Disclosed herein is the fabrication and implementation of prefabricated volumetric construction modules that include transitioning members that adjust between vertical support columns and structural trusses via lateral joints. Modification of vertical support columns to trusses enables open space configurations in volumetric construction. Each volumetric module includes a habitation zone and a truss zone. Folding or transitioning a vertical support column at the lateral joint positions a lower region of the support column from the habitation zone into the truss zone. The vertical support columns are transitioned in a specified order where within a given row of vertical support columns. Beginning from a first interior column on an edge-positioned transforming volumetric module, workers fold half of the vertical support columns of the given row into the truss arrangement in a first direction toward the edge-positioned transforming volumetric module. Continuing from a second interior column on an opposite edge-positioned transforming volumetric module, a worker folds a remaining half of the vertical support columns of the given row into the truss arrangement in a second direction toward the opposite edge-positioned transforming volumetric module.

Disclosed herein is the fabrication and implementation of prefabricated volumetric construction modules that include transitioning members that adjust between vertical support columns and structural trusses via lateral joints. Modification of vertical support columns to trusses enables open space configurations in volumetric construction. Each volumetric module includes a habitation zone and a truss zone. Folding or transitioning a vertical support column at the lateral joint positions a lower region of the support column from the habitation zone into the truss zone. The vertical support columns are transitioned in a specified order where within a given row of vertical support columns. Beginning from a first interior column on an edge-positioned transforming volumetric module, workers fold half of the vertical support columns of the given row into the truss arrangement in a first direction toward the edge-positioned transforming volumetric module. Continuing from a second interior column on an opposite edge-positioned transforming volumetric module, a worker folds a remaining half of the vertical support columns of the given row into the truss arrangement in a second direction toward the opposite edge-positioned transforming volumetric module.

A transportable storm shelter or kit for a transportable storm shelter having a plurality of removable frames and a plurality of removable skins removably receivable on or within the removable frames and secured together by removable fasteners that are not bolted in place. A hollow tube fastener, having a hollow tube guide and a removeable pin receivable therethrough, is configured on a surface of the removable skins to hold the removable skins in assembled configuration with the removable frames. The removable skins are securable from the interior of the shelter, allowing the occupant to remove the skins from within the interior by removing the pins from the fasteners. The storm shelter provides a door with hinges that may be removed from the exterior by rescue personnel. The storm shelter is approximately the size of a garage workbench and can be sold as a kit and assembled using minimal construction skills.

Insulated panels having suitable surface members separated by an inner layer of insulated foam are used for the walls and as structural members for the floor and roof of a building structure. A rigid frame supports the wall, floor and roof insulated panels. The wall insulated panels are supported on the exterior of the frame by rigid brackets with the insulated panels being suitably flashed or capped.

Aspects of the present disclosure generally pertain to Relocatable Habitat Units (RHUs) for use as a rapidly deployable shelter. More particularly, the present application pertains to an RHU that can be assembled, reconfigured and disassembled on-site, using panels that can be maneuvered, positioned and interconnected by two men. Aspects of the present disclosure also pertain to field-deployable construction sets for the assembly of a RHU and associated panels, used for simulating real world environments without costly construction expenses. The RHU or components thereof may simulate a real building structure both visually and in a non-visual domain such as via electromagnetic sensors. Aspects of the present disclosure also generally pertain to a deployable structure for human use. Aspects of the present disclosure are directed toward a rapidly deployable habitat, for use where providing traditional structures is not an option or otherwise impractical.

A rapid deployment and reuseable, multi-level structural system called Metrideck that uses traditional types of walls structures and handrail. Metrideck system includes (a) a set of vertical columns each with a set of attachment features; (b) a set of pre-manufactured beams each said beam with a set of attachment features; (c) a Quicset for connecting beam and columns; (d) a deck panel with hardware to attach it to the beams and with slots to attach a hanger bracket to connect to the wall structure; (e) a series of curbing that encircles the deck panel perimeter with a set of attachment features; (f) a stair system; and (g) a set of handrail/guardrails wherein the decking system maintains a modular relationship to the mating wall structures, provides multiple platform configurations, uses fewer components, and provides a higher strength to weight ratio compared to other rapid deployment structural systems.

A portable building is disclosed, having a wall section including a first upwardly extending support member, a second upwardly extending support member and a header supported by the first upwardly extending support member and the second upwardly extending support member, the header having a header channel. The wall section also includes a floor beam secured to the first upwardly extending support member and the second upwardly extending support member, the floor beam having a floor beam channel. Further, the wall section includes a plurality of wall panels, where each of the plurality of wall panels are removably retained within the header channel and the floor beam channel, such that each of the plurality of wall panels are slidable along the floor beam and the header while retained within the header channel and the floor beam channel. Each of the plurality of wall panels are configured to interlockingly engage an immediately adjacent wall panel and an exterior surface of each of the plurality of wall panels form a continuous exterior wall surface.

A portable shelter with electromagnetic interference (EMI) protection includes a plurality of walls that define an interior space. The walls can be fixed or movable. An EMI protected edge connector joins at least two of the walls together. The EMI protected edge connector assembly can be fixed or hinged. The edge connector can include a metallic outer edge member with two legs and a separate metallic inner edge member with two legs to define an edge channel therebetween with: (i) the first outer leg and the first inner leg are arranged parallel and spaced-apart relative to each other; and (ii) the second outer leg and the second inner leg arranged parallel and spaced-apart relative to each other. The shelter walls can include an inner surface covered by a metallic foil inner layer. A first wall panel is received in a first portion of the edge channel with its metallic foil inner layer contacting the inner edge member and a second wall panel is received in a second portion of the edge channel with it metallic foil inner layer contacting the inner edge member.

A device comprising: a first sidewall connected to a bottom wall via a first hinge and connected to a top wall via a second hinge, wherein a third hinge is disposed in the first sidewall about parallel to both the first hinge and the second hinge; a second sidewall connected to the bottom wall via a fourth hinge and connected to the top wall via a fifth hinge, wherein a sixth hinge is disposed in the second sidewall about parallel to both the fourth hinge and the fifth hinge, wherein the second sidewall is opposite the first sidewall, and wherein the third hinge of the first sidewall and the sixth hinge of the second sidewall have about a co-equal height along the side first and second sidewalls, relative to the bottom wall; a third sidewall connected to the bottom wall via a seventh hinge; and a fourth sidewall connected to the bottom wall via an eight hinge, wherein the fourth sidewall is configured to fold onto the bottom wall, and wherein the third sidewall is configured to fold onto the fourth sidewall in a collapsed position of the device.

The present disclosure relates to a modular assembly, a site factory, for at least partially enclosing a site during construction of a structure. The modular assembly comprising: a plurality of portal frames, each portal frame comprising two columns and a roof beam, each column and roof beam comprising a plurality of pre-assembled units; a jack-up frame for each column; at least two first rails, each of the first rails being mounted to at least one of the roof beams; at least one second rail slidably mounted to the at least two first rails; and a plurality of panels of a flexible material configured to provide a full enclosure of the site and mounted above the roof beam. The or each second rail is configured to slidably receive at least one lifting device. The pre-assembled units are configured to be connected on site, and lifted using said jack-up frames, to form the portal frames, and wherein each first rail, and the or each second rail are configured to be mounted on the portal frames on site.