aeroelastic tailoring
Aeroelastic tailoring is defined as "the embodiment of directional stiffness into an aircraft structural design to control aeroelastic deformation, static or dynamic, in such a fashion as to affect the aerodynamic and structural performance of that aircraft in a beneficial way",Shirk, M., Hertz, T., Weisshaar, T., "Aeroelastic Tailoring – Theory, Practice, Promise", Journal of Aircraft, Vol. 23, No. 1, pp. 6-18, 1986. or "passive aeroelastic control".Weisshaar, T., Aircraft Aeroelastic Design and Analysis, 1995 Objectives associated with aeroelastic tailoring include weight minimization, flutter, divergence, stress, roll reversal, control effectiveness, lift, drag, skin buckling, and fatigue.{{cite web |last1=Jutte |first1=Christine |last2=Stanford |first2=Bret K. |title=Aeroelastic Tailoring of Transport Aircraft Wings: State-of-the-Art and Potential Enabling Technologies |url=https://ntrs.nasa.gov/citations/20140006404 |access-date=19 December 2021 |language=en |date=1 April 2014}} {{PD-notice}}
History
According to Shirk et al., the first record of aeroelastic tailoring is from 1949 by Munk,Munk, M., "Propeller Containing Diagonally Disposed Fibrous Material," U.S. Patent 2,484,308,1111, Oct. 1949. who oriented the grain of his wooden propeller blade to create desirable deformation couplings when operated. In the late 1960s, there was a thrust in aeroelastic tailoring research, which has continued fairly steadily through to today. The forward swept wings of the X-29 and the Active Aeroelastic Wing are two aeroelastic tailoring examples highlighted by Weisshaar. Today the use of composite materials is becoming more prevalent in transport aircraft, including the Boeing 787, the Airbus A380, and the upcoming Airbus A350. Enhanced fabrication processes for composite laminates offer new design possibilities that have not been fully exploited for optimal aeroelastic performance and weight savings.