The illustrative examples provide a slat movement system for use in an aircraft. An aircraft comprises a wing having a fixed edge and a wing front spar, and a moveable slat connected to the wing by a four bar linkage and a slat arm, the slat arm movable along a track comprising a slot terminating prior to the wing front spar.

The illustrative examples provide a slat movement system for use in an aircraft. An aircraft comprises a wing having a fixed edge and a wing front spar, and a moveable slat connected to the wing by a four bar linkage and a slat arm, the slat arm movable along a track comprising a slot terminating prior to the wing front spar.

Flaperon actuation systems for aircraft are disclosed herein. An example aircraft includes a wing including, a fixed wing portion, a flaperon, and an actuation system. The actuation system includes a first actuator coupled to the fixed wing portion. The first actuator is operable to move the flaperon along a first degree of freedom between a stowed position in which the flaperon is aligned with the fixed wing portion and a deployed position in which the flaperon is moved downward relative to the fixed wing portion. The actuation system also includes a linkage assembly coupled between the fixed wing portion and the flaperon. The linkage assembly includes a second actuator operable to move the flaperon along a second degree of freedom to pitch the flaperon between an upward position and a downward position.

Flaperon actuation systems for aircraft are disclosed herein. An example aircraft includes a wing including, a fixed wing portion, a flaperon, and an actuation system. The actuation system includes a first actuator coupled to the fixed wing portion. The first actuator is operable to move the flaperon along a first degree of freedom between a stowed position in which the flaperon is aligned with the fixed wing portion and a deployed position in which the flaperon is moved downward relative to the fixed wing portion. The actuation system also includes a linkage assembly coupled between the fixed wing portion and the flaperon. The linkage assembly includes a second actuator operable to move the flaperon along a second degree of freedom to pitch the flaperon between an upward position and a downward position.

Multi-functional trailing edge apparatus and methods for aircraft are disclosed herein. An example wing of an aircraft disclosed herein includes an aft edge supporting a trailing edge device. The trailing edge device has a control surface and a side surface. A linkage is rotatably coupled to the side surface and the aft edge, and a rotary actuator is operatively coupled to the linkage to move the control surface.

A rudder apparatus designed to significantly reduce drag near a centerline of a watercraft or aerial vehicle in which it is attached and to significantly increase a turning efficiency of the watercraft or aerial vehicle in which it is attached.

A high-lift trailing edge flap system for an aircraft wing unit is provided. In high-lift trailing edge flap system, the backward movement and the inclination of the trailing edge flap in the extended position are dissociated in order to allow for the incorporation of the actuating mechanism into the wing in the stowed position.

A high-lift trailing edge flap system for an aircraft wing unit is provided. In high-lift trailing edge flap system, the backward movement and the inclination of the trailing edge flap in the extended position are dissociated in order to allow for the incorporation of the actuating mechanism into the wing in the stowed position.

Multi-functional trailing edge apparatus and methods for aircraft are disclosed herein. An example wing of an aircraft disclosed herein includes an aft edge supporting a trailing edge device. The trailing edge device has a control surface and a side surface. A linkage is rotatably coupled to the side surface and the aft edge, and a rotary actuator is operatively coupled to the linkage to move the control surface.

We describe a propeller-thrust-governing system (PTGS) for a propeller that is part of an aircraft. The PTGS includes one or more control surfaces that are located within an airflow of the propeller. The control surfaces are adjustable to reduce thrust produced by the propeller and are also adjustable to redirect the thrust.