An H-beam joint structure for joining ends of H-beam steel materials adjacent to each other. The steel materials have a flange and a web. The joint structure includes: a transmission plate arranged parallel to a front surface of the web on at least one side of the web of the H-beam and the steel material, and welded to a back surface of the flange; and a coupling plate provided in close contact with the transmission plate to connect the H-beam and the steel material. A web of the H-beam, the web of the steel material and the transmission plate are bolted via the coupling plate. As a result, there is provided an H-beam joint structure which has a joining strength equivalent to a conventional joint structure for an H-beam, and also which can easily be constructed to have less parts and make front surfaces of the flanges flat.

A rail for a cable tray having opposite longitudinal ends includes a generally vertical web having opposite upper and lower ends, an upper flange at the upper end of the web, and a lower flange at the lower end of the web. A splice plate retention groove outboard of the vertical web and generally adjacent at least one of the opposite longitudinal ends of the rail is configured to receive a splice plate therein to facilitate positioning of the splice plate on the rail.

A framework section having a connection region which is formed on the end face of at least one of its two ends. The connection region can be connected to the connection region of a further framework section. The framework section can include two upper chord sections and two lower chord sections, which extend parallel to one another in the longitudinal direction of the framework section and are connected to one another by connecting struts such that they define a cuboid space. The upper chord sections and the lower chord sections can have a tubular cross section, wherein the upper chord sections and the lower chord sections can also be configured to transition from the tubular cross section into an I-shaped cross section in the connection region.

A structural assembly (10) comprising a first structural member (100), a second structural member (200), and a lock plate (300). Each of the structural members (100, 200) have a first portion (102, 202) which extends in a first plane and a second portion (103, 203) which extends away from the first portion (102, 202) and which extends in a second plane at an angle to the first plane. The first portion (102, 202) of the structural members (100, 200) are provided with an engagement feature (104, 204) configured to interlock with a compatible engagement feature (304) provided on the lock plate (300) of the structural assembly. The second portion (103, 203) of the first structural member (100) and second structural member (200) being provided with: compatible seating features (106, 206) configured to seat one of the structural members (200) on the other structural member (100).

A structural member section comprised of horizontal top and bottom flange elements interconnected by one or more vertical web member. The top flange of the member is serrated such that a series of serrations protrude horizontally in at least one direction from a top of the one or more vertical web member or are cut-out from the flange of a rolled shape. In one embodiment, the serrated top flange and at least a portion of the web member are intended to be encased by a horizontal concrete slab or slab-on-deck assembly. The slab material is capable of encasing all exposed surfaces of and curing around each serration to transfer horizontal shear forces between the serrated top flange and the slab material such that the member and slab behave compositely.

Modular building methods and systems using lightweight foam modular panels. Each panel includes one or more channels formed through the length of the foam body, where the channels are configured to receive splines therein. The channels may include pairs of top and pairs of bottom channels, each channel being offset from the center of the foam body, so that the channels are oriented towards the respective panel faces. Splines may also be positioned along the top and bottom of the panel (such splines forming a web center portion of an I-beam). In combination with the splines in the top and bottom channels, these web center portion splines form horizontally extending I-beams at the top and bottom of each panel, so that stacked panels include a horizontally extending I-beam there between. Side-by-side panels include vertical posts there between, such that the system forms a post and beam construction system.

A structural assembly (10) comprising a first structural member (100), a second structural member (200), and a lock plate (300). Each of the first structural member (100) and second structural member (200) have a first portion (102, 202) which extends in a first plane and a second portion (103, 203) which extends away from the first portion (102, 202) and which extends in a second plane at an angle to the first plane. The first portion (102, 202) of the first structural member (100) and second structural member (200) are provided with an engagement feature (104, 204) configured to interlock with a compatible engagement feature (304) provided on the lock plate (300) of the structural assembly. The second portion (103, 203) of the first structural member (100) and second structural member (200) being provided with: compatible seating features (106, 206) configured to seat one of the structural members (200) on the other structural member (100).

An H-beam joint structure for joining ends of H-beam steel materials adjacent to each other. The steel materials have a flange and a web. The joint structure includes: a transmission plate arranged parallel to a front surface of the web on at least one side of the web of the H-beam and the steel material, and welded to a back surface of the flange; and a coupling plate provided in close contact with the transmission plate to connect the H-beam and the steel material. A web of the H-beam, the web of the steel material and the transmission plate are bolted via the coupling plate. As a result, there is provided an H-beam joint structure which has a joining strength equivalent to a conventional joint structure for an H-beam, and also which can easily be constructed to have less parts and make front surfaces of the flanges flat.

The present invention is an I beam including a web, a top flange and a bottom flange. The flanges are parallel with the web extending therebetween so as to form spaces, at both sides of the web. Notches are formed in the top and bottom flanges of a joist of a height for fitment into the space of beam. A plate with at least four holes equi-spaced top and bottom is welded to each end of the stock length supplied beam, perpendicular to the web. The invention includes the method for providing a beam to beam connection, wherein the top and bottom flanges of beams are notched such that a first end is disposed between the top and bottom flanges of the first beam, and wherein the second beam web includes a connection plate to attach to the first beam web via fasteners.

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.