An energy-saving building system using a porous silicate material for thermal insulation, comprises a foundation, a retaining wall body, and a roof system. The foundation comprises a ground ring beam and columns, and a porous silicate thermal insulation material is cast around the ground ring beam and the columns; the porous silicate thermal insulation material is composed of an organic lightweight aggregate and a lightweight inorganic matrix, and the lightweight inorganic matrix is provided thereon with a plurality of micropores; the retaining wall body comprises an outer wall disposed on the ground ring beam, the outer wall comprises an outer side support body, an inner side support body, and the porous silicate thermal insulation material cast between the inner and outer side support bodies, and the outer side support body and the inner side support body are connected therebetween by means of a heat insulating connection member.

An energy-saving building system using a porous silicate material for thermal insulation, comprises a foundation, a retaining wall body, and a roof system. The foundation comprises a ground ring beam and columns, and a porous silicate thermal insulation material is cast around the ground ring beam and the columns; the porous silicate thermal insulation material is composed of an organic lightweight aggregate and a lightweight inorganic matrix, and the lightweight inorganic matrix is provided thereon with a plurality of micropores; the retaining wall body comprises an outer wall disposed on the ground ring beam, the outer wall comprises an outer side support body, an inner side support body, and the porous silicate thermal insulation material cast between the inner and outer side support bodies, and the outer side support body and the inner side support body are connected therebetween by means of a heat insulating connection member.

A louver canopy comprises a frame with a top disposed with parallel rafters; a plurality of louvers rotationally connected between the rafters and sequentially arranged along a length direction of the rafters, the louvers are disposed at intervals and parallel to each other, each of the louvers includes an elongated flashing; a baffle connected to a first long side of the flashing; an elongated first guide groove formed between the baffle and the flashing; When the louvers rotate to a closed state, an opening of the first guide groove faces upward, and a second long side of the flashing passes over a top of the baffle of an adjacent louver of the louvers and positions above the first guide groove of the adjacent louver.

To provide a laminate whereby, when a printed layer is formed by an inkjet printing system, the adhesion of the printed layer can be easily maintained and it is possible to obtain a printed matter having excellent durability; a printed matter using said laminate; and a method for producing the printed matter. The laminate comprises a film-shaped substrate 1 containing a first fluorinated polymer and a coating layer 3 present in contact directly with one side or each side of the substrate 1, wherein the coating layer 3 is a coating layer containing a second fluorinated polymer different from the first fluorinated polymer, the visible light transmittance of the substrate is 0% or more than 0%, and when it is more than 0%, the visible light transmittance difference expressed by the following formula (1), of the laminate, is at most 40%. Visible light transmittance difference=(visible light transmittance (%) of the substrate−visible light transmittance of the laminate)/visible light transmittance of the substrate×100 (%) (1).

An energy-saving building system using a porous silicate material for thermal insulation, comprises a foundation, a retaining wall body, and a roof system. The foundation comprises a ground ring beam and columns, and a porous silicate thermal insulation material is cast around the ground ring beam and the columns; the porous silicate thermal insulation material is composed of an organic lightweight aggregate and a lightweight inorganic matrix, and the lightweight inorganic matrix is provided thereon with a plurality of micropores; the retaining wall body comprises an outer wall disposed on the ground ring beam, the outer wall comprises an outer side support body, an inner side support body, and the porous silicate thermal insulation material cast between the inner and outer side support bodies, and the outer side support body and the inner side support body are connected therebetween by means of a heat insulating connection member.

Gypsum panels, methods for their manufacture, and systems and methods for monitoring environmental conditions with such panels are provided herein. The panels include a gypsum core having a first surface and an opposed second surface, a first facer material associated with the first surface of the gypsum core, and an environmental sensor assembly associated with the gypsum panel and configured to detect an environmental condition of the gypsum panel and wirelessly communicate data on the environmental condition to a reader.

Gypsum panels, methods for their manufacture, and systems and methods for monitoring environmental conditions with such panels are provided herein. The panels include a gypsum core having a first surface and an opposed second surface, a first facer material associated with the first surface of the gypsum core, and an environmental sensor assembly associated with the gypsum panel and configured to detect an environmental condition of the gypsum panel and wirelessly communicate data on the environmental condition to a reader.

Devices and associated methods are provided for improving ventilation of insulation material and building construction and renovation. Specifically, the present disclosure includes devices and system(s) to achieve the ventilation of exterior walls and roofs. Components of the system(s) consider shut-down of the ventilation process when it is not necessary, such as in winter, and in the event of fire, where the prevention of vertical and horizontal fire spread is desired.

Devices and associated methods are provided for improving ventilation of insulation material and building construction and renovation. Specifically, the present disclosure includes devices and system(s) to achieve the ventilation of exterior walls and roofs. Components of the system(s) consider shut-down of the ventilation process when it is not necessary, such as in winter, and in the event of fire, where the prevention of vertical and horizontal fire spread is desired.

A wooden module may include four cross-sectionally square longitudinal pieces of timber, at least six cross-sectionally square transverse pieces of timber, and at least two cross-sectionally square plugs, which may be connected to one another via a plurality of connection plugs. The four longitudinal pieces of timber may be arranged parallel to and spaced apart from one another such that the four longitudinal pieces of timber span a square. The at least six transverse pieces of timber may be arranged over a length of the four longitudinal pieces of timber and may be arranged between the four longitudinal pieces of timber. The at least two plugs may be arranged vertically parallel to one another and to at least four vertical transverse pieces of timber on at least two horizontal transverse pieces of timber and may project from a lateral face of the wooden module.