A thrust generator comprising: a motor (17), and a wing mounting (10), comprising a base (11) and a wing (2, 20), the base connected to the motor and configured to rotate the wing mounting about a stroke axis (13) within an angular stroke range, wherein the wing comprises a wing panel (24) having a first longitudinal edge (5) and a second longitudinal edge (6), the wing panel defining a wing surface (4) between the first and second longitudinal edges, and wherein the wing panel is configurable between: a first configuration in which the first longitudinal edge of the wing panel defines a leading edge and the second longitudinal edge of the wing panel defines a trailing edge; and a second configuration in which the second longitudinal edge of the wing panel defines a leading edge and the first longitudinal edge of the wing panel defines a trailing edge, the thrust generator being configured to rotate the wing mounting about the stroke axis in a first direction when the wing panel is in the first configuration and to rotate the base about the stroke axis in a second direction when the wing panel is in the second configuration.

A vertical takeoff and landing aircraft capable of six degree-of-freedom motion where lift, pitch, and roll are provided by multirotors oriented vertically, lateral translation is provided by a cyclorotor oriented vertically, and yaw is provided by a combination of the cyclorotor and the multirotors. The invention includes a frame, which supports the multirotors and cyclorotors. The frame also supports a payload and battery which are positioned at the extreme ends of the frame. The aircraft is capable of hovering precisely to position a payload close to or touching a target surface in the air.

A vertical takeoff and landing aircraft capable of six degree-of-freedom motion where lift, pitch, and roll are provided by multirotors oriented vertically, lateral translation is provided by a cyclorotor oriented vertically, and yaw is provided by a combination of the cyclorotor and the multirotors. The invention includes a frame, which supports the multirotors and cyclorotors. The frame also supports a payload and battery which are positioned at the extreme ends of the frame. The aircraft is capable of hovering precisely to position a payload close to or touching a target surface in the air.

Disclosed are embodiments of flow diverting lift elements which, when placed in the proper orientation and propelled through a fluid, produce a lift force with improved lift versus velocity performance. The flow diverting lift elements can produce lift for rotary lift devices such as aircraft. The flow diverting lift devices include an airfoil and a diversion wall extending from an upper surface of the airfoil. The airfoil can be an annular airfoil.

An unmanned vehicle having a launch configuration and one or more operational configurations. In the launch configuration, one or more engines resides within an engine bay. The unmanned vehicle is generally shaped like a projectile and can be launch from any tube-shaped deployment system using an initial propulsor. The engine bay can be opened, and the engines can be moved into a generally external position with respect to the engine bay for operation of said engines. In some embodiments, the one or more engines can pivot to direct thrust in multiple directions. In some embodiments, the unmanned vehicle includes flight control surfaces to further improve the flight characteristics of the vehicle.

The invention discloses a flying saucer aircraft, comprising a saucer body, a flying paddle, and landing brackets, wherein the middle of the egg-shaped saucer body is provided with an electromagnetic track with the central portion recessed inward, which is provided with an electromagnetic levitation vehicle; the flying paddle is connected to the outer surface of the vehicle, and can be driven by the vehicle to rotate; turbojet brackets are further provided on both sides of the egg-shaped saucer body; the turbojet bracket is connected with a turbojet; the landing brackets are arranged at the bottom of the egg-shaped saucer body. The aircraft can be used as a new aircraft for transportation, travel, exploration and other activities; the aircraft does not need a special runway for take-off and landing, it can take off and land vertically, and while flying in the air, the direction can be easily changed by the turbojet.

Apparatus for vertical or short takeoff and landing, and operational control during flight. In one embodiment, the apparatus includes a main body assembly, the main body assembly including: a fuselage, the fuselage includes one or more power motor assemblies and one or more actuator motor assemblies; a plurality of power mounting bodies and a plurality of power/articulation mounting bodies; a static rail that is operatively coupled with the plurality of power mounting bodies; a transient rail that is operatively coupled with the plurality of power/articulation bodies; and a plurality of airfoils, each of the plurality of airfoils being coupled to a respective power/articulation mounting body. Various sub-systems of the apparatus and methods of manufacture and use are also disclosed.

Apparatus for vertical or short takeoff and landing, and operational control during flight. In one embodiment, the apparatus includes a main body assembly, the main body assembly including: a fuselage, the fuselage includes one or more power motor assemblies and one or more actuator motor assemblies; a plurality of power mounting bodies and a plurality of power/articulation mounting bodies; a static rail that is operatively coupled with the plurality of power mounting bodies; a transient rail that is operatively coupled with the plurality of power/articulation bodies; and a plurality of airfoils, each of the plurality of airfoils being coupled to a respective power/articulation mounting body. Various sub-systems of the apparatus and methods of manufacture and use are also disclosed.

A foldable wing system for an unmanned aerial system having a fuselage includes a left wing frame having an inboard gear rotatably coupled to the fuselage, a right wing frame having an inboard gear rotatably coupled to the fuselage and a wing actuator coupled to a linkage point on at least one of the wing frames. The wing frames are movable between a plurality of positions including a deployed position and a stowed position. The inboard gear of the left wing frame is engaged with the inboard gear of the right wing frame such that the wing frames move symmetrically between the plurality of positions in response to movement of the linkage point by the wing actuator.

A manned or unmanned aircraft has a main body with a circular shape and a circular outer periphery. One or more rotor blades extend substantially horizontally outward from the main body at or about the circular outer periphery. In addition, one or more counter-rotation blades extend substantially horizontally outward from said main body at or about the circular outer periphery, but vertically offset from the main rotor blades. The rotor blades and counter-rotation blades can be folded upward into a storage position. In addition, the unmanned aircraft can have solar panels positioned about the top housing and fuselage of the aircraft.