Aeroelasticity & Structural Dynamics in a Fast Changing World
17 – 21 June 2024, The Hague, The Netherlands
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Wind Tunnel Tests for Gust Load Investigation in transonic flows – Part 2: Experimental results and control demonstration


Go-down ifasd2024 Tracking Number 227

Presentation:
Session: Gust 5
Room: Room 1.2
Session start: 16:00 Thu 20 Jun 2024

Vincent Bouillaut   vincent.bouillaut@onera.fr
Affifliation: DAAA, ONERA, Institut Polytechnique de Paris, 92320 Chatillon, France

Alex Dos Reis De Souza   alex.dos_reis_de_souza@onera.fr
Affifliation: DTIS, ONERA, Universite de Toulouse, 31000, Toulouse, France

Pierre Vuillemin   Pierre.Vuillemin@onera.fr
Affifliation: DTIS, ONERA, Universite de Toulouse, 31000, Toulouse, France

Charles Poussot-Vassal   Charles.Poussot-Vassal@onera.fr
Affifliation: DTIS, ONERA, Universite de Toulouse, 31000, Toulouse, France

Arnaud Lepage   arnaud.lepage@onera.fr
Affifliation: DAAA, ONERA, Institut Polytechnique de Paris, 92320 Chatillon, France


Topics: - Active Control and Adaptive Structures (Vehicle analysis/design using model-based and data driven models), - Experimental Methods in Structural Dynamics and Aeroelasticity (Experimental methods), - Wind Tunnel and Flight Testing (Experimental methods)

Abstract:

Aerodynamic loads are a recurrent topic in aeronautical research. Indeed, during a flight, a wing can endure a wide variety of load sources impacting significantly the aerodynamical performances of the aircraft. Regarding those problematics, aeronautical studies aim to understand and find ways to decrease the effects of those disturbances. The present work focuses on one of those sources: the vertical gust, a particularly common phenomenon, responsible for important alterations of the airflow around the wing profile. To reproduce its effect, a gust generator has been installed in the contraction section of the S3Ch transonic wind tunnel at the ONERA Meudon center. The present study first introduces the gust generator used in this wind tunnel experiment. It is composed of two wings located upstream of the model. The two wings oscillate, hence creating vortices that will be carried by the flow stream to the model. Then, the effects of the gust are described, in both subsonic and transonic (up to Mach 0.82), on the aerodynamics and the aeroelastic response of a heavy instrumented (accelerometers, pressure sensors, strain gages) half wing fuselage model. In addition, an optical methodology gives access to deformation measurements of the model, thus giving a global picture of the phenomenon. Finally, a gust load alleviation methodology based on an active feedback loop is presented. A real-time device has been used and linked to a movable aileron of the model. A control algorithm based on several input sensors is implemented in the real-time device to decrease the effects of the gust load on the structural dynamics of the model. The results of this active control experiment will be discussed.