A variable area fan nozzle actuation (VAFN) system is disclosed. The VAFN system may include an electrohydrostatic actuator (EHA) arranged to translate a VAFN panel relative to a translating sleeve. An electrical coupling may extend between a translating sleeve associated with the VAFN system and the fixed structure. The electrical coupling may be movable so that as the translating sleeve and fixed structure move relative to each other, power may be provided to the EHA by a wiring harness extending across the space between the translating sleeve and the fixed structure and connecting the EHA to an EHA power source.

A variable area fan nozzle actuation (VAFN) system is disclosed. The VAFN system may include an electrohydrostatic actuator (EHA) arranged to translate a VAFN panel relative to a translating sleeve. An electrical coupling may extend between a translating sleeve associated with the VAFN system and the fixed structure. The electrical coupling may be movable so that as the translating sleeve and fixed structure move relative to each other, power may be provided to the EHA by a wiring harness extending across the space between the translating sleeve and the fixed structure and connecting the EHA to an EHA power source.

There is disclosed a linear actuator comprising: a screw shaft comprising a screw thread and having a longitudinal axis A; a nut movable along the screw shaft from a retracted position to an extended position; and a plurality of rollers movable with the nut, each comprising a cylindrical surface configured to roll along one or more flanks of the screw thread, such that rotation of the screw shaft causes the rollers to roll along the flank(s) so that the nut translates in an axial direction along the screw shaft; wherein the screw thread comprises one or more detents (e.g., grooves) configured to lock the nut in one or more axial positions.

A chine spoiler system enhances aircraft wing stall recovery characteristics while optimizing a maximum lift coefficient (CLMAX) of an aft-swept wing on an aircraft having an engine nacelle mounted below the wing. The system includes a chine located on a surface of the nacelle; the chine is configured to generate a vortex at high angles of attack. The vortex passes over an upper surface of the wing, favorably influencing inboard wing aerodynamics to delay airflow separation from the wing, in advance of a stall. The vortex increases CLMAX, but also creates a nose-up pitching moment on an aft-swept wing, which degrades stall recovery. A chine spoiler system module is configured to render the chine ineffective at predetermined wing flap configurations and angles of attack (typically post CLMAX) to balance the objectives of achieving high pre-stall CLMAX, while providing a nose-down pitching moment increment for improved stall recovery.

A chine spoiler system enhances aircraft wing stall recovery characteristics while optimizing a maximum lift coefficient (CLMAX) of an aft-swept wing on an aircraft having an engine nacelle mounted below the wing. The system includes a chine located on a surface of the nacelle; the chine is configured to generate a vortex at high angles of attack. The vortex passes over an upper surface of the wing, favorably influencing inboard wing aerodynamics to delay airflow separation from the wing, in advance of a stall. The vortex increases CLMAX, but also creates a nose-up pitching moment on an aft-swept wing, which degrades stall recovery. A chine spoiler system module is configured to render the chine ineffective at predetermined wing flap configurations and angles of attack (typically post CLMAX) to balance the objectives of achieving high pre-stall CLMAX, while providing a nose-down pitching moment increment for improved stall recovery.

Refueling devices for use in in-flight refueling operation are provided, including a body configured for being towed by a tanker aircraft and having a boom member that has a fuel delivery nozzle, a spatial control system and a longitudinal control system. The longitudinal displacement control system includes at least one panel element defining a front panel projected area orthogonal to a body longitudinal axis, each panel element being controllably and reversibly deployable incrementally to each one of a plurality of successive deployed positions between a fully retracted position and a fully deployed position, to provide a respective reversible incrementally increasing aft force to the refueling device at least during the in-flight refueling operation.

A system comprising an aerial vehicle or an unmanned aerial vehicle (UAV) configured to control pitch, roll, and/or yaw via airfoils having resiliently mounted trailing edges opposed by fuselage-house deflecting actuator horns. Embodiments include one or more rudder elements which may be rotatably attached and actuated by an effector member disposed within the fuselage housing and extendible in part to engage the one or more rudder elements.

A system comprising an aerial vehicle or an unmanned aerial vehicle (UAV) configured to control pitch, roll, and/or yaw via airfoils having resiliently mounted trailing edges opposed by fuselage-house deflecting actuator horns. Embodiments include one or more rudder elements which may be rotatably attached and actuated by an effector member disposed within the fuselage housing and extendible in part to engage the one or more rudder elements.

An aircraft nose gear-mounted flight control device promotes aircraft stability during low-speed phases of flight, including take-offs and landings. The flight control device is an operable airfoil secured to an aircraft nose gear, either to a vertical support strut or to a wheel axle thereof. The airfoil is deployed when the nose gear is deployed, and is retracted when the nose gear is retracted. Upon deployment, the airfoil is effective to at least provide aircraft pitch control. In some configurations, the airfoil deploys as two separate but mirror-imaged left and right airfoil components that move in concert to provide pitch control. In other configurations, the airfoil components move at relatively different angular rates and amounts to provide both pitch and roll control. The entire airfoil may be pivotal for pitch control, or may instead be fixed, but have moveable flaps or flap-like portions that provide pitch control.

An aircraft nose gear-mounted flight control device promotes aircraft stability during low-speed phases of flight, including take-offs and landings. The flight control device is an operable airfoil secured to an aircraft nose gear, either to a vertical support strut or to a wheel axle thereof. The airfoil is deployed when the nose gear is deployed, and is retracted when the nose gear is retracted. Upon deployment, the airfoil is effective to at least provide aircraft pitch control. In some configurations, the airfoil deploys as two separate but mirror-imaged left and right airfoil components that move in concert to provide pitch control. In other configurations, the airfoil components move at relatively different angular rates and amounts to provide both pitch and roll control. The entire airfoil may be pivotal for pitch control, or may instead be fixed, but have moveable flaps or flap-like portions that provide pitch control.