@article{f10b45e8abc04ce0ab8d63fb75592392,
title = "Dynamic modelling and actuation of the adaptive torsion wing",
abstract = "This article presents the dynamical modelling of a novel active aeroelastic structure. The adaptive torsion wing concept is a thin-wall, two-spar wingbox whose torsional stiffness can be adjusted by translating the spar webs in the chordwise direction inward and towards each other using internal actuators. The reduction in torsional stiffness allows external aerodynamic loads to induce twist on the structure and maintain its deformed shape. Here, the adaptive torsion wing system is considered as integrated within the wing of a representative unmanned aerial vehicle to replace conventional ailerons and provide roll control. The adaptive torsion wing is modelled as a two-dimensional equivalent aerofoil using bending and torsion shape functions to express the equations of motion in terms of the twist angle and plunge displacement at the wingtip. The full equations of motion for the adaptive torsion wing equivalent aerofoil were derived using Lagrangian mechanics. The aerodynamic lift and moment acting on the aerofoil were modelled using Theodorsen's unsteady aerodynamic theory. A low-dimensional, state-space representation of an empirical Theodorsen's transfer function was adopted to allow time-domain analyses. Four actuation strategies were investigated. Figures of merit, including plunge displacement, twist angle, actuation forces and actuation powers, were quantified and discussed for each of the scenarios. This study allows the conceptual design and sizing of the internal actuators that are required to drive the webs.",
keywords = "aeroelastic, Morphing, torsion, UAV, wing",
author = "Ajaj, \{Rafic M.\} and Friswell, \{Michael I.\} and Dettmer, \{Wulf G.\} and Giuliano Allegri and Isikveren, \{Askin T.\}",
note = "Funding Information: In Europe, the active aeroelastic aircraft structures (3AS) research project (; ; ; ), which involved a consortium of 15 European partners in the aerospace industry and was partially funded by the European Community, focused on developing AAS concepts through exploiting structural flexibility in a beneficial manner. The final aim was to improve the aircraft aerodynamic efficiency and flight control. One of the novel concepts proposed in the 3AS project was the all-moving vertical tail (AMVT) with a variable torsional stiffness attachment. The AMVT concept was employed to design a smaller and lighter fin while maintaining stability and rudder effectiveness for a wide range of airspeeds. The AMVT employs a single attachment whose position can be adjusted in the chordwise direction relative to the position of the centre of pressure to achieve an aeroelastic effectiveness above unity (). Furthermore, the 3AS project investigated a variety of variable stiffness attachments and mechanisms for the AMVT concept, including a pneumatic device developed at the University of Manchester (). took the AMVT a step forward and investigated the use of magnetorheological (MR) fluid cylinders to form a mechanical chain between the AMVT shaft and the actuator and control the torsional rigidity of the tail to provide the best mechanical response at different flight regimes. Funding Information: This study was funded by the European Research Council through Grant Number 247045 entitled {\textquoteleft}Optimisation of Multi-scale Structures with Applications to Morphing Aircraft{\textquoteright}.",
year = "2013",
month = nov,
doi = "10.1177/1045389X12444493",
language = "British English",
volume = "24",
pages = "2045--2057",
journal = "Journal of Intelligent Material Systems and Structures",
issn = "1045-389X",
publisher = "SAGE Publications Ltd",
number = "16",
}