Abstract: A wing fold system may move a second portion of a wing with respect to a first portion of the wing between flight position 301 and folded position 303. A first link may rotate in response to actuating an actuator. A second link may move in response to rotating of the first link. The second portion of the wing may move in response to moving the second link and the second portion may move with respect to the first portion of the wing. One of the first portion and the second portion may be a fixed portion of the wing and the other of the first portion and the second portion may be a wingtip of the wing.

Abstract: Aircraft and airframes include a skin operatively coupled to a structural reinforcement member. The structural reinforcement member and the skin collectively define a run-out region that encompasses a terminal edge of the structural reinforcement member. Within the run-out region, the skin is more flexible than in adjacent portions of the skin. Methods include defining a region of increased flexibility of a skin relative to adjacent portions of the skin, and operatively coupling the skin to a structural reinforcement member.

Abstract: A wing fold system may move a second portion of a wing with respect to a first portion of the wing between flight position 301 and folded position 303. A first link may rotate in response to actuating an actuator. A second link may move in response to rotating of the first link. The second portion of the wing may move in response to moving the second link and the second portion may move with respect to the first portion of the wing. One of the first portion and the second portion may be a fixed portion of the wing and the other of the first portion and the second portion may be a wingtip of the wing.

Abstract: Aircraft and airframes include a skin operatively coupled to a structural reinforcement member. The structural reinforcement member and the skin collectively define a run-out region that encompasses a terminal edge of the structural reinforcement member. Within the run-out region, the skin is more flexible than in adjacent portions of the skin. Methods include defining a region of increased flexibility of a skin relative to adjacent portions of the skin, and operatively coupling the skin to a structural reinforcement member.

Abstract: Aircraft wing assemblies having both composite and metal panels are disclosed. In one embodiment, a wing assembly includes a support structure, an upper panel assembly formed from a metal material and coupled to the support structure, and a lower panel assembly formed from a composite material and coupled to the support structure. The metal material may be aluminum, titanium, or any other suitable metal, and the composite material may be a carbon fiber reinforced plastic (CFRP) material or other suitable composite material. In another embodiment, the upper panel assembly includes a downwardly depending first web portion, and the lower panel assembly includes an upwardly depending second web portion, the second web portion being proximate the first web portion, and an interface member of an isolating material is disposed between the first and second web portions.

Abstract: Aircraft wing assemblies having both composite and metal panels are disclosed. In one embodiment, a wing assembly includes a support structure, an upper panel assembly formed from a metal material and coupled to the support structure, and a lower panel assembly formed from a composite material and coupled to the support structure. The metal material may be aluminum, titanium, or any other suitable metal, and the composite material may be a carbon fiber reinforced plastic (CFRP) material or other suitable composite material. In another embodiment, the upper panel assembly includes a downwardly depending first web portion, and the lower panel assembly includes an upwardly depending second web portion, the second web portion being proximate the first web portion, and an interface member of an isolating material is disposed between the first and second web portions.

Abstract: A discretely stiffened composite panel formed of multiple layers of cured fibrous material. The panel (46) includes a planar part (38) and a plurality of stringers (36) located in spaced apart positions across the width of the planar part. The stringers terminate before reaching the edge of the planar part of the panel. The panel includes groups of interspersed strips of fibrous material (60, 61) having load bearing characteristics most favorable to carrying the primary axial loading (P) applied to the panel. The strips underlie the stringers and extend beyond the stringers to the edge of the planar part of the panel. The regions between the strips are filled with filler layers (64, 65). The use of groups of strips (60, 61) and filler layers located at the edge of the panel provides a panel having a reinforced, constant thickness edge having improved damage containment characteristics that is easily spliced with no significant loss of strength on the splice area.

Abstract: The front bearing for a landing gear trunion is carried by a rear wing spar and the rear bearing is carried by a landing gear beam which is pivotly attached at its inner end to the body frame. A main attach pin pivotally connects the outer end of such beam to a pair of connector plates, one located on each side of the connection. A pair of shear pins connect the connector plates to a short cantilever beam which is connected to and projects inwardly from the rear wing spar, generally in line with the landing gear beam. One of the shear pins is positioned generally horizontally outwardly from the main attach pin. The second shear pin is positioned generally vertically below the main attach pin. Generally vertical overloads are carried by the lower shear pin load and such shear pin is designed to fracture in response to a load slightly below the vertical load reacting capability of the reaction structure.