A building container outrigger to provide an elevated work space for use between concrete slabs of a building under construction having a container, a plurality of support beams, each support beam positioned lengthwise under the floor of the container and extend therefrom the sides, a pair of spaced apart outrigger beams, a first outrigger end and a second outrigger end, each second outrigger end in contact with and affixed to the upper side of each support beam end, the other outrigger beam end removeably anchored to the slab floor with the front edge of the container flush with the exterior or front slab edge, and, thus, functions to functions to efficiently move materials and tools or personnel space from floor to floor as construction phases move vertically.

Expandable shelter systems and associated methods are described herein. In one aspect, an expandable shelter system can include a system container, where the container defines a container cavity when the system container is in a collapsed form; an expandable container section positioned within the defined cavity or forming the defined cavity when the system container is in the collapsed form, and including at least one of an expandable container front, an expandable container rear, an expandable container first side, an expandable container second side, an expandable container bottom, or an expandable container top; and an actuation system coupled to the system container and the expandable container section, where the actuation system is configured or adapted to reposition the expandable container section from the collapsed form to an expanded form, where a dimension of the cavity is greater in the expanded form compared to the collapsed form.

The disclosure relates to a platform for the space-saving formation of an energy conversion system. In this, containers are stacked one above the other as housings of components of the energy conversion system with the platform arranged between the containers, wherein the platform has a frame structure which has, on a first side, first alignment elements for placing the platform on a first container and, on a second side, opposite the first side, of the frame structure, second alignment elements for placing a second container on a placement area of the frame structure. The first and second alignment elements are arranged in such a way that they result in an arrangement, which is laterally centered and vertically spaced apart by a height (H) of the platform, of the second container above the first container, wherein the frame structure forms a standing area, which circumferentially surrounds the placement area and is walkable by persons, as access to the second container. An energy conversion system can be designed as a stack of at least two containers as housings of components of the energy conversion system, between each of which containers such a platform is arranged.

A modular self-contained gate for selectively blocking an entryway comprising an ISO standard shipping container modified such that an existing closed end wall of the shipping container comprises an elongate slot-like opening arranged vertically and adjacent an edge of the closed end wall, a substantially flat and rectangular gate comprising a long edge having a length substantially the same as a length of the shipping container and a height less than a height of the opening, the gate aligned with and linearly displaceable through the opening between a first position wherein the gate is stored inside the shipping container and the entryway is open and a second position wherein the gate is extended outside of the shipping container and passage via the entryway is barred, and a support mechanism inside the shipping container suspending the gate such that the gate remains suspended above the ground.

The present disclosure provides for a modular design and build architecture, comprising: one or more integrated system module (ISMs) that are configured to be shipped and assembled on-site to construct an operational infrastructure for one or more application environments, wherein each of the ISMs comprises two or more different functional components that are integrated onto and/or supported by a common structural floor.

A portable enclosed-structure deployment system configured to be stored and deployed from within a shipping container. A floor support system including a plurality of floor panels is disposed in the shipping container proximate to a bottom surface of the shipping container. The plurality of floor panels withdraw from an open side of the shipping container. A plurality of wall panels are stored in the shipping container above the plurality of floor panels. The plurality of wall panels are withdrawn from the open side of the shipping container subsequent to the plurality of floor panels being withdrawn from the shipping container. A roof system includes a plurality of roof panels supported on a rack in the shipping container above the plurality of wall panels. The plurality of roof panels slideably withdraw from the shipping container subsequent to the plurality of wall panels being withdrawn from the shipping container.

One or more embodiments of a device or structure for medical testing. The structure may include a shell defining an interior of the structure, at least one workstation in the interior of the structure, at least one window in the shell, each of the at least one workstation including one of the at least one window communicating between the respective workstation and an exterior of the structure, and an air control system configured to filter air and control air pressure in the interior of the structure.

Provided is a portable facility (1) including: a power generation unit (3) and a function unit (5), wherein the power generation unit (3) includes a transportable first housing (H1) and at least one power generation device attached to the first housing (H1), the first housing including a top wall (15), a bottom wall (17), and a surrounding wall (19), the at least one power generation device being one or more of a wind power generation device (7), a solar power generation device (9), and a hydraulic power generation device, and the function unit (5) includes a transportable second housing (H2) and an electric apparatus (11) disposed inside the second housing (H2) and configured to be powered by the power generation unit (3) to operate, the second housing including a top wall (15), a bottom wall (17), and a surrounding wall (19).

Provided is a mobile shop (1) including: a transportable shop body (3) including a top wall (11), a bottom wall (13), and a surrounding wall (15); and at least one power generation device attached to the shop body (3), the at least one power generation device being one or more of a wind power generation device (5), a solar power generation device (7), and a hydraulic power generation device. The mobile shop (1) may include all of the wind power generation device (5), the solar power generation device (7), and the hydraulic power generation device. The shop body (3) may be a freight container.

An emergency restoration system is disclosed. The emergency restoration system including a base and a tower pivotally connected to the base. The tower including at least one tower section and at least one insulated tower section pivotally connected to the at least one tower section, the insulated tower section including at least one insulator pivotally connected thereto.