Various embodiments include methods, devices, and systems of transporting a payload using a robotic vehicle. The methods may determine whether a payload has separated from the robotic vehicle and take a corrective action in response to determining that the payload is not securely held by the robotic vehicle.

The present disclosure is directed to systems and methods too of implementing a hybrid robotic system capable of reversibly transitioning producing propulsion units may be coupled to the payload platform. In a first position, the payload platform may be positioned such that the thrust-producing propulsion units generate a substantially horizontal thrust to provide horizontal movement of the robotic system. In a second position, the payload platform may be positioned such that the thrust-producing propulsion units generate a substantially vertical thrust to provide vertical movement of the robotic system.

The present disclosure is directed to systems and methods too of implementing a hybrid robotic system capable of reversibly transitioning producing propulsion units may be coupled to the payload platform. In a first position, the payload platform may be positioned such that the thrust-producing propulsion units generate a substantially horizontal thrust to provide horizontal movement of the robotic system. In a second position, the payload platform may be positioned such that the thrust-producing propulsion units generate a substantially vertical thrust to provide vertical movement of the robotic system.

[Object] To provide a flying vehicle in which a working unit can be brought close to an appropriate distance from a work target. [Solution] The flying vehicle according to the present disclosure includes a flying part having a plurality of rotary blades for generating thrust, a leg part, an arm part connecting the flying part and the leg part, and a fixed wing part provided at substantially the center of the arm part. The flying body further includes a mounting part installed to be movable between the first position of the arm part and the second position located behind the first position.

An aircraft includes a fuselage having a longitudinal axis, a wing assembly, and a fuselage positioning mechanism operatively connecting the fuselage to the wing assembly. The fuselage positioning mechanism is operable to move the fuselage relative to the wing assembly in a longitudinal direction parallel to the longitudinal axis between a fuselage maximum forward position and a fuselage maximum aft position. When the aircraft for flight, a position of a center of gravity of the aircraft relative to a center of lift is determined. The fuselage can be moved relative to the wing assembly to bring the center of gravity within an allowable range of distances from the center of lift to balance the aircraft for flight. The fuselage positioning mechanism can be automated to allow adjustment of the fuselage position during the flight of the aircraft.

The Lopsided Payload Carriage Gimbal in al its embodiments allow Aerial Vehicles and Water-borne vehicles to carry payloads far from the vehicle Geometric Center without significant travel of the vehicle's overall Center of Gravity. Large travel of the CG limits vehicle's performance or renders it inoperable. The embodiments rely on the interaction of the payload and the counter balancing weight through the payload link 18, balancing link 10 main link 14 and battery pylon 8 to substantially reduce the torque generated by the payload in a lopsided position. The embodiments also allow the vehicle carrying the payload to change thrust direction agilely. Finally, the embodiment acts as a mechanical stabilization device for the payload as well. This invention is adaptable to all forms of hover-capable aerial vehicles as well as water-borne vehicles.

An adjustment device for adjusting the position of the center of gravity of an aircraft, the aircraft having at least two thrust production units that contribute at least to providing the aircraft with lift, the adjustment device comprising at least one heavy member that is movable relative to an airframe of the aircraft and also at least one actuator for causing the heavy member to move. The adjustment device includes an avionics system configured to detect a failure of any one of the thrust production units and, in the presence of such a failure, to control the at least one actuator to cause the heavy member to move.

A load control method and device based on a UAV, and a UVA. The UVA includes: a UVA body, a propeller arm with a first end connected to the UVA body, a propeller blade connected to a second end of the propeller arm and a processor installed in the UVA body; a length of the propeller arm and a size of the propeller blade are adjustable. The control method includes: determining load gravity of the UVA based on a carrying object of the UVA; determining a target lift of the UVA based on the load gravity; determining a target size of the propeller blade and a target length of the propeller arm based on the target lift; and adjusting the propeller arm to the target length and the propeller blade to the target size, so that the UVA controls the propeller blade to rotate to carry the carrying object.

An aeronautical vehicle that rights itself from an inverted state to an upright state has a self-righting frame assembly has a protrusion extending upwardly from a central vertical axis. The protrusion provides an initial instability to begin a self-righting process when the aeronautical vehicle is inverted on a surface. A propulsion system, such as rotor driven by a motor can be mounted in a central void of the self-righting frame assembly and oriented to provide a lifting force. A power supply is mounted in the central void of the self-righting frame assembly and operationally connected to the at least one rotor for rotatably powering the rotor. An electronics assembly is also mounted in the central void of the self-righting frame for receiving remote control commands and is communicatively interconnected to the power supply for remotely controlling the aeronautical vehicle to take off, to fly, and to land on a surface.

The present invention provides a pod (100) for an aircraft (1000), comprising: a housing (1); a unit (2) comprising a propulsion system, the unit comprising at least one attachment point (5) for coupling the unit to the housing (1), wherein the position of the unit relative to the housing is selected from a plurality of positions based on the centre of gravity of the aircraft, such that deflection of control surfaces required for the aircraft to maintain a constant angle of attack is minimised. The invention also provides an aircraft (1000) having the pod (100) and a method of balancing the aircraft (1000).