Turbulent drag reduction by spanwise wall forcing. Part 2: High-Reynolds-number experiments

TL;DR

This study investigates high-Reynolds-number turbulent drag reduction using spanwise wall forcing, demonstrating that outer-scaled actuation achieves energy-efficient drag reduction with positive net power savings.

Contribution

It provides experimental validation of outer-scaled actuation for drag reduction at high Reynolds numbers, highlighting its energy efficiency and effectiveness.

Findings

Up to 25% drag reduction with high power input in ISA pathway.

Consistent 5-10% net power savings with OSA pathway.

Complex turbulence interactions attenuate fluctuations across scales.

Abstract

Here, we present measurements of turbulent drag reduction in boundary layers at high friction Reynolds numbers in the range of $4500 \le Re_\tau \le 15000$. The efficacy of the approach, using streamwise travelling waves of spanwise wall oscillations, is studied for two actuation regimes: (i) inner-scaled actuation (ISA), as investigated in Part 1 of this study, which targets the relatively high-frequency structures of the near-wall cycle, and (ii) outer-scaled actuation (OSA), which was recently presented by Marusic et al. (Nat. Commun., vol. 12, 2021) for high-$Re_\tau$ flows, targeting the lower-frequency, outer-scale motions. Multiple experimental techniques were used, including a floating-element balance to directly measure the skin-friction drag force, hot-wire anemometry to acquire long-time fluctuating velocity and wall-shear stress, and stereoscopic-PIV (particle image velocimetry) to measure the turbulence statistics of all three velocity components across the boundary layer. Under the ISA pathway, drag reduction of up to 25% was achieved, but mostly with net power saving losses due to the high-input power cost associated with the high-frequency actuation. The low-frequency OSA pathway, however, with its lower input power requirements, was found to consistently result in positive net power savings of 5 - 10%, for moderate drag reductions of 5 - 15%. The results suggest that OSA is an attractive pathway for energy-efficient drag reduction in high Reynolds number applications. Both ISA and OSA strategies are found to produce complex inter-scale interactions, leading to attenuation of the turbulent fluctuations across the boundary layer for a broad range of length and time scales.