When a first generator is stopped, an electric motor control section reduces the output power of a VTOL electric motor and a cruise electric motor that operate with electric power supplied from the first generator, and increases the output power of a VTOL electric motor and a cruise electric motor that operate with electric power supplied from a second generator.

When a difference in the SOC among respective batteries is greater than or equal to a first prescribed value, an electric motor control section reduces output power of a cruise electric motor that operates using electric power of a battery with a low SOC and increases output power of a cruise electric motor that operates using electric power of a battery with a high SOC.

An aircraft is disclosed. The aircraft includes a first pair of wings, each wing in the first pair of wings including one or more actuating flaps configured to move to facilitate the aircraft transitioning between a forward cruise mode and a vertical hover mode, and operating in one of the forward cruise mode or the vertical hover mode. The aircraft further includes a second pair of wings, and one or more propellers coupled to the second pair of wings and oriented horizontally to provide upward lift.

An aircraft includes: rotors each driven by an electric motor; a PCU that converts AC power output from a generator into DC power; an inverter that converts DC power supplied from the PCU into AC power and outputs the AC power to the electric motor; a DC wire that connects the PCU and the inverter; and an AC wire that connects the inverter and the electric motor. The AC wire is disposed in a direction orthogonal to a direction in which rotation shafts of the generator and a gas turbine extend.

A control system 70 includes: a VTOL rotor 20 and a cruise rotor 29 configured to generate a thrust; a power unit that has a power generation device 40a configured to generate power and supply the power to the rotors, and a battery 32 configured to store power which is supplied from the power generation device, and supply stored power to the rotors; and a control unit 91 configured to calculate a charging time of the battery based on a required amount of power storage that should be stored in the battery when the aircraft flies in a predetermined flight condition, and a state of the battery, and determine a charge start time of the battery based on the charging time and a flight time it takes to reach the predetermined flight condition. With this, it is possible to suppress a deterioration.

A ram chute assembly is provided for directing a flow of cooling air into a hollow wing structure of an aircraft. The ram chute assembly includes a ram chute body defining an interior passage, and an air inlet enabling an airflow from an exterior of the ram chute body into the interior passage. The assembly is structured to be attachable to an exterior of an engine nacelle so as to receive propeller wash air through the air inlet into the interior passage when a propeller of the engine nacelle is rotating. The ram chute assembly is also structured to discharge the propeller wash air in a direction toward an air intake opening formed in an upper surface of a hollow wing structure on which the engine nacelle is mounted.

A power supply apparatus includes: a traveling unit operated and caused to travel by electric power supplied from a first storage battery; a pad on which a vertical take-off and landing aircraft is placed; a power supply unit for supplying the aircraft with power output from the first storage battery; a movement plan recognition unit for recognizing a movement plan of the aircraft; a second storage battery state recognition unit for recognizing a state of a second storage battery provided in the aircraft; and a power supply control unit for controlling first power, which is supplied from the first storage battery to the traveling unit based on the movement plan and the state of the second storage battery, and second power, which is supplied from the first storage battery to the aircraft via the power supply unit.

A system for recharging an electric vehicle including a recharging component, wherein the recharging component is configured to supply power to an energy source of an electric vehicle, a sensor, wherein the sensor is configured to detect a plurality of data regarding the electric vehicle and generate an environment datum as a function of the plurality of data, a ventilation system, wherein the ventilation system is communicatively connected to the recharging component and a control pilot, wherein the control pilot is in electronic communication with the sensor, wherein the control pilot is configured to receive the environment datum from the sensor, generate a ventilation requirement datum as a function of the environment datum and command the ventilation system to perform a ventilation process as a function of the ventilation requirement datum.

The present invention relates to a control input device applicable to an eVTOL aircraft, which is an electric-powered vertical take-off and landing aircraft, and more particularly, to an aircraft control input device that may replace a cyclic control stick, a tail rotor control pedal, and a collective control stick used for flight control of a conventional aircraft, which is simpler in configuration and easier to operate than conventional control devices and may improve pilot convenience and stability of flight operation through simple and accurate flight manipulation, and a command input method using the same.

Method and system to ascertain location of drone box for landing and charging drones comprising at least a drone box having a drone platform with a plurality of limiting boundaries, divided into number of sensor zones that are mechanically contiguous and electrically separated by an insulated separator of insulation width, each sensor zone having an identification coordinates, each drone having a plurality of ground interfaces, each having a unique address code, each ground interface has a charging terminal at a far end, each charging terminal having an interlocked switchable electricity polarity. The identification coordinates of the activated sensor zones are communicable to a second drone so that the second drone knows where NOT to land on the drone box, Such communication enables a third and subsequent drone to ascertain whether the identified drone box is suitable and available for landing.