Litcius/Paper detail

An energy-efficient pathway to turbulent drag reduction

Ivan Maruŝiĉ, Dileep Chandran, Amirreza Rouhi, Matthew Fu, David Wine, Brian C. Holloway, Daniel Chung, Alexander J. Smits

2021Nature Communications139 citationsDOIOpen Access PDF

Abstract

Simulations and experiments at low Reynolds numbers have suggested that skin-friction drag generated by turbulent fluid flow over a surface can be decreased by oscillatory motion in the surface, with the amount of drag reduction predicted to decline with increasing Reynolds number. Here, we report direct measurements of substantial drag reduction achieved by using spanwise surface oscillations at high friction Reynolds numbers ([Formula: see text]) up to 12,800. The drag reduction occurs via two distinct physical pathways. The first pathway, as studied previously, involves actuating the surface at frequencies comparable to those of the small-scale eddies that dominate turbulence near the surface. We show that this strategy leads to drag reduction levels up to 25% at [Formula: see text] = 6,000, but with a power cost that exceeds any drag-reduction savings. The second pathway is new, and it involves actuation at frequencies comparable to those of the large-scale eddies farther from the surface. This alternate pathway produces drag reduction of 13% at [Formula: see text] = 12,800. It requires significantly less power and the drag reduction grows with Reynolds number, thereby opening up potential new avenues for reducing fuel consumption by transport vehicles and increasing power generation by wind turbines.

Topics & Concepts

DragTurbulenceReynolds numberDrag coefficientPhysicsAlgorithmArtificial intelligenceMaterials scienceMechanicsComputer scienceFluid Dynamics and Turbulent FlowsFluid Dynamics and Vibration AnalysisHeat Transfer Mechanisms