Introduction to UAV Systems. Mohammad H. Sadraey

Introduction to UAV Systems - Mohammad H. Sadraey


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aircraft performance analysis relies heavily on the calculation accuracy of friction drag (i.e., CDo). The CDo of an aircraft is simply the summation of CDo of all contributing components:

      Reference [12] provides a build‐up technique to calculate the contribution of each component to CDo of an aircraft. The majority of the equations are based on flight test data and wind tunnel test experiments, so the technique is mainly relying on empirical formulas.

      The total resistance to the motion of a subsonic air‐vehicle wing is made up of two components: the drag due to lift (induced drag) and the profile drag, which in turn is composed of the friction drag and the pressure drag (due to flow separation). For the overall air vehicle, the drag of all the non‐lift parts (e.g., fuselage, landing gear, and payload) are lumped together and called parasite (or parasitic) drag. If the various drag components are expressed in terms of drag coefficients, then simply multiplying their sum by the dynamic pressure (q) and a characteristic area (usually the wing area, S) results in the total drag:

      (3.14)upper D equals one half rho upper V squared upper S left-parenthesis upper C Subscript upper D o Baseline plus upper C Subscript upper D i Baseline right-parenthesis

      The ScanEagle UAV – developed by Boing Insitu – is composed of four field‐replaceable major modules/components: (1) nose (including payload sensors), (2) fuselage, (3) Wing, and (4) prop‐driven engine. The UAV has a cylindrical fuselage of 2 m long with a mid‐mounted swept‐back wing with winglets, endplate vertical tail and movable rudders. The nose carries a pitot tube, which is fitted with an anti‐precipitation system for cold weather operation. The air vehicle is fitted with a pusher piston engine (0.97 kW) with a two‐blade propeller. All of these external components contribute to the total vehicle drag.

      Moreover, the internal components include avionics, autopilot, communication system, fuel system, and mechanical/electric systems. The nose houses a gimballed and inertially stabilized turret which is fitted with EO/IR cameras. The air vehicle is not fitted with landing gear. The vehicle carries a maximum of 4.3 kg of fuel.

      There is interest in UAVs that use flapping wings to fly like a bird. The details of the physics and aerodynamics of flight using flapping wings are beyond our scope, but the basic aerodynamics can be appreciated based on the same mechanisms for generating aerodynamic forces that we have outlined for fixed wings. The following discussion is based largely on Nature’s Flyers: Birds, Insects, and the Biomechanics of Flight [13].

Schematic illustration of flight of a bird.

      The velocity and force triangles vary along the length of the wing because w is approximately zero at the root of the wing, where it joins the body of the bird and has a maximum value at the tip of the wing, so that the net force, F, is nearly vertical at the root of the wing and tilted furthest forward at the tip. As a result, it sometimes is said that the root of the bird’s wing produces mostly lift and the tip produces mostly thrust. This is dissimilar to a fixed‐wing air vehicle, where the lift at the wingtip is almost zero, while at the wing root, it is often the maximum.

      It is also possible for the bird to introduce a variable twist in the wing over its length, which could maintain the same angle of attack as w increases and the relative wind becomes tilted more upward near the tip. This twist can also be used to create an optimum angle of attack that varies over the length of the wing. This can be used to increase the thrust available from the wing tip.


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