Surface roughness effects on transonic aircraft performance: Experimental/numerical comparisons

•Use of an engineering-oriented correlation in conjunction with an equivalent sand-grain height surface roughness model for the aerodynamic performance analysis of a generic civil aircraft configuration.•Comparison of Reynolds-averaged Navier-stokes simulations against large-scale wind-tunnel experi...

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Bibliographic Details
Published inAerospace science and technology Vol. 154; p. 109507
Main Authors Hue, David, Cartieri, Aurélia, Petropoulos, Ilias
Format Journal Article
LanguageEnglish
Published Elsevier Masson SAS 01.11.2024
Elsevier
Subjects
Aircraft
Drag
Engineering Sciences
Flight
Physics
Prediction
Surface roughness
Wind tunnel
Surface roughness
Wind tunnel
Drag
Aircraft
Flight
Prediction
soufflerie
drag (physics)
aircraft
wind tunnel
état de surface (mécanique)
avion
surface roughness
traînée
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Summary:•Use of an engineering-oriented correlation in conjunction with an equivalent sand-grain height surface roughness model for the aerodynamic performance analysis of a generic civil aircraft configuration.•Comparison of Reynolds-averaged Navier-stokes simulations against large-scale wind-tunnel experiments.•Analysis of surface roughness effects on overall aircraft performance for different operating conditions. This work highlights the necessity of taking into account surface roughness when conducting experimental tests, and when using numerical simulations to precisely calculate the turbulent lift and drag of wind-tunnel models or real aircraft in transonic conditions. The present article is a continuation of “Turbulent drag induced by low surface roughness at transonic speeds: Experimental/numerical comparisons,” Physics of Fluids, Vol. 32, 045108 (2020) by Hue and Molton. The outcomes of this former study, which was focused on flat plate samples, are here applied to a three-dimensional aircraft configuration: the Common Research Model used as a reference in the recent international Drag Prediction Workshops. Experimental campaigns have been performed in the largest ONERA wind tunnels S1MA and S2MA involving models with average surface roughness heights Ra close to 0.5 micrometers, wingspans up to 3.5 meters, Mach and Reynolds numbers up to 0.95 and 5 million respectively. Reynolds-averaged Navier–Stokes computations based on the wind-tunnel tests have then been carried out, using the equivalent sand-grain roughness height approach as well as a Musker-type correlation to determine relevant ks values. The results of both the experimental and numerical campaigns have demonstrated that the aerodynamic coefficients of the aircraft can be significantly affected by the surface roughness, even with roughness Reynolds numbers ks+ potentially below the usual threshold values sometimes considered in engineering applications (i.e. in the order of 3.5 to 5). In particular, the surface roughness effects on lift and drag have been studied using far-field analyses to evaluate the responses of friction, viscous pressure, wave and lift-induced drag components. Finally, the numerical studies have been extended to the full-scale geometry in flight conditions in order to assess the roughness effects and potential gains in realistic aircraft operating conditions.
ISSN:1270-9638
DOI:10.1016/j.ast.2024.109507