An unmanned aerial vehicle includes at least one rotor motor configured to drive at least one propeller to rotate. The unmanned aerial vehicle includes a data center including a processor; a data storage component; and a wireless communications component. The unmanned aerial vehicle includes a hybrid generator system configured to provide power to the at least one rotor motor and to the data center, the hybrid generator system including a rechargeable battery configured to provide power to the at least one rotor motor; an engine configured to generate mechanical power; and a generator motor coupled to the engine and configured to generate electrical power from the mechanical power generated by the engine. The data center may include an intelligent data management module configured to control power distribution and execution of mission tasks in response to available power generation and mission task priorities.

An aircraft includes an electric power source having a combustion engine and an electric generator. The electric generator is powered by the combustion engine. The aircraft also includes a propulsion assembly including a propulsor and an electric motor, the electric motor configured for rotating the propulsor. The aircraft also includes an electrical outlet configured for connection with an outside power sink. The electrical outlet and the propulsion assembly are selectively in electrical communication with the electric power source such that the electric power source selectively provides electrical power to one of the electrical outlet or the propulsion assembly.

A vertical take-off and landing aircraft using a hybrid electric propulsion system includes an engine, a generator that produces electric power using power supplied by the engine, and a battery that stores the produced electric power. A motor receives the electric power stored in the battery and electric power produced by the generator but not stored in the battery and provides the power to a thrust generating apparatus. A controller selects either silence mode or normal mode, and determines the amount of electric power stored in the battery and the amount of electric power not stored in the battery from the electric power supplied to the motor. In the silence mode, the controller supplies only the electric power stored in the battery and controls a duration by adjusting output power of motor. In the normal mode, the controller supplies electric power not stored in the battery.

An aircraft has a bearing structure, the bearing structure having at least one central fuselage and two pylons each situated at a distance laterally from the fuselage. In addition, the aircraft has a wing structure, at least four hub rotors, and at least one thrust drive. Each hub rotor is fastened to the bearing structure, has a propeller having two propeller blades, and produces, through rotation of the propeller, an upward drive force acting in the vertical direction on the aircraft. The thrust drive is produces a thrust force acting in the horizontal direction on the bearing structure. The pylons each have two hub rotors, the hub rotors being configured to arrest respective propeller blades of a hub rotor in a position relative to the pylons. In the arrested position, the propeller blades of a hub rotor do not extend beyond the outer dimensions of the pylons.

The disclosure relates to a propeller drive that is, in particular, an aircraft drive and includes a propeller machine and an electric drive connected without a converter to the propeller machine. The aircraft includes such a propeller drive.

An engine-carrying flight device capable of stably hovering is provided. The engine-carrying flight device 10 can fly in a hovering state in which an altitude is maintained and in an ascending/descending state in which the altitude is changed. The engine-carrying flight device 10 includes main rotors 14, sub-rotors 15, an engine 26; motors 21; and an arithmetic control unit 25. The main rotors 14 are rotated by drive force received from the engine 26, the sub-rotors 15 are rotated by drive force received from the motors 21, and the arithmetic control unit 25 causes a thrust generated by rotation of the main rotors 14 to be smaller than a thrust necessary for keeping the altitude constant, in the hovering state.

An engine-carrying flight device capable of stably hovering is provided. The engine-carrying flight device 10 can fly in a hovering state in which an altitude is maintained and in an ascending/descending state in which the altitude is changed. The engine-carrying flight device 10 includes main rotors 14, sub-rotors 15, an engine 26; motors 21; and an arithmetic control unit 25. The main rotors 14 are rotated by drive force received from the engine 26, the sub-rotors 15 are rotated by drive force received from the motors 21, and the arithmetic control unit 25 causes a thrust generated by rotation of the main rotors 14 to be smaller than a thrust necessary for keeping the altitude constant, in the hovering state.

A vertical take-off and landing aircraft using a hybrid electric propulsion system includes an engine, a generator that produces electric power using power supplied by the engine, and a battery that stores the produced electric power. A motor receives the electric power stored in the battery and electric power produced by the generator but not stored in the battery and provides the power to a thrust generating apparatus. A controller selects either silence mode or normal mode, and determines the amount of electric power stored in the battery and the amount of electric power not stored in the battery from the electric power supplied to the motor. In the silence mode, the controller supplies only the electric power stored in the battery and controls a duration by adjusting output power of motor. In the normal mode, the controller supplies electric power not stored in the battery.

The flying object control device 1 includes a generator 2, a drive source 3, a battery 4, an electric motor 5, a battery status determination unit 8, and a state-of-charge control unit 11. The battery status determination unit 8 determines a first amount of charge power, which is a current state of charge of the battery. After a flying object starts cruising, the state-of-charge control unit 11 calculates a second amount of charge power, which is a state of charge of the battery 4 required for takeoff during the next flight, based on flight plans 53 and 54 of the flying object, predicts timing of supplying electric power from the generator 2 to the battery 4 based on the first amount of charge power and the second amount of charge power, and starts power supply from the generator 2 to the battery 4 at this timing.

A vertical take-off and landing aircraft using a hybrid electric propulsion system includes an engine, a generator that produces electric power using power supplied by the engine, and a battery that stores the produced electric power. A motor receives the electric power stored in the battery and electric power produced by the generator but not stored in the battery and provides the power to a thrust generating apparatus. A controller selects either silence mode or normal mode, and determines the amount of electric power stored in the battery and the amount of electric power not stored in the battery from the electric power supplied to the motor. In the silence mode, the controller supplies only the electric power stored in the battery and controls a duration by adjusting output power of motor. In the normal mode, the controller supplies electric power not stored in the battery.