A seal is disclosed for a wing for providing an aerodynamic seal between a fixed aerofoil and a movable control surface.

Provided are vertical tail structures with symmetry action slat systems. Specifically, a vertical tail structure comprises a main element and a leading edge element. The leading edge element comprises a first slat body and a second slat body that are symmetrically positioned on either side of a longitudinal centerline of the vertical tail structure. Each slat body is configured to move between a retracted position and an extended position to increase a camber sag of an airfoil of the vertical tail structure and thereby increase a maximum aerodynamic yawing moment provided by the vertical tail structure. In a first operable mode, each of the slat bodes are in the respective retracted position. In a second operable mode, one of the slat bodies is in the respective extended position. The extended position of each of the slat bodies includes a pitch angle and an extension distance from the main element.

Apparatus for improving flow characteristics around aircraft wings by obstructing air flow through an aperture formed in a wing skin for a movable duct or track are disclosed. In one embodiment, the apparatus comprises a substantially rigid panel movable at least partially across the aperture for at least partially occluding the aperture and for accommodating movement of a slat track extending through the aperture. In another embodiment, the apparatus comprises a hinged panel configured to swing outwardly from an outer side of the wing skin toward an open position to accommodate movement of an anti-icing duct extending through the aperture and to swing toward a closed position at least partially occluding the aperture.

Apparatus for improving flow characteristics around aircraft wings by obstructing air flow through an aperture formed in a wing skin for a movable duct or track are disclosed. In one embodiment, the apparatus comprises a substantially rigid panel movable at least partially across the aperture for at least partially occluding the aperture and for accommodating movement of a slat track extending through the aperture. In another embodiment, the apparatus comprises a hinged panel configured to swing outwardly from an outer side of the wing skin toward an open position to accommodate movement of an anti-icing duct extending through the aperture and to swing toward a closed position at least partially occluding the aperture.

A method of retrofitting a wing of a fixed wing aircraft is disclosed including the steps of providing an existing aircraft wing with a main fixed wing portion, and the main fixed wing portion having a tip end and an existing movable flight control surface connected adjacent the tip end. The existing movable flight control surface is then removed from the main fixed wing portion, and a wing tip device and movable flight control surface are selected as a pair to replace the existing movable flight control surface, with the selected movable flight control surface having an aerodynamic surface of different shape to the shape of the flight control surface removed from the wing. The selected wing tip device and movable flight control surface are then fitted to the main fixed wing portion.

A method of retrofitting a wing of a fixed wing aircraft is disclosed including the steps of providing an existing aircraft wing with a main fixed wing portion, and the main fixed wing portion having a tip end and an existing movable flight control surface connected adjacent the tip end. The existing movable flight control surface is then removed from the main fixed wing portion, and a wing tip device and movable flight control surface are selected as a pair to replace the existing movable flight control surface, with the selected movable flight control surface having an aerodynamic surface of different shape to the shape of the flight control surface removed from the wing. The selected wing tip device and movable flight control surface are then fitted to the main fixed wing portion.

A thrust producing unit for producing thrust in a predetermined direction, comprising at least two rotor assemblies and a shrouding that accommodates at most one of the at least two rotor assemblies, wherein the shrouding defines a cylindrical air duct that is axially delimited by an air inlet region and an air outlet region, and wherein the air inlet region exhibits in circumferential direction of the cylindrical air duct an undulated geometry.

A thrust producing unit for producing thrust in a predetermined direction, comprising at least two rotor assemblies and a shrouding that accommodates at most one of the at least two rotor assemblies, wherein the shrouding defines a cylindrical air duct that is axially delimited by an air inlet region and an air outlet region, and wherein the air inlet region exhibits in circumferential direction of the cylindrical air duct an undulated geometry.

An aerodynamic device includes a main aerodynamic body having a leading edge and a trailing edge, a flight control surface coupled to the main aerodynamic body near the trailing edge of the main aerodynamic body, and a translating body coupled to the flight control surface. The translating body is moveable relative to the flight control surface between a sealed position and a retracted position to define a gap. The translating body is extended toward the main aerodynamic body while in the sealed position to close the gap. The translating body is retracted away from the main aerodynamic body while in the retracted position to widen the gap. The gap adjusts an airflow flowing between the main aerodynamic body and the flight control surface.

An aerodynamic device includes a main aerodynamic body having a leading edge and a trailing edge, a flight control surface coupled to the main aerodynamic body near the trailing edge of the main aerodynamic body, and a translating body coupled to the flight control surface. The translating body is moveable relative to the flight control surface between a sealed position and a retracted position to define a gap. The translating body is extended toward the main aerodynamic body while in the sealed position to close the gap. The translating body is retracted away from the main aerodynamic body while in the retracted position to widen the gap. The gap adjusts an airflow flowing between the main aerodynamic body and the flight control surface.