Experimental investigation on the turbulent wake flow in fully-established transonic buffet conditions

TL;DR

This study experimentally investigates the turbulent wake flow behind a supercritical airfoil during transonic buffet conditions, revealing how shock-wave interactions influence wake turbulence and vortex shedding.

Contribution

It provides detailed experimental insights into the turbulent wake structures and their spectral characteristics under transonic buffet, highlighting the impact of shock-induced flow separation.

Findings

Severe flow separation and momentum deficit in the wake during buffet.

High-frequency vortex shedding forming a von Karman vortex street.

Significant influence of buffet on turbulent wake dynamics.

Abstract

The transonic flight regime is often dominated by transonic buffet, a highly unsteady and complex shock-wave/boundary-layer interaction involving major parts of the flow field. The phenomenon is associated with a large-amplitude periodic motion of the compression shock coupled with large-scale flow separation and intermittent re-attachment. Due to the resulting large-scale variation of the global flow topology, also the turbulent wake of the airfoil or wing is severely affected, and so are any aerodynamic devices downstream on which the wake impinges. To analyze and understand the turbulent structures and dynamics of the wake, we performed a comprehensive experimental study of the near wake of the supercritical OAT15A airfoil in transonic buffet conditions at a chord Reynolds number of 2 mio. Velocity field measurements reveal severe global influences of the buffet mode on both the surface-bound flow field on the suction side of the airfoil and the wake. The flow is intermittently strongly separated, with a significant momentum deficit that extends far into the wake. The buffet motion induces severe disturbances and variations of the turbulent flow, as shown on the basis of phase-averaged turbulent quantities in terms of Reynolds shear stress and RMS-values. The spectral nature of downstream-convecting fluctuations and turbulent structures are analyzed using high-speed focusing schlieren sequences. Analyses of the power spectral density pertaining to the vortex shedding in the direct vicinity of the trailing edge indicate dominant frequencies one order of magnitude higher than those associated with shock buffet. It is shown that the flapping motion of the shear layer is accompanied by the formation of a von Karman-type vortex street of fluctuating strength. These wake structures and dynamics will impact any downstream aerodynamic devices affected by the wake.