A Reynolds-averaged Navier–Stokes (RANS) computational study was conducted to investigate the effect of various variable camber continuous trailing edge flap (VCCTEF) configurations on the lift and drag of a NASA generic transport model (GTM) wing section. Out of the five two-dimensional (2D) VCCTEF configurations considered with varying camber in the three-segment flap region, with a total deflection of 6 deg, the best stall performance was exhibited by the circular and parabolic arc camber flaps. Both circular and parabolic arc flaps give similar lift performance, with the circular arc yielding a higher lift coefficient and parabolic arc resulting in the lowest drag and hence the best L/D performance at design Cl. Analysis of results based on linear theory shows excellent agreement between computed and theoretical incremental lift.

Issue Section:
Flows in Complex Systems
Keywords:
Aerodynamics , Compressible flows, Computational fluid dynamics, Drag, RANS simulations, Shocks, Transonic flows, Unsteady flows
Topics:
Airfoils, Drag (Fluid dynamics), Flow (Dynamics), Simulation, Turbulence, Wings, Reynolds-averaged Navier–Stokes equations, Pressure, Shock (Mechanics), Design, NASA, Computational fluid dynamics, Deflection

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