Reynolds-number scaling of wall-pressure--velocity correlations in wall-bounded turbulence

Abstract

Wall-pressure fluctuations are a practically robust input for real-time control systems aimed at modifying wall-bounded turbulence. The scaling behaviour of the wall-pressure--velocity coupling requires investigation to properly design a controller with such input data so that it can actuate upon the desired turbulent structures. A comprehensive database from direct numerical simulations of turbulent channel flow is used for this purpose, spanning a Reynolds-number range Reτ ≈ 550-5\,200. Spectral analysis reveals that the streamwise velocity is most strongly coupled to the linear term of the wall-pressure, at a wall-scaling of λx/y ≈ 14 (and λx/y ≈ 8.5 for the wall-normal velocity). When extending the analysis to both homogeneous directions in x and y, the peak-coherence is centred at λx/λz ≈ 2 and λx/λz ≈ 1 for pw and u, and pw and v, respectively. A stronger coherence is retrieved when the quadratic term of the wall-pressure is concerned, but there is only little evidence for a wall-attached-eddy type of scaling. Experimental data are explored in the second part of this work: wall-pressure data are denoised and subsequently used for predicting the binary-state of the streamwise velocity fluctuations in the logarithmic region. A binary estimation accuracy of up to 72% can be achieved by including both the linear and quadratic terms of the wall-pressure. This study demonstrates that a controller for wall-bounded turbulence (solely relying on wall-pressure data) has merit in terms of a sufficient state estimation capability, even in the presence of significant facility noise.