Abstract
Morphing technology offers a strategy to modify the wing geometry, and the wing planform and cross-sectional parameters can be optimised to the flight conditions. This paper presents an investigation into the effect of span and camber morphing on the mission performance of a 25-kg UAV, with a straight, rectangular, unswept wing. The wing is optimised over two velocities for various fixed wing and morphing wing strategies, where the objective is to maximise aerodynamic efficiency or range. The investigation analyses the effect of the low and high speed velocity selected, the weighting of the low and high velocity on the computation of the mission parameter, the maximum allowable span retraction and the weight penalty on the mission performance. Models that represent the adaptive aspect ratio (AdAR) span morphing concept and the fish bone active camber (FishBAC) camber morphing concept are used to investigate the effect on the wing parameters. The results indicate that generally morphing for both span and camber, the aerodynamic efficiency is maximised for a 30%–70% to 40%–60% weighting between the low and high speed flight conditions, respectively. The span morphing strategy with optimised fixed camber at the root can deliver up to 25% improvement in the aerodynamic efficiency over a fixed camber and span, for an allowable 50% retraction with a velocity range of 50–115 kph. Reducing the allowable retraction to 25% reduces the improvement to 8%–10% for a 50%–50% mission weighting. Camber morphing offers a maximum of 4.5% improvement approximately for a velocity range of 50–90 kph. Improvements in the efficiency achieved through camber morphing are more sensitive to the velocity range in the mission, generally decreasing rapidly by reducing or increasing the velocity range, where span morphing appears more robust for an increase in velocity range beyond the optimum. However, where span morphing requires considerable modification to the planform, the camber change required for optimum performance is only a 5% trailing edge tip deflection relative to cross-sectional chord length. Span morphing, at the optimal mission velocity range, with 25% allowable retraction, can allow up to a 12% increase in mass before no performance advantage is observed, where the camber morphing only allows up to 3%. This provides the designer with a mass budget that must be achieved for morphing to be viable to increase the mission performance.
Highlights
Aircraft missions typically involve a number of phases, with varying operating conditions and a variety of requirements
A change of 2% in the tip deflection for the fish bone active camber (FishBAC) concept is a very manageable change, while a span reduction of 66% or an increase of 200% is far more difficult to achieve and impossible in a single-stage span morph with the proposed adaptive aspect ratio (AdAR) concept
These results show that the greater the range of mission speeds, using a 50–50 mission weighting from low to high speed, a larger allowable span retraction is required to maximise the performance potential
Summary
Aircraft missions typically involve a number of phases, with varying operating conditions and a variety of requirements. Where the mission flight phase requirements vary widely, such as flight conditions that lead to incompatible wing loading requirements for a fixed wing, generally, additional systems, so-called “secondary high lift” systems, are required to modify the wing for these flight phases. These generally lead to discontinuities in the structure and aerodynamic boundary, which can lead to losses in aerodynamic efficiency
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