Aerodynamic Performance of a Tip-Mounted Propeller-Wing System at Positive and Negative Thrust

Abstract

A wind-tunnel experiment was performed at the DNW Low-Speed Tunnel with a powered propeller-wing model to prove the concept of energy-harvesting with propellers and assess its impact on the wing performance. By separating the contributions of the propeller and wing to the overall system forces, both for positive and negative thrust settings improved understanding was obtained of the propeller-wing interaction. A tip-mounted propeller configuration was simulated. At positive thrust settings, the operation of the propeller increased the lift gradient and improved the aerodynamic efficiency of the wing (L/D) by 10-35% compared to the propeller-off configuration. At CL = 0.5 and net zero force in streamwise direction the benefit was 12%, while at CL = 1.0 and a net force in streamwise direction of approximately three times the wing drag the benefit was 32%. At negative thrust, the propeller operation decreased the lift gradient, but the wing aerodynamic efficiency was still higher than that of the propeller-off configuration. This was an unexpected result, which was explained by the reduction in friction drag on the wing immersed in the propeller slipstream due to the lower dynamic pressure, and a possible reduction in wing induced drag due to downwash on the outboard part of the wing. The aileron effectiveness was decreased by about 10% when switching from positive to negative thrust operation. However, for angles of attack up to approximately 14 degrees even at negative thrust, the aileron effectiveness was still higher than for the clean wing.