A multicopter includes: a support; rotors supported by the support; an electrical equipment that supplies power for rotationally driving the rotors; a circuitly that controls a flight of an airframe by individually adjusting a rotor speed of each of the rotors; and a cooling unit that cools the electrical equipment. The cooling unit includes a heat exchanger, a refrigerant circulating through the heat exchanger and the electrical equipment, and a pump that circulates the refrigerant.

An exemplary embodiment of the present disclosure provides a modular and reconfigurable aircraft including a first aircraft module, a second aircraft module, a plurality of connectors, and a coupler. The first aircraft module can include a polyhedral cage structure, a propeller disposed in an interior of the polyhedral cage structure, and a motor disposed in the interior of the polyhedral cage structure and configured to drive the propeller. The second aircraft module can include a polyhedral cage structure, a propeller disposed in the interior of the polyhedral cage structure, and a motor disposed in the interior of the polyhedral cage structure and configured to drive the propeller, a plurality of connectors configured to couple the polyhedral cage structure of the first aircraft module to the polyhedral cage structure of the second aircraft module.

An exemplary embodiment of the present disclosure provides a modular and reconfigurable aircraft including a first aircraft module, a second aircraft module, a plurality of connectors, and a coupler. The first aircraft module can include a polyhedral cage structure, a propeller disposed in an interior of the polyhedral cage structure, and a motor disposed in the interior of the polyhedral cage structure and configured to drive the propeller. The second aircraft module can include a polyhedral cage structure, a propeller disposed in the interior of the polyhedral cage structure, and a motor disposed in the interior of the polyhedral cage structure and configured to drive the propeller, a plurality of connectors configured to couple the polyhedral cage structure of the first aircraft module to the polyhedral cage structure of the second aircraft module.

The present invention relates to a protective foldable cage (100) adapted to flying drones. It comprises several ribs linked at their extremities by a ring and comprising on their length several connexion points allowing strings to join each of the adjacent ribs. The length of the string corresponds to the maximal angular shift between the first and the last ribs. The protective cage further comprises easily removable locking means adapted to maintain the ribs at predetermined relative angular position once deployed. The resent invention further relates to a system comprising such a protective cage and a drone support, as well as a method of protection of flying drones.

The present invention relates to a protective foldable cage (100) adapted to flying drones. It comprises several ribs linked at their extremities by a ring and comprising on their length several connexion points allowing strings to join each of the adjacent ribs. The length of the string corresponds to the maximal angular shift between the first and the last ribs. The protective cage further comprises easily removable locking means adapted to maintain the ribs at predetermined relative angular position once deployed. The resent invention further relates to a system comprising such a protective cage and a drone support, as well as a method of protection of flying drones.

Provided herein are systems and methods for an unmanned aerial vehicle (UAV) to skid and roll along an environmental surface. A rollable UAV includes an airframe assembly, a propulsion system, and a logic device configured to communicate with the propulsion system. The airframe assembly includes a cylindrical rolling guard configured to allow the UAV to roll along an environmental surface in contact with the cylindrical rolling guard. The logic device is configured to determine a rolling orientation for the UAV corresponding to the environmental surface, maneuver the UAV to place the cylindrical rolling guard of the airframe assembly in contact with the environmental surface, and roll the airframe assembly of the UAV along the environmental surface at approximately the determined rolling orientation while the cylindrical rolling guard is in contact with the environmental surface.

Provided herein are systems and methods for an unmanned aerial vehicle (UAV) to skid and roll along an environmental surface. A rollable UAV includes an airframe assembly, a propulsion system, and a logic device configured to communicate with the propulsion system. The airframe assembly includes a cylindrical rolling guard configured to allow the UAV to roll along an environmental surface in contact with the cylindrical rolling guard. The logic device is configured to determine a rolling orientation for the UAV corresponding to the environmental surface, maneuver the UAV to place the cylindrical rolling guard of the airframe assembly in contact with the environmental surface, and roll the airframe assembly of the UAV along the environmental surface at approximately the determined rolling orientation while the cylindrical rolling guard is in contact with the environmental surface.

Systems, devices, and methods for stopping the rotation of propellers used in unmanned aerial vehicles (UAV) such as drones are disclosed. The propellers are stopped in response to detecting when beams of light adjacent the propellers are blocked.

A multicopter is provided with: a support; multiple rotors provided to the support; an engine which is provided to the support and capable of varying the output thereof; an electric generator which is supported by the support and generates electricity by being driven by the engine; a capacitor which is provided to the support; multiple motors which are provided to the support, which are configured to be capable of supplying electricity from the electric generator and the capacitor, and which drive the multiple rotors respectively; a flight controller which controls the attitude of the multicopter main body by adjusting the revolving speeds of the respective rotors; and a power plant controller which controls the electric power to be generated by controlling both the engine and the electric generator in accordance with a control instruction given by the flight controller.

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.