A framework includes at least three posts, and at least three connecting ribs between the posts. First ends of the posts define a first plane, and second ends of the posts, that are opposite to the first ends thereof, define a second plane. At least one of the posts is adjustable to define, in combination with a further post of the at least three posts and two connecting ribs between the adjustable post and the further post, an adjustable trapezium that is configured to set a relative orientation between the first plane and the second plane and to thereby set an orientation of an adjoining framework. A system in which a plurality of said frameworks are interconnected.

A building structure assembly includes standardized interlocking components sized to suit any particular size of building required and ISO standard shipping containers, including: at least one modular base structure, at least one modular beam structure, and at least one wall support in the form of a shipping container and a method of assembly of the building structure. Each modular beam and base structures a frame, interlocking with each other and a shipping container by corner castings with twist lock assemblies, arranged in a particular orientation with each other. The modular base structure is supported by the corner castings of a shipping container and the base structure supports an end portion of at least one modular beam structure. A modular beam structure spans shipping containers. The modular beam structures can function as roof trusses and are sized to be transported inside shipping containers.

An erected platform which contains parallel lines of trusses connected end-to-end and method of erecting thereof, as illustrated in FIGS. 20 to 23. Each truss has two sides for chords respectively, with apertures or eyelets at the ends. First and second other trusses for a pair of parallel lines respectively are connected by positioning a first other truss adjacent the decking laid on an existing platform portion. Apertures on first respective sides of the first other truss and one of the existing trusses are connected by a first pin and the first other truss swung into an end-to-end position with the one existing truss and a second pin inserted in apertures on second respective sides of the first other truss and the one existing truss. The first pin is removed and the first other truss swung out of the way so that the second other truss may be attached. The second other truss is positioned adjacent the existing decking and similarly connected end-to-end with the other existing truss. The first other truss is then swung back into position for end-to-end attachment to the one existing truss and the second pin re-inserted.

A method automatically propagates a corner trimming in a 3D modeled object having a plurality of corners with a plurality of structural corner-members. Each corner includes a corner location and a count of its corner-members. The features of each corner-member include a cross-sectional shape and size, a corner-member location, and its relative orientation with respect to the other corner-members. A list of the corners and a selection of a seed corner is received. A target corner in the model is identified as topologically similar to the seed corner. A user definition of a trimming of the seed corner is automatically applied to the target corner.

The present disclosure is directed to climbing wall assemblies having a variety of improvements. For instance, the climbing wall assemblies may include connectors to attach the surface panels to the framework, in which the connectors may be mounted substantially anywhere along the front of the framework and at substantially any angle, providing for the securement of climbing panels in various geometries. The climbing wall assemblies may also include braces that may easily be adjusted to a desired length and configuration during construction of a climbing wall. The climbing wall assemblies may also include variable-angle, integral front posts, which provide for the easy and stable securement of climbing panels in various geometries. These improvements provide climbing wall assemblies that may be easily assembled to produce a desirable climbing wall structure having few framework components.

A composite lattice beam. The composite lattice beam includes four or more longitudinals. The four or more longitudinals are parallel to one another, comprise the four corners of a rectangle and include a tow, where the tow includes a bundle of untwisted fibers. The composite lattice beam also includes one or more outer diagonals. The one or more outer diagonals vary in two dimensions and include a tow, where the tow includes a bundle of untwisted fibers. The composite lattice beam further includes one or more inner diagonals. The one or more inner diagonals vary in three dimensions and include a tow, where the tow includes a bundle of untwisted fibers. The composite lattice beam additionally includes one or more nodes. The nodes are each an interweaving of at least one of the four or more longitudinals, at least one of the one or more outer diagonals and at least one of the one or more inner diagonals.

A support structure including a tension-compression element is composed of tension-compression bars that are connected in real joints as well as tension straps that extend from one joint to another. The outermost tension-compression bars are connected in one respective knot. Two pressurized hollow members that are surrounded by a cover are arranged on both sides of a plane that extends through the tension-compression element such that the linear tensions generated in the cover preload the tension straps on the plane of the tension-compression element, secure the tension-compression bars against bending, and stabilize the joints. The linear tensioning components that extend perpendicular to said plane of symmetry strut the tension-compression element against lateral bending. Air-tight, optionally elastic pneumatic elements can be inserted into the hollow members.

A system for capturing three-dimensional images, the system comprising: a truss assembly having a truss frame defining an interior, the truss assembly coupled to an array of cameras, lights, and microphones directed towards the interior, wherein the truss assembly may be of a polyhedron shape and wherein a subject may be located within the interior; the array of cameras being distributed throughout the truss assembly. Also disclosed is a system for capturing three-dimensional images wherein the cameras, lights, and microphones capture the subject from enough angles to generate a three-dimensional virtual model of the subject.

A connection apparatus may be used to connect truss sections or other objects. A connection segment is mounted on each truss to be connected. Each of a first and second connection segment has an opening, in alignment with each other to receive a fastener. The opening of the first connection segment allows the fastener to pivot. The second connection segment has a side opening which allows the fastener to pivot inside and outside the body of the second connection segment. The fastener has a threaded end and a locking end. The locking end may be secured against an outer surface of the second connection segment. In the locked position the locking end of the fastener engages the outer surface of one the second connection segment and the fastener is prevented from rotational or axial movement. The connection segments are thus fixed relative to each other as are the truss sections on which the connection sections may be mounted.

A composite lattice beam. The composite lattice beam includes four or more longitudinals. The four or more longitudinals are parallel to one another, comprise the four corners of a rectangle and include a tow, where the tow includes a bundle of untwisted fibers. The composite lattice beam also includes one or more outer diagonals. The one or more outer diagonals vary in two dimensions and include a tow, where the tow includes a bundle of untwisted fibers. The composite lattice beam further includes one or more inner diagonals. The one or more inner diagonals vary in three dimensions and include a tow, where the tow includes a bundle of untwisted fibers. The composite lattice beam additionally includes one or more nodes. The nodes are each an interweaving of at least one of the four or more longitudinals, at least one of the one or more outer diagonals and at least one of the one or more inner diagonals.