A method of delivering heavy payload using an autonomous UAV able to deliver supply by way of airdrop with more precision and at a lower cost. The UAV is equipped with two movable wing systems that rotate from a stowed position to a deployed position upon jettison of the UAV from a mothership. The UAV can be controlled remotely or it can operate autonomously and the movable wings can include ailerons to effectuate flight control of the UAV. The UAV can be reusable or can be an expendable UAV.

A drone with extendable and rotatable wings and a multiple accessory securing panel is provided. The extendable wings help increase the lift of the drone and reduce the air drag on the drone. The multiple accessory securing panel allows various tools and objects to be temporarily and selectively secured to the drone. The multiple accessories may be secured to the drone by a ground based rotating delivery unit. The drone may have a removable front nose and legs which receive power from a power unit.

A rotary wing vehicle includes a body structure having an elongated tubular backbone or core, and a counter-rotating coaxial rotor system having rotors with each rotor having a separate motor to drive the rotors about a common rotor axis of rotation. The rotor system is used to move the rotary wing vehicle in directional flight.

A vehicle comprising a morphing wing and a body is disclosed. The aircraft is configured to transform from a first configuration into a second configuration for ascent or descent of the aircraft. The drag force and lift force on the aircraft in the second configuration are less than in the first configuration. Transforming from the first to the second configuration comprises: contracting the wing within a geometric plane defined by the wing, and rotating the outer edge of the wing downwards, out of the geometric plane.

A method for realizing a vertical take-off and landing aircraft that does not use a mechanism dedicated for take-off and landing, which cannot be achieved on the basis of an existing concept of aircraft flight control, by introducing a new concept of a shoulder rotational axis and an arm rotational axis into aircraft flight control and controlling vertical take-off and landing and ordinary flight with the same mechanism. This instruction eliminates a necessity of a tail and ailerons from an airframe of the aircraft, enables reduction of manufacturing, maintenance, and running costs thereof, and makes it possible to avoid problems of maneuverability and cruising distance performance of airframes of vertical take-off and landing aircrafts.

An unmanned aerial vehicle is provided, including an airframe including a fuselage and at least one stowable wing. The unmanned aerial vehicle can further include a radar panel positioned on the fuselage such that the radar panel is angled downward and extends longitudinally along a ventral region of the fuselage. The unmanned aerial vehicle can further include a drop-away rocket engine that is configured to detachably mount to the airframe adjacent the radar panel.

An unmanned aerial vehicle is provided, including an airframe including a fuselage and at least one stowable wing. The unmanned aerial vehicle can further include a radar panel positioned on the fuselage such that the radar panel is angled downward and extends longitudinally along a ventral region of the fuselage. The unmanned aerial vehicle can further include a drop-away rocket engine that is configured to detachably mount to the airframe adjacent the radar panel.

A foldable wing with foldable trailing edge flap, that includes a main wing and a foldable trailing edge flap. The main wing includes a wing supporting skeleton and a plurality of skin supporting ribs. The foldable trailing edge flap includes a plurality of crank-shaped flap supporting ribs, a flexible flap skin, a connecting shaft, and a return spring. The plurality of crank-shaped flap supporting ribs are hinged with lower surfaces of corresponding plurality of skin supporting ribs through the connecting shaft to form a foldable trailing edge flap supporting skeleton that relies on the plurality of skin supporting ribs. The return spring makes an upper surface of a long side of each crank-shaped flap supporting rib attach closely to a lower surface of each skin supporting rib. The flexible flap skin is attached to an upper surface of the foldable trailing edge flap supporting skeleton.

A system and method for transformation of motor transportation vehicle for ground and air transport, motor transportation vehicle are disclosed. The motor transportation vehicle consists of the body with the cabin, the front and rear axles, an actuation system, wings, covers, and tail including the support and the tail surfaces, and for transformation of the motor transportation vehicle for air transport to the motor transportation vehicle for ground transport the following transformation steps are preformed: minimization of the wings footprint area by turning the wings around their horizontal axes, which axes run through the halves or near the halves of the wing widths; opening two body covers; turning the folded wings into the vertical position; turning the folded wings from the vertical position towards rear position around the horizontal axis perpendicular to the length of the motor transportation vehicle, followed by closing the body covers; tilting the support cover/covers out; retracting the support/supports of the tail surfaces under the opened support covers; closing the support cover/covers.

A water-air amphibious cross-medium bio-robotic flying fish includes a body, pitching pectoral fins, variable-structure pectoral fins, a caudal propulsion module, a sensor module and a controller. The caudal propulsion module is controlled to achieve underwater fish-like body-caudal fin (BCF) propulsion, and the variable-structure pectoral fins is adjusted to achieve air gliding and fast splash-down diving motions of the bio-robotic flying fish. The coordination between the caudal propulsion module and the pitching pectoral fins is controlled to achieve the motion of leaping out of water during water-air cross-medium transition. The ambient environment is detected by the sensor module, and the motion mode of the bio-robotic flying fish is controlled by the controller.