A construction system for a module of a dwelling the main elements of which are made of plastic material includes a set of hollow profiled beams (1, 1′) of elongate rectilinear shape of type 1 and of type 2. The beams (1, 1′) include at each end (5, 5′) a transverse passage opening (6, 6′). The transverse passage opening (6) of a beam (1) of type 1 comes to be nested with the transverse passage opening (6′) of a beam (1′) of type 2 when the two beams (1, 1′) are assembled end to end at a right angle leaving a passage opening (6, 6′) between the two ends (5, 5′) of the beams (1, 1′). Two beams (1) of type 1 can be assembled with two beams (1′) of type 2 to form a rectangular frame. The system further includes a set of corner assembly elements (2, 2′), each assembly element (2, 2′) including a body intended to pass through the transverse passage opening (6, 6′) of the beams (1, 1′) of type 1 and 2. The system also includes a set of plates (3) that can be assembled between two beams (1) of type 1 when assembled or two beams (1′) of type 2 when assembled to form a rectangular frame, and a set of posts (11) of hollow rectangular section the hollow ends of which come to be nested over a corner assembly element (2, 2′) of a rectangular frame formed of beams (1, 1′) of type 1 and of type 2 so as to form a three-dimensional framework. The posts (11) include longitudinal rails or grooves (8) on two adjacent surfaces to receive other plates (3′) between the posts (11) during assembly. Each hollow profile beam (1, 1′) including along an upper surface spaced rails or grooves (8) intended to receive said other plates (3′).

Agricultural barns, warehouses, and methods for construction including a floor, walls that include foam wall panels, a wainscot of impact resistant panels at a lower portion of the wall, and a ceiling formed from foam roof panels integrated into the roof truss assembly. Once the floor, walls, and ceiling are assembled, walls and ceiling can be coated over with an abrasion resistant, impact resistant polymeric coating (e.g., akin to a truck-bed liner), tying these structures together in a seamless shell that provides sufficient elasticity to accommodate typical expansion/contraction due to daily and seasonal heating/cooling, humidity changes, etc. The sealed interior envelope allows the interior surfaces to easily be pressure washed daily, or whenever else needed. Such construction is particularly well suited to an agricultural barn or warehouse, where cattle or forklifts may run into the lower portion of the walls, and pressure washing may be a daily need.

The assembled light steel structure energy-saving composite wall in the present invention comprises: a cement board and/or ceramic tile, a column, a support rod, a cross beam, a bottom plate, a diagonal brace and a diagonal draw steel bar. In the thickness direction of the composite wall, the horizontal side of each group of columns is outside the composite wall, a plurality of support rods and diagonal braces are installed between the four second vertical sides of the columns of the each opposite group of columns. In the width direction of the composite wall, a plurality of cross beams and diagonal draw steel bars are installed between the first vertical sides of the column of the adjacent groups of columns. On both sides of the thickness direction of the composite wall, the horizontal sides of the column of the two adjacent columns are provided with a cement board and/or a ceramic tile inserted by a strip fastener and a strip, and the space enclosed by the cement board and the ceramic tile, the cement board and the cement board or the ceramic tile and the ceramic tile is filled with the filler. The assembled light steel structure wall system is simple to assemble, convenient to transport, operate and maintain, energy-saving and heat-preserving, the wall installation and wall decoration is completed at one time.

Agricultural barns, warehouses, and methods for construction including a floor, walls that include foam wall panels, a wainscot of impact resistant panels at a lower portion of the wall, and a ceiling formed from foam roof panels integrated into the roof truss assembly. Once the floor, walls, and ceiling are assembled, walls and ceiling can be coated over with an abrasion resistant, impact resistant polymeric coating (e.g., akin to a truck-bed liner), tying these structures together in a seamless shell that provides sufficient elasticity to accommodate typical expansion/contraction due to daily and seasonal heating/cooling, humidity changes, etc. The sealed interior envelope allows the interior surfaces to easily be pressure washed daily, or whenever else needed. Such construction is particularly well suited to an agricultural barn or warehouse, where cattle or forklifts may run into the lower portion of the walls, and pressure washing may be a daily need.

An insulation product may include a container, a first insulation material forming a first layer inside the container, and a second insulation material forming a second layer inside the container, and the first layer is compressed by the second layer. A structure in a building may include studs, first and second claddings mounted to opposite sides of the studs, and structure spaces defined between the studs and the opposing claddings. A first insulation material may include first layers on and substantially covering a first one of the claddings inside the structure spaces. In addition, a second insulation material may have second layers inside the structure spaces. The first layers are compressed and substantially covered by the second layers, and the second layers substantially cover a second one of the claddings inside the structure spaces.

The assembled light steel structure energy-saving composite wall in the present invention comprises: a cement board and/or ceramic tile, a column, a support rod, a cross beam, a bottom plate, a diagonal brace and a diagonal draw steel bar. In the thickness direction of the composite wall, the horizontal side of each group of columns is outside the composite wall, a plurality of support rods and diagonal braces are installed between the four second vertical sides of the columns of the each opposite group of columns. In the width direction of the composite wall, a plurality of cross beams and diagonal draw steel bars are installed between the first vertical sides of the column of the adjacent groups of columns. On both sides of the thickness direction of the composite wall, the horizontal sides of the column of the two adjacent columns are provided with a cement board and/or a ceramic tile inserted by a strip fastener and a strip, and the space enclosed by the cement board and the ceramic tile, the cement board and the cement board or the ceramic tile and the ceramic tile is filled with the filler. The assembled light steel structure wall system is simple to assemble, convenient to transport, operate and maintain, energy-saving and heat-preserving, the wall installation and wall decoration is completed at one time.

A T-shaped shear wall module including a straight pattern plate, two L-shaped pattern plates with a same structure, and connectors. Each of the two L-shaped pattern plates includes a first pattern plate and a second pattern plate which are perpendicular to each other. In a direction perpendicular to the straight pattern plate, the two first pattern plates are arranged in parallel to each other and both extend in a direction away from the straight pattern plate, and a plurality of connectors are rigidly arranged between two first pattern plates. Along a direction parallel to the straight pattern plate, two second pattern plates are coplanar and extend in opposite directions, and a plurality of connectors are rigidly arranged between the straight pattern plate and the two second pattern plates. The present application also provides a shear wall and a construction method thereof.

An insulation product may include a container, a first insulation material forming a first layer inside the container, and a second insulation material forming a second layer inside the container, and the first layer is compressed by the second layer. A structure in a building may include studs, first and second claddings mounted to opposite sides of the studs, and structure spaces defined between the studs and the opposing claddings. A first insulation material may include first layers on and substantially covering a first one of the claddings inside the structure spaces. In addition, a second insulation material may have second layers inside the structure spaces. The first layers are compressed and substantially covered by the second layers, and the second layers substantially cover a second one of the claddings inside the structure spaces.

A building component utilizing a pourable polyurethane or structural foam that can be used for floors, walls, and roof assemblies with a frame with an interior, back or a front, multiple partition beams forming cells in said frame, pourable polyurethane or structural foam exterior backing attached to said frame back. The structural foam is poured into said cells to a desired level, and after said structural foam is poured into said cells, said interior backing is attached to said frame front. Cabling is used to improve movability of the invention, and improve on wind loading and seismic requirements of the present invention. Safety is also improved during the manufacturing process, loading, unloading, and in final assembly through the use of cabling.

An insulation product may include a container, a first insulation material forming a first layer inside the container, and a second insulation material forming a second layer inside the container, and the first layer is compressed by the second layer. A structure in a building may include studs, first and second claddings mounted to opposite sides of the studs, and structure spaces defined between the studs and the opposing claddings. A first insulation material may include first layers on and substantially covering a first one of the claddings inside the structure spaces. In addition, a second insulation material may have second layers inside the structure spaces. The first layers are compressed and substantially covered by the second layers, and the second layers substantially cover a second one of the claddings inside the structure spaces.