Abstract
Morphing aircraft are the flight vehicles that can reconfigure their shape during the flight in order to achieve superior flight performance. However, this promising technology poses cross-disciplinary challenges that encourage widespread design possibilities. This research aims to investigate the flight dynamic characteristics of various morphed wing configurations that can be incorporated in small-scale UAVs. The objective of this study was to analyze the effects of in-flight wing sweep and wingspan morphing on aerodynamic and flight stability characteristics. Longitudinal, lateral, and directional characteristics were evaluated using linearized equations of motion. An open-source code based on Vortex Lattice Method (VLM) assuming quasi-steady flow was used for this purpose. Trim points were identified for a range of angles of attack in prestall regime. The aerodynamic coefficients and flight stability derivatives were compared for the aforementioned morphing schemes with a fixed-wing counterpart. The results indicated that wingspan morphing is better than wing sweep morphing to harness better aerodynamic advantages with favorable flight stability characteristics. However, extension in wingspan beyond certain limits jeopardizes the advantages. Dynamically, wingspan and sweep morphing schemes behave in an exactly opposite way for longitudinal modes, whereas lateral-directional dynamics act in the same fashion for both morphing schemes. The current study provided a baseline to explore the advanced flight dynamic aspects of employed wing morphing schemes.
Highlights
Introduction e role of Unmanned AirVehicles (UAVs) in unconventional and asymmetric military roles as well as diversified civil environments is on the rise
Morphing aircraft are the flight vehicles that can reconfigure their shape during the flight in order to achieve superior flight performance. This promising technology poses cross-disciplinary challenges that encourage widespread design possibilities. is research aims to investigate the flight dynamic characteristics of various morphed wing configurations that can be incorporated in small-scale Unmanned AirVehicles (UAVs). e objective of this study was to analyze the effects of in-flight wing sweep and wingspan morphing on aerodynamic and flight stability characteristics
UAVs are designed to meet conflicting mission requirements with dynamic on-board reconfiguration capabilities. e conventional fixed-wing aircraft design puts severe flight limitations to operate in a diverse set of mission requisites
Summary
Stability Characteristics of Wing Span and Sweep Morphing for Small Unmanned Air Vehicle: A Mathematical Analysis. Is research aims to investigate the flight dynamic characteristics of various morphed wing configurations that can be incorporated in small-scale UAVs. e objective of this study was to analyze the effects of in-flight wing sweep and wingspan morphing on aerodynamic and flight stability characteristics. Ese are the most important morphing parameters that can greatly affect the aircraft’s flight dynamics Both wingspan and sweep angle can be adjusted to control the wing aspect ratio in order to modify lift-to-drag ratio, lift-curve slope, the inertia of the aircraft, and other forces depending on the wing area. The results are discussed in terms of trim conditions, static stability, and aircraft dynamic modes for both (variable wingspan and sweep angle) morphing schemes. The wings can be swept between 0° and
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