Reynolds-dependence of turbulent skin-friction drag reduction induced by spanwise forcing

TL;DR

This study investigates how increasing Reynolds number impacts the effectiveness of spanwise wall forcing techniques for turbulent skin-friction drag reduction, using extensive DNS data at different Re to analyze performance and scaling.

Contribution

It provides a comprehensive analysis of the Reynolds dependence of spanwise forcing drag reduction, including a systematic database and insights into viscous scaling effects.

Findings

Drag reduction performance remains consistent with Re when scaled by friction velocity.

Maximum drag reduction declines mildly with Re, following a logarithmic trend.

Traveling waves could still achieve ~30% drag reduction at flight Reynolds numbers.

Abstract

This paper examines how increasing the value of the Reynolds number $Re$ affects the ability of spanwise-forcing techniques to yield turbulent skin-friction drag reduction. The considered forcing is based on the streamwise-travelling waves of spanwise wall velocity (Quadrio {\em et al. J. Fluid Mech.}, vol. 627, 2009, pp. 161--178). The study builds upon an extensive drag-reduction database created with Direct Numerical Simulation of a turbulent channel flow for two, 5-fold separated values of $Re$, namely $Re_\tau=200$ and $Re_\tau=1000$. The sheer size of the database, which for the first time systematically addresses the amplitude of the forcing, allows a comprehensive view of the drag-reducing characteristics of the travelling waves, and enables a detailed description of the changes occurring when $Re$ increases. The effect of using a viscous scaling based on the friction velocity of either the non-controlled flow or the drag-reduced flow is described. In analogy with other wall-based drag reduction techniques, like for example riblets, the performance of the travelling waves is well described by a vertical shift of the logarithmic portion of the mean streamwise velocity profile. Except when $Re$ is very low, this shift remains constant with $Re$, at odds with the percentage reduction of the friction coefficient, which is known to present a mild, logarithmic decline. Our new data agree with the available literature, which is however mostly based on low-$Re$ information and hence predicts a quick drop of maximum drag reduction with $Re$. The present study supports a more optimistic scenario, where for an airplane at flight Reynolds numbers a drag reduction of nearly 30\% would still be possible thanks to the travelling waves.