A helicopter uses electric propeller torque arm as power source directly driving main rotor to rotate. The helicopter may be battery powered. The helicopter may be without an engine, a clutch, a reducer, a tail driver, a tail boom, a tail rotor and a fuel supply system. The main design goal is to have the output shaft of the high-energy motor being coaxial with the main rotor shaft or having output shafts of a plurality of motors as close as possible to the main rotor shaft. The centrifugal force of the motor(s) is negligible or minimized. The torque arm assembly includes a plurality of torque arms. Each of the torque arm of the plurality of torque arms includes a propeller and a driving system. In the case of a malfunction, the helicopter's main rotor will spin like a maple leaf and will facilitate the spin autorotation landing.

Provided is a quiet redundant urban rotorcraft, commonly known as urban air mobility eVTOL. The quiet redundant urban rotorcraft is designed to perform vertical takeoff and landings powered by two independent electric lifting motors. The lifting force is distributed among counter-rotating, co-axial main multi-bladed rotors and several smaller rotors distributed around the vehicle which provide attitude control during hover and low speed flight. The quiet redundant urban rotorcraft is capable to fly at relatively high horizontal speed by using a dedicated horizontal thrust propeller driven by an electric motor, turbine or internal combustion engine. In high speed flight, the main rotors turn freely, the control electric motors turn off and the attitude control is provided by aerodynamic fixed and moving surfaces. The quiet redundant urban rotorcraft has a low noise footprint and multiple redundancy for safety, while at the same time having a compact configuration for operating area restrictions.

An embodiment includes a system for controlling blade pitch in a rotorcraft having an engine; a drive shaft with a first end and a second end and connected at the first end to the engine; a rotor with two or more blades connected to the second end of the drive shaft; and one or more actuators positioned adjacent to the rotor blades operable to change a blade pitch of the rotor blades.

A system for providing a flying craft is disclosed. The craft may include gyroscopes for stability, and rotor blades and/or chambers of lighter-than-air gasses for lift. The craft may be equipped with payloads such as lights, water delivery devices, speaker, wireless power systems and other payloads.

The invention relates to an autogyro having a rotor (12). According to the invention, a gas pressure spring (32) is provided and is arranged for trimming the rotor (12).

A helicopter has a helicopter body with a longitudinal axis and a rotor head which is driven via the rotor drive axis. The helicopter further has at least two rotor blades held via one rotor blade shaft each. In order to permit higher speeds, a rotor bearing axis of the rotor blade shafts is adjustable perpendicular to a direction of extent of the rotor bearing axis in relation to the rotor drive axis.

An adaptive flight control system for controlling the pitch of blades of a propulsive propeller of a hybrid helicopter as a function of the return value of the pitch. The adaptive flight control system comprises control means supplying the pitch control order, a piloting member controlling variation of the pitch, and piloting means applying a control gain in order to transform the control order into a setpoint, and transmitting the setpoint to the piloting member. The piloting means include information return means applying a return gain that is variable to the return value of the variation of the pitch to the piloting means, also modifying the control gain as a function of the return value.

A fan-in-wing aerial vehicle according to an embodiment may comprise: a fuselage; main wings expending from both sides of the fuselage in the span direction; rotors rotatably mounted inside the main wings, respectively; and opening/closing portions installed on the main wings such that the same can be opened/closed and thereby expose the rotors to the outside or conceal the rotors from the outside, respectively.

A rotor hub assembly includes an open rotor hub assembly with an open rotor hub and a mounting plate. The open rotor hub includes an annular base portion with periphery and a plurality of rotary member portions arranged about the annular base portion that each define an aperture for receiving a rotor blade. The mounting plate spans the annular base portion and is coupled to the annular base portion by a resilient member to accommodate radially expansion and contraction of the annular base portion according to loads exerted on the rotor hub by rotor blades seated in the apertures of the rotary member portions.

An unmanned aircraft system has a vertical takeoff and landing flight mode and a forward flight mode. The unmanned aircraft system includes an airframe, a rotor assembly rotatably coupled to the airframe and a propeller rotatably coupled to the airframe. The rotor assembly including at least two rotor blades having tip jets that are operably associated with a compressed gas power system. The propeller is operably associated with an electric power system. In the vertical takeoff and landing flight mode, compressed gas from the compressed gas power system is discharged through the tip jets to rotate the rotor assembly and generate vertical lift. In the forward flight mode, the electric power system drives the propeller to generate forward thrust and autorotation of the rotor assembly generates vertical lift.