A window frame insulation method for constructing a warm house of the present invention, provided in order to achieve the above objective, comprises: a placement preparation step (S10) for opening a portion of a wall body so as to insert a window frame before the wall body is formed, and forming a mold so as to form a stepped portion on the outer side of the wall body; a placement step (S20) for placing concrete so as to form the wall body within the mold; a preservation step (S30) for conservation of the concrete formed within the mold in order to prevent harmful effects; a window frame installment step (S40) for installing a window frame on the inner side of the opened wall body; an insulation material installment step (S50) for installing insulation material in the wall body except for the window frame; and a finishing material installment step (S60) for installing finishing material on the outer side of an outer insulation material.

A window frame insulation method for constructing a warm house of the present invention, provided in order to achieve the above objective, comprises: a placement preparation step (S10) for opening a portion of a wall body so as to insert a window frame before the wall body is formed, and forming a mold so as to form a stepped portion on the outer side of the wall body; a placement step (S20) for placing concrete so as to form the wall body within the mold; a preservation step (S30) for conservation of the concrete formed within the mold in order to prevent harmful effects; a window frame installment step (S40) for installing a window frame on the inner side of the opened wall body; an insulation material installment step (S50) for installing insulation material in the wall body except for the window frame; and a finishing material installment step (S60) for installing finishing material on the outer side of an outer insulation material.

The present application relates to a construction member 3D printing spray bead with vibrating rod which includes a frame, a receiving hopper, a vibrating rod and a lifting device; the Vibrating'rod includes a cylindrical vibrating body and cable wires connected to the cylindrical vibrating body. The lifting device includes a set of guide wheels, clamp, wire rope, electrical winding drum. Wherein, the cylindrical vibrating body is located within the receiving hopper. The cable wire which is connected to the cylindrical vibrating body extends outside the receiving hopper via the space between the wheels of the set of guide wheels arranged above the receiving hopper. One side of the clamp clamps the cable wire that is outwardly extended, while the other side of the clamp clamps the wire rope. The wire rope is wrapped around the electrical winding drum.

Concrete wall supports that reduce or eliminate wall movement due to exterior horizontal forces. One support is a bracket mounted to a floor joist with a plate extending below the top of the wall and two legs extending from the plate and attaching to the joist. One leg is above the concrete wall on one horizontal side of the plate, and the other leg is on the opposite side of the plate. Another support has a plate that extends below the top of the wall with two legs on opposite sides of the joist above the wall. A leg attaches to the lower edge of the joist. A support against shear forces includes a highly water permeable aggregate composite disposed in the voids of the wall, with a supportive strip that is enclosed in the aggregate composite and extends out of the voids to the face of the wall.

An improved lath is disclosed having a water drainage layer provided in association with the lath. The water drainage layer serves to remove water that might otherwise build up between the lath and wall structure.

A pedestal for supporting a partition and a method for a partition. The pedestal includes a base for mounting onto a floor, the base having a peripheral outer surface. The pedestal also includes a body having a first end opposite a second end and an inner surface proximate the first end interfacing with the base peripheral outer surface. A cap is coupled to the body proximate the second end, and a bracket is coupled to the cap for coupling with a partition. The method includes connecting a base to a floor, coupling a body of to the base, coupling a sleeve to the base on which is coupled a bracket, and coupling the partition to the bracket.

A wall structure and a method for forming a wall structure is provided using three-dimensional printing of extruded building material applied to a surface of a building structure. According to one embodiment, the wall structure includes a pair of outer wythes spaced from an inner wythe. The outer wythes can include a core extending between the pair of outer wythes and toward the inner wythe. A protrusion can also extend toward the inner wythe a spaced distance from the inner wythe or entirely toward and adjoining the inner wythe. The core is configured with an inwardly facing spaced opposed surfaces of the outer wythes surrounding a vertically extending rebar, with grout surrounding that rebar. Horizontally extending support pins can be spaced parallel from each other and extend from the protrusions and into the inner wythe.

A wall structure and a method for forming a wall structure is provided using three-dimensional printing of extruded building material applied to a surface of a building structure. According to one embodiment, the wall structure includes a pair of outer wythes spaced from an inner wythe. The outer wythes can include a core extending between the pair of outer wythes and toward the inner wythe. A protrusion can also extend toward the inner wythe a spaced distance from the inner wythe or entirely toward and adjoining the inner wythe. The core is configured with an inwardly facing spaced opposed surfaces of the outer wythes surrounding a vertically extending rebar, with grout surrounding that rebar. Horizontally extending support pins can be spaced parallel from each other and extend from the protrusions and into the inner wythe.

A dry papercrete mix containing a pulp of fiber material such as newsprint and sharp sand, Portland cement and adding additional sand and/or pumice. The resulting dry, granular mix can then be handled stored and used in the manner which is conventional for concrete. The dry papercrete mix can be fortified with a fiber form of basalt which can be added to or substituted for all or a portion of the cellulose fiber content of the dry papercrete mix to provide a stronger structure when hydrated and cast into a desired shape with only a small increase in weight. Basalt reinforcing bars and meshes may be included in shapes cast from the hydrated mix in combination with or substitution for steel reinforcing structures. Including basalt in the mix and in reinforcing systems allows the design of joints between structural modules to provide exceptional strength in a unitary structure so formed.

A dry papercrete mix containing a pulp of fiber material such as newsprint and sharp sand, Portland cement and adding additional sand and/or pumice. The resulting dry, granular mix can then be handled stored and used in the manner which is conventional for concrete. The dry papercrete mix can be fortified with a fiber form of basalt which can be added to or substituted for all or a portion of the cellulose fiber content of the dry papercrete mix to provide a stronger structure when hydrated and cast into a desired shape with only a small increase in weight. Basalt reinforcing bars and meshes may be included in shapes cast from the hydrated mix in combination with or substitution for steel reinforcing structures. Including basalt in the mix and in reinforcing systems allows the design of joints between structural modules to provide exceptional strength in a unitary structure so formed.