The present invention discloses an integrated steel concrete building and its construction method. The building comprises a plurality of prefabricated room modules of steel, each including at least one column having a structure of hollow steel tube, which has an inner chamber inserted with penetrating rebars and poured with concrete. The penetrating rebars extend upwardly out of the column of the prefabricated room module into an inner chamber of a column of a prefabricated room module of an upper floor.

Systems and methods are provided for securing a transport device to preexisting studs or support members. One embodiment includes a clamp assembly with a compression fitting adapted to be secured to a plurality of different sized studs or wall supports, and further to support additional supports including, but not limited, horizontal support members. A transport device is further provided that is selectively connectable to clamp and support members of the disclosure. In another embodiment, a hook bracket is provided which includes a projection configured to be positioned in a hole through a stud. The extension may include a notch to engage a portion of the stud. The hook bracket includes at least one aperture adapted to secure the hook bracket to a support member operatively interconnected to the transport device.

A device comprising a weldment having an upper beam, a vertical beam, and a lower beam, wherein the upper beam further comprises at least two lifting eyes and at least one crane hook, and the lower beam further comprises a plurality of swivel-hoist rings and a plurality of forklift pockets, and wherein the lower beam is a length minimally required to locate a structure laterally underneath an upper level of a platform having an upper level and a lower level.

A computer system of a finishing center, such as a mobile finishing center, includes a tool that allows a customer to preview or create new designs for apparel before purchase and before laser finishing. Software and lasers are used in finishing apparel to produce a desired wear pattern or other design. Based on a laser input file with a pattern, a laser will burn or ablate the pattern onto apparel. With the tool, the customer will be able to preview, create, make changes, and view images of a design, in real time, before purchase and burning or ablation by a laser. Input to the tool can include fabric template images, laser input files, and damage input. In an implementation, the customer or another user can also move, rotate, scale, and warp the image input.

The present invention refers to a modular system for fast connection of habitable modules (2) based on coupling standardized shipping containers to adjusted receiving structures (3). This system is based on a connecting plate system (1), habitable modules (2), a receiving structure (3), an alveolar structure (7) to connect said receiving structure (3) and automatic systems for transport, lifting, docking and coupling. The present invention refers also to a method of fast connection of habitable modules (2) within this modular structure.

A prefabricated house including: a steel-frame foundation where H-shaped steels are connected in a rectangular contour, a vertical frame and a horizontal frame composed of an H-shaped steel are arranged inside the connected H-shaped steels, and inclined frames are mounted at four corners of the rectangular contour; a seismic isolation rubber supporting the steel-frame foundation on a foundation of the prefabricated house via a supporting frame; a rectangular floor member; outer wall members erected from four peripheries of the floor member; an inner wall member mounted at a position partitioning the floor member; and a roof member with a mountain-shaped section mounted on the outer wall members via a climbing beam, wherein changing positions of a window and a door and changing a room layout can is possible by changing positions of the wall member panels or reversing outer and inner faces or upper and lower sides of these panels.

An object handling system is described, the system having two substantially perpendicular sets of rails forming a grid above a workspace, the workspace having a plurality of stacked containers. The system includes a series of robotic load handling devices operating on the grid above the workspace, the load handling devices having a body mounted on wheels. The robotic devices can move around the grid under instruction from a computing device, the robotic devices being moved to a point on the grid above a stack of containers and then, using a lifting device, engage and lift a container from the stack. The container is then moved to a point where the objects in the container can be accessed. Modifications to the workspace and grid are described that allow vehicles and roll cages to be used to move stacks from the workspace to a point outside the workspace or from outside the workspace into the workspace.

A multi-story building (200) is described for manufactured homes (212) such as container homes. The building (200) includes a ground floor (202), a number of intermediate floors (204), and a top floor (206). The building (200) includes a throughway (208) on the ground floor (202) that allows passage of a transportation vehicle (210) such as a flatbed truck carrying a manufactured home (212). The transportation vehicle (210) can use the throughway (208) to position the manufactured home (212) in alignment with a hoistway (214). A hoist mounted on the roof (216) can then be used to hoist the home (212) to a desired floor (204 or 206).

A modular multi-container housing structure connector for containers, which each have sides including a roof, a floor, and four lateral sides, includes a connector frame comprising vertical and horizontal struts shaped to connect to at least one of the sides of two adjacent containers and at least one interlock configured to secure the connector frame to the side of one container. The at least one interlock may be a plurality of interlocks. The connector frame may comprise two vertical struts and two horizontal struts each shaped and configured to connect to a respective edge of an adjacent side of two adjacent containers and, responsive to the connector frame being connected to two adjacent sides of two adjacent containers by the plurality of interlocks, the connector frame and interlocks form a container-to-connector frame-to-container connection to establish a weather-tight housing structure with the two or multiple connected containers.

The present invention discloses a heating and cooling system of a modular residential building at least comprising: a) a building framework, b) a number of flat modules (1.0), c) a number of front elements (6.04), d) at least two gable elements (6.03), e) at least one roof element (6.02), and f) a plurality of horizontal and vertical heating and cooling canals, where the building frameworks includes fastening means (5.02) for securing the flat modules (1.0) to the building framework with a horizontal and vertical distance between neighbouring flat modules (1.0) thereby creating cavities there between where cavities are utilized as the plurality of horizontal and vertical heating and cooling canals.