Boundary layer unsteady blowing is one of the most advanced solution to reduce aircraft parasite drag and flow separation at high angles of attack. In this way high lift can be achieved along with low-drag and since endurance is one of the most important performance parameter for some types of aircraft, such as an UAV, it is clear that the ratio CL3/2/CD has to be maximized. Main goal of the present investigation is the exploration of the possible ways for obtaining efficient turbulent boundary layer control, keeping in mind, at the same time, the practical problems connected to the installation of the device in a real wing. The work has been mainly addressed to the verification of active control through pulsed blowing as an effective tool to delay boundary layer separation. Numerical simulation and experimental investigations on a model wing opportunely instrumented and set in the wind tunnel are presented followed by the discussion of results.
Improving aircraft endurance through turbolent separation control / Coiro, Domenico; Bellobuono, ERNANI FULVIO; Nicolosi, Fabrizio; R., Donelli. - ELETTRONICO. - AIAA 2007-4428:(2007), pp. 100-110. (Intervento presentato al convegno 25th AIAA Applied Aerodynamics Conference tenutosi a Miami, FL nel 25-28 June 2007).
Improving aircraft endurance through turbolent separation control
COIRO, DOMENICO;BELLOBUONO, ERNANI FULVIO;NICOLOSI, FABRIZIO;
2007
Abstract
Boundary layer unsteady blowing is one of the most advanced solution to reduce aircraft parasite drag and flow separation at high angles of attack. In this way high lift can be achieved along with low-drag and since endurance is one of the most important performance parameter for some types of aircraft, such as an UAV, it is clear that the ratio CL3/2/CD has to be maximized. Main goal of the present investigation is the exploration of the possible ways for obtaining efficient turbulent boundary layer control, keeping in mind, at the same time, the practical problems connected to the installation of the device in a real wing. The work has been mainly addressed to the verification of active control through pulsed blowing as an effective tool to delay boundary layer separation. Numerical simulation and experimental investigations on a model wing opportunely instrumented and set in the wind tunnel are presented followed by the discussion of results.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.