approximately equal. The above results are then used to study the contribution of each mechanism to the pressure correlations in low-Reynolds-number plane channel flow, and to discuss standard second-moment-closure modelling practices.