Characterisation of rough-wall drag in compressible turbulent boundary layers

Abstract

In compressible turbulent boundary layers (TBLs), roughness drag is typically characterised by first applying a velocity transformation to account for compressibility, after which the momentum deficit U+ (Hama, 1954) and the equivalent sand-grain roughness ks are inferred. In practice, ks is often obtained from measurements at a single Mach number M and Reynolds number Re, effectively forcing the roughness into the U+--(ks) relation of Nikuradse (1933). This raises a key question: if a rough surface has a known ks in incompressible flow, under what conditions can this value be used in compressible flows? This question is explored using data obtained through a series of experiments of TBLs on rough walls (P60- and P24-grit sandpapers) over 0.3 ≤ M ≤ 2.9 and 7427 ≤ Reτ ≤ 30292, including independent variation of Reτ at M=2. Results show that U+ is largely insensitive to the velocity transformation, but the fully rough regime exhibits a Mach-number-dependent shift in the logarithmic relation. Three empirical scalings are examined: an equivalent incompressible ks, a viscosity-scaled roughness k* = k/∞+ with ∞+ = ∞/w, and a correction factor 1/Fc where Fc depends on T∞/Tw. The last provides the most consistent improvement across datasets, although all corrections remain empirical and rely on smooth-wall compressibility transformations. This paves the way for future work to develop custom transformation for a rough-wall TBL that can account for roughness properties and other parameters including wall conditions.

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