The ‘Air Wheel’ rotor is a variable pitch rotor with variable twist blades. The ‘Air Wheel’ rotor comprises a closed wing coupled to one or more coaxial hubs via torsional elastic blades, the blades are coupled to the closed wing in one of the following ways: rigid, elastic, or visco-elastic. There is provided a wide range of combinations of the wing relative width and coning angle typical for a lifting rotor with a thin planar wing attached to the tips of long blades, for a shrouded fan in a wide annular wing, or for an impeller in a rotating cylindrical wing. The ‘Air Wheel’ rotor combines and enhances the advantages of a rotor and a wing, it has excellent aerodynamic characteristics, and eliminates limitations of the rotor size and flight speed. The ‘Air Wheel’ rotor can be used for designing vertical take-off and landing aircraft. The “Air Wheel” rotor is universal and can function as a lifting rotor, or a wind turbine, or an aircraft propeller, or a marine propeller.

A propulsion assembly includes a rotor assembly, a mast coupled to the rotor assembly and a bull gear coupled to the mast. The bull gear is subject to radial and axial loads. The propulsion assembly includes a flexured standpipe extending through the bull gear and a ball bearing including inner and outer races interposed between the bull gear and the flexured standpipe. The ball bearing is configured to absorb axial loads from the bull gear. The bull gear is rotatably coupled to the flexured standpipe via the ball bearing. The flexured standpipe flexes in response to radial loads from the bull gear.

A propulsion assembly includes a rotor assembly, a mast coupled to the rotor assembly and a bull gear coupled to the mast. The bull gear is subject to radial and axial loads. The propulsion assembly includes a flexured standpipe extending through the bull gear and a ball bearing including inner and outer races interposed between the bull gear and the flexured standpipe. The ball bearing is configured to absorb axial loads from the bull gear. The bull gear is rotatably coupled to the flexured standpipe via the ball bearing. The flexured standpipe flexes in response to radial loads from the bull gear.

The invention relates to an aerodyne with vertical take-off and landing ability and the ability to generate lift by means of both rotors and fixed wings, which includes: a fuselage (1); two fixed wings (2); two front rotors (11) and two rear rotors (12) arranged symmetrically and actuated by means of motors (13), each rotor (10) being attached to a central portion of a fixed wing (2) by means of a support (14) and connected pivotably about a connection shaft (E2), which allows changing the inclination of each rotor (10) from a longitudinal forward movement position, in which they propel the aerodyne horizontally, to a lift position in which it provides vertical lift; said rear rotors being in a lift position partially overlapping a portion of the wing including a flap (20) freely connected to the rest of the wing, the position thereof being determined between a lift position and a longitudinal forward movement position by the effect of the aerodynamic thrust.

The invention relates to an aerodyne with vertical take-off and landing ability and the ability to generate lift by means of both rotors and fixed wings, which includes: a fuselage (1); two fixed wings (2); two front rotors (11) and two rear rotors (12) arranged symmetrically and actuated by means of motors (13), each rotor (10) being attached to a central portion of a fixed wing (2) by means of a support (14) and connected pivotably about a connection shaft (E2), which allows changing the inclination of each rotor (10) from a longitudinal forward movement position, in which they propel the aerodyne horizontally, to a lift position in which it provides vertical lift; said rear rotors being in a lift position partially overlapping a portion of the wing including a flap (20) freely connected to the rest of the wing, the position thereof being determined between a lift position and a longitudinal forward movement position by the effect of the aerodynamic thrust.

A rotorcraft includes a main rotor system coupled to a mast and a rotor assembly. The rotor assembly includes a yoke comprising a rotor coupling, a first damper mount attached to the rotor coupling, a rotor extension configured to couple to the rotor coupling and comprising a second damper mount, a damper coupled to the first and second damper mounts, and a fairing enclosing the damper and the yoke.

An unmanned aerial vehicle having an airframe whose horizontal dimension is efficiently reduced. This object is solved by an unmanned aerial vehicle that includes: a rotor; an arm; and an arm connector. The arm connector includes an arm holder that is a fixing member holding a part of the arm in a longitudinal direction of the arm. The part of the arm held by the arm holder is changeable by sliding the arm in the longitudinal direction of the arm relative to the arm holder. The arm holder is a movable member movable in directions in which the arm is turned upward and downward and/or rightward and leftward. The object is also solved by an unmanned aerial vehicle that includes: a rotor; an arm; and an arm connector. The arm is provided with a hinge on which the arm is foldable at a middle portion of the arm.

An unmanned aerial vehicle having an airframe whose horizontal dimension is efficiently reduced. This object is solved by an unmanned aerial vehicle that includes: a rotor; an arm; and an arm connector. The arm connector includes an arm holder that is a fixing member holding a part of the arm in a longitudinal direction of the arm. The part of the arm held by the arm holder is changeable by sliding the arm in the longitudinal direction of the arm relative to the arm holder. The arm holder is a movable member movable in directions in which the arm is turned upward and downward and/or rightward and leftward. The object is also solved by an unmanned aerial vehicle that includes: a rotor; an arm; and an arm connector. The arm is provided with a hinge on which the arm is foldable at a middle portion of the arm.

A rotor blade control system and methods therefor including a hub assembly pivotally attached to a rotor blade; a mast attached to the hub assembly; a swashplate assembly engaged with the mast and including a swashplate actuation mechanism pivotally coupled with the non-rotating ring at a plurality of coupling locations for moving the non-rotating ring and pivotally coupled with the base at a plurality of base locations, the swashplate actuation mechanism comprises a plurality of substantially triangular dual actuator assemblies that are independently and concurrently operable to move the respective coupling location so as to impart movement on the non-rotating ring. The swashplate actuation mechanism is configured to move the swashplate assembly about a longitudinal axis and a lateral axis in response to a cyclic input. The swashplate actuation mechanism is configured to move the swashplate assembly along the mast in response to a collective input.

Rotor assembly apparatus are disclosed. An example rotor assembly includes a twist actuator to drive a first rotation of a first shaft about a first axis, the twist actuator positioned at a center of rotation of the rotor assembly. A first gear assembly to convert the first rotation into a plurality of second rotations of a plurality of second shafts. Each of the second shafts to provide torque to a respective blade coupled to the rotor assembly.