Abstract: The present disclosure provides a brace having a first leg and a second leg offset from the first leg. The brace also has a pivot assembly having a bar pivotably coupled with the first leg to define a first pivot point and pivotably coupled with the second leg to define a second pivot point. The brace further includes first and second attachment assemblies coupled with the first leg and the second leg, respectively, and each arranged to couple to a portion of a structure. In addition, the brace includes an actuator assembly coupling the first leg with the second leg and having an actuator arranged to pivot, or maintain a position of, the first leg relative to the first pivot point and to pivot, or maintain the position of, the second leg relative to the second pivot point so as to control a load on, and deflection of, the structure.

Abstract: The present disclosure provides a brace having a first leg and a second leg offset from the first leg. The brace also has a pivot assembly having a bar pivotably coupled with the first leg to define a first pivot point and pivotably coupled with the second leg to define a second pivot point. The brace further includes first and second attachment assemblies coupled with the first leg and the second leg, respectively, and each arranged to couple to a portion of a structure. In addition, the brace includes an actuator assembly coupling the first leg with the second leg and having an actuator arranged to pivot, or maintain a position of, the first leg relative to the first pivot point and to pivot, or maintain the position of, the second leg relative to the second pivot point so as to control a load on, and deflection of, the structure.

Abstract: The present disclosure provides a brace having a first leg and a second leg offset from the first leg. The brace also has a pivot assembly having a bar pivotably coupled with the first leg to define a first pivot point and pivotably coupled with the second leg to define a second pivot point. The brace further includes first and second attachment assemblies coupled with the first leg and the second leg, respectively, and each arranged to couple to a portion of a structure. In addition, the brace includes an actuator assembly coupling the first leg with the second leg and having an actuator arranged to pivot, or maintain a position of, the first leg relative to the first pivot point and to pivot, or maintain the position of, the second leg relative to the second pivot point so as to control a load on, and deflection of, the structure.

Abstract: A self-aligning support incorporates a support attachment fitting and a rotatable pin assembly having a primary load pin coupling the support attachment fitting to an attachment support, and inboard and outboard attachment claws engaged to end portions of the primary load pin. The rotatable pin assembly is configured to rotate relative to the support attachment fitting. At least one fuse pin extends through the primary load pin to limit translation of the primary load pin relative to the inboard and outboard claws.

Abstract: A system to arrest flap over-travel employs a track engaging a flap to a support structure. The track has a deployment profile determining flap motion relative to the support structure during travel between an extended position and a normal retracted position. The deployment profile has a transition portion extending beyond the normal retracted position and terminating in a detent. A resiliently mounted catcher is configured to be displaced by the transition portion during over-travel of the flap beyond the normal retracted position and captured in the detent in a maximum retracted position thereby restraining the flap.

Abstract: A flap support structure incorporates an auxiliary flap support attachment fitting and an auxiliary flap support track. A primary load pin couples the auxiliary support track to the auxiliary flap support attachment fitting and reacts operating loads on the flap. At least one fuse pin extends through the primary load pin to limit translation of the primary load pin relative to the attachment fitting.

Abstract: Disclosed herein is a system for actuating a flap coupled to a wing of an aircraft in a streamwise direction. The system comprises a geared rotary actuator comprising a drive gear that is rotatable about a first rotational axis. The system also comprises a crank shaft comprising a driven gear in gear meshing engagement with the drive gear of the geared rotary actuator to rotate the crank shaft about a second rotational axis. The second rotational axis is angled relative to the first rotational axis. The system further comprises a crank arm co-rotatably coupled to the crank shaft and configured to be coupled to the flap. Rotation of the crank shaft about the second rotational axis rotates the crank arm in a direction perpendicular to the second rotational axis.

Abstract: A flap actuation mechanism incorporates a flap bracket attached to a flap and coupled to an underwing structure with a pivotal coupling. A crankshaft is configured for over center rotation and has aligned inboard and outboard crank arms extending from axially spaced inboard and outboard journals disposed in the underwing structure and configured to rotate about a rotation axis of the inboard and outboard journals. A crank pin is connected between the inboard and outboard crank arms. An actuating rod has a first end rotatably coupled to the crank pin and a second end coupled to the flap bracket. Rotation of the crankshaft displaces the actuating rod to cause rotation of the flap bracket and the flap.

Abstract: A system to arrest flap over-travel employs a track extending from a flap and engaging an auxiliary support. The track has a deployment profile determining flap motion relative to the support structure during travel between an extended position and a normal retracted position. The deployment profile has a transition portion extending beyond the normal retracted position and terminating in a detent. A resiliently mounted catcher is configured to be displaced by the transition portion during over-travel of the flap beyond the normal retracted position and captured in the detent in a maximum retracted position thereby restraining the flap.

Abstract: An aircraft control structure includes first and second outer surfaced joined to a side wall. Stiffening webs extends between the first and second outer surfaces, each stiffening web at least partially surrounding an associated aperture formed in either the first or second outer surface and defining a stiffening recess. Skin plates are sized to extend over an associated stiffening recess and are shaped to conform to an associated aperture. Each skin plate is joined to an associated stiffening web by a friction stir welded seam.

Abstract: Example methods and apparatus for mitigating aerodynamic flutter of aircraft wing flaps are disclosed. An example apparatus includes a fairing, an actuator, and a damper. The fairing is located on a bottom side of a wing of an aircraft. The actuator is disposed in the fairing. The actuator is coupled to and extends between the wing and a flap of the wing. The damper is disposed in the fairing. The damper is coupled to and extends between the fixed wing and the moveable flap.

Abstract: An aeroseal comprises a substantially straight portion having a first engagement end and a second engagement end opposite the first engagement end. The aeroseal also comprises a first engagement extension extending transversely from the first engagement end of the substantially straight portion and having a distal end. The aeroseal further comprises a second engagement extension extending transversely from the second engagement end of the substantially straight portion and having a distal end. The aeroseal also comprises a substantially curved portion interconnecting the distal end of the first engagement extension and the distal end of the second engagement extension to form an acute angle between the first and second engagement extensions and facing away from the substantially straight portion.

Abstract: A flap actuation mechanism incorporates a flap bracket attached to a flap and coupled to an underwing structure with a pivotal coupling. A crankshaft is configured for over center rotation has aligned inboard and outboard crank arms extending from axially spaced inboard and outboard journals disposed in the underwing structure and configured to rotate about a rotation axis of the inboard and outboard journals. A crank pin connected between the inboard and outboard crank arms. An actuating rod has a first end rotatably coupled to the crank pin and a second end coupled to the flap bracket. Rotation of the crankshaft displaces the actuating rod to cause rotation of the flap bracket and the flap.

Abstract: A self-aligning support incorporates a support attachment fitting and a rotatable pin assembly having a primary load pin coupling the support attachment fitting to an attachment support, and inboard and outboard attachment claws engaged to end portions of the primary load pin. The rotatable pin assembly is configured to rotate relative to the support attachment fitting. At least one fuse pin extends through the primary load pin to limit translation of the primary load pin relative to the inboard and outboard claws.

Abstract: A flap support structure incorporates an auxiliary flap support attachment fitting and an auxiliary flap support track. A primary load pin couples the auxiliary support track to the auxiliary flap support attachment fitting and reacts operating loads on the flap. At least one fuse pin extends through the primary load pin to limit translation of the primary load pin relative to the attachment fitting.

Abstract: Example methods and apparatus for mitigating aerodynamic flutter of aircraft wing flaps are disclosed. An example apparatus includes a fairing, an actuator, and a damper. The fairing is located on a bottom side of a wing of an aircraft. The actuator is disposed in the fairing. The actuator is coupled to and extends between the wing and a flap of the wing. The damper is disposed in the fairing. The damper is coupled to and extends between the fixed wing and the moveable flap.

Abstract: An aircraft control structure includes first and second outer surfaced joined to a side wall. Stiffening webs extends between the first and second outer surfaces, each stiffening web at least partially surrounding an associated aperture formed in either the first or second outer surface and defining a stiffening recess. Skin plates are sized to extend over an associated stiffening recess and are shaped to conform to an associated aperture. Each skin plate is joined to an associated stiffening web by a friction stir welded seam.

Abstract: Disclosed herein is a system for actuating a flap coupled to a wing of an aircraft in a streamwise direction. The system comprises a geared rotary actuator comprising a drive gear that is rotatable about a first rotational axis. The system also comprises a crank shaft comprising a driven gear in gear meshing engagement with the drive gear of the geared rotary actuator to rotate the crank shaft about a second rotational axis. The second rotational axis is angled relative to the first rotational axis. The system further comprises a crank arm co-rotatably coupled to the crank shaft and configured to be coupled to the flap. Rotation of the crank shaft about the second rotational axis rotates the crank arm in a direction perpendicular to the second rotational axis.

Abstract: An aeroseal comprises a substantially straight portion having a first engagement end and a second engagement end opposite the first engagement end. The aeroseal also comprises a first engagement extension extending transversely from the first engagement end of the substantially straight portion and having a distal end. The aeroseal further comprises a second engagement extension extending transversely from the second engagement end of the substantially straight portion and having a distal end. The aeroseal also comprises a substantially curved portion interconnecting the distal end of the first engagement extension and the distal end of the second engagement extension to form an acute angle between the first and second engagement extensions and facing away from the substantially straight portion.

Abstract: A system to arrest flap over-travel employs a track extending from a flap and engaging an auxiliary support. The track has a deployment profile determining flap motion relative to the support structure during travel between an extended position and a normal retracted position. The deployment profile has a transition portion extending beyond the normal retracted position and terminating in a detent. A resiliently mounted catcher is configured to be displaced by the transition portion during over-travel of the flap beyond the normal retracted position and captured in the detent in a maximum retracted position thereby restraining the flap.