Reynolds number effects on surface-induced secondary flows in turbulent boundary layers
Abstract
This study explores the effect of friction Reynolds number (Reτ ≈ 3,000--13,000) on secondary flows in three-dimensional turbulent boundary layers induced by spanwise surface heterogeneity. Using a combination of floating-element drag balance and high-resolution hot-wire anemometry, we examine how varying spanwise spacing (S/δ) influences frictional drag, turbulence intensity, spectral energy distribution, and the organisation of coherent structures. The results reveal that secondary flows modulate turbulence differently depending on S/δ, with strong near-wall effects at S/δ < 1 and outer-layer modulation at S/δ 1. A robust spectral signature of secondary flows peaking at λx ≈ 3δ and y ≈ 0.5δ emerges across all cases. This peak coexists with, or suppresses, very-large-scale motions (VLSMs), depending on flow region and spacing. While VLSMs are suppressed in low-momentum pathways (LMPs), they gradually recover in high-momentum pathways (HMPs) at higher S/δ and Reτ. These findings offer new insight into the interplay between secondary motions and scale interactions in three-dimensional turbulent boundary layers, with implications for drag control, mixing, and surface design.
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