In one embodiment, a method may comprise coupling a plurality of reinforcement fibers to a plurality of spherical components; inserting the plurality of spherical components into an enclosure; and heating the enclosure to cause the plurality of spherical components to expand, wherein the plurality of spherical components expands to form a geodesic structure, wherein the geodesic structure comprises a plurality of polyhedron components configured in a geodesic arrangement.

A central airfoil box comprising two beams, each beam having a wall pierced with a first bore centered on a first axis, a connecting rod comprising, for each wall, a yoke joint having two flanks arranged on either side of the wall and pierced with a bore. Each yoke joint is fixed to the wall by a fixing system. The fixing system comprises a bearing lodging in the first bore, and being pierced with a second bore centered on a second axis parallel and offset to the first axis, a cylindrical shoulder, secured to and coaxial with the bearing and bearing against the wall, an outer perimeter of the shoulder having a plurality of splines, at least one block fixed to the wall around the first bore and configured to lodge in one of the splines, and a shaft lodging in the second bore and the yoke joint bores.

A central airfoil box comprising two beams, each beam having a wall pierced with a first bore centered on a first axis, a connecting rod comprising, for each wall, a yoke joint having two flanks arranged on either side of the wall and pierced with a bore. Each yoke joint is fixed to the wall by a fixing system. The fixing system comprises a bearing lodging in the first bore, and being pierced with a second bore centered on a second axis parallel and offset to the first axis, a cylindrical shoulder, secured to and coaxial with the bearing and bearing against the wall, an outer perimeter of the shoulder having a plurality of splines, at least one block fixed to the wall around the first bore and configured to lodge in one of the splines, and a shaft lodging in the second bore and the yoke joint bores.

An aircraft arrangement is provided, the aircraft arrangement including a first aircraft component for converting at least one input vibration into an output vibration suitable for driving an energy harvester, and an energy harvester coupled to the first aircraft component and configured to generate electrical energy in response to the output vibration of the first aircraft component, the first aircraft component including a three-dimensional lattice structure including a multiplicity of unit cells, the unit cells including multiple lattice-forming members, the unit cells having a mean greatest dimension of at least 10 nm.

The present disclosure generally relates to thermoplastic truss structures and methods of forming the same. The truss structures are formed using thermoplastic materials, such as fiber reinforced thermoplastic resins, and facilitate directional load support based on the shape of the truss structure. In one example, multiple two-dimensional patterns of fiber reinforced thermoplastic resin are disposed on one another in a saw tooth pattern, sinusoidal pattern, or other repeating pattern, and adhered to one another in selective locations. The two dimensional patterns may then be expanded in a third dimension to form a three-dimensional, cross-linked truss structure. The three-dimensional, cross-linked truss structure may then be heated or otherwise treated to maintain the three-dimensional shape.

The present disclosure generally relates to thermoplastic truss structures and methods of forming the same. The truss structures are formed using thermoplastic materials, such as fiber reinforced thermoplastic resins, and facilitate directional load support based on the shape of the truss structure. In one example, multiple two-dimensional patterns of fiber reinforced thermoplastic resin are disposed on one another in a saw tooth pattern, sinusoidal pattern, or other repeating pattern, and adhered to one another in selective locations. The two dimensional patterns may then be expanded in a third dimension to form a three-dimensional, cross-linked truss structure. The three-dimensional, cross-linked truss structure may then be heated or otherwise treated to maintain the three-dimensional shape.

A component, including a part, comprising a honeycomb-like structure formed from at least a seamless resin-infused fiber composite material. The honeycomb-like structure includes a first plurality of cells, and a second plurality of cells, different than the first plurality of cells.

A component, including a part, comprising a honeycomb-like structure formed from at least a seamless resin-infused fiber composite material. The honeycomb-like structure includes a first plurality of cells, and a second plurality of cells, different than the first plurality of cells.

A central wing box for an aircraft, including a top panel, a bottom panel, a front spar, a rear spar, and at least one secondary rib. A secondary rib includes two stiffeners, a first stiffener extending adjacent to the top panel and to one of the front spar and the rear spar, and a second stiffener extending adjacent to the bottom panel and to the other of the front spar and the rear spar. A reduced number of components can be employed, thereby simplifying the construction of the central wing box of an aircraft, particularly the installation of the secondary ribs.

A central wing box for an aircraft, including a top panel, a bottom panel, a front spar, a rear spar, and at least one secondary rib. A secondary rib includes two stiffeners, a first stiffener extending adjacent to the top panel and to one of the front spar and the rear spar, and a second stiffener extending adjacent to the bottom panel and to the other of the front spar and the rear spar. A reduced number of components can be employed, thereby simplifying the construction of the central wing box of an aircraft, particularly the installation of the secondary ribs.