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Macro-fiber composite actuators for a swept wing unmanned aircraft

Published online by Cambridge University Press:  03 February 2016

O. Bilgen
Affiliation:
onurb@vt.edu, Virginia Polytechnic Institute and State University, Blacksburg, USA
K. B. Kochersberger
Affiliation:
kbk@vt.edu
D. J. Inman
Affiliation:
dinman@vt.edu

Abstract

The purpose of the research presented here is to exploit actuation via smart materials to perform shape control of an aerofoil on a small aircraft and to determine the feasibility and advantages of smooth control surface deformations. A type of piezoceramic composite actuator known as Macro-Fiber Composite (MFC) is used for changing the camber of the wings. The MFC actuators were implemented on a 30° swept wing, 0·76m wingspan aircraft. The experimental vehicle was flown using two MFC patches in an elevator/aileron (elevon) configuration. Preliminary flight and wind-tunnel testing has demonstrated the stability and control of the concept. Flight tests were performed to quantify roll control using the MFC actuators. Lift and drag coefficients along with pitch and roll moment coefficients were measured in a low-speed, open-section wind tunnel. A vortex-lattice analysis complemented the database of aerodynamic derivatives used to analyse control response. The research, for the first time, successfully demonstrated that piezoceramic devices requiring high voltages can be effectively employed in small air vehicles without compromising the weight of the overall system.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2009 

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