Litcius/Paper detail

Low-Reynolds-number aerofoil boundary layer transition in large-scale free stream turbulence

Connor E. Toppings, Serhiy Yarusevych

2025Journal of Fluid Mechanics7 citationsDOIOpen Access PDF

Abstract

The effects of high-intensity, large-scale free stream turbulence on the aerodynamic loading and boundary layer flow field development on a NACA 0018 aerofoil model were studied experimentally using direct force measurements and particle image velocimetry at a chord Reynolds number of $7\times 10^4$ . An active turbulence grid was used to generate free stream turbulence intensities of up to $16\,\%$ at integral length scales of the order of the aerofoil chord length. Relative to the clean flow condition with a free stream turbulence intensity of $0.1\,\%$ , elevated levels of free stream turbulence intensity decrease the lift slope at low angles of attack, and increase the stall angle and maximum lift coefficient. At moderate angles of attack, high-intensity free stream turbulence causes large variations in the location of transition, with laminar flow occasionally persisting over $90\,\%$ of the chord length. At pre-stall angles of attack, high-intensity free stream turbulence causes intermittent massive separation. Variations in the extent of turbulence in the suction surface boundary layer are linked to fluctuations in effective angle of attack, suggesting that the observed variability in transition location is related to large-scale incoming flow disturbances impinging on the aerofoil model. A comparative analysis of the present results and those in previous studies for predominantly smaller integral length scales shows the importance of both the intensity and length scale of free stream turbulence on the flow development over the aerofoil.

Topics & Concepts

AirfoilTurbulenceMechanicsBoundary layerPhysicsChord (peer-to-peer)Turbulence kinetic energyK-epsilon turbulence modelFlow separationReynolds numberParticle image velocimetryLift (data mining)Laminar flowLift coefficientTurbulence modelingStall (fluid mechanics)NACA airfoilAerodynamicsLaminar-turbulent transitionK-omega turbulence modelLift-to-drag ratioAngle of attackIntermittencyFree surfaceClassical mechanicsBoundary layer thicknessDragRelative windFluid Dynamics and Turbulent FlowsComputational Fluid Dynamics and AerodynamicsFluid Dynamics and Vibration Analysis