An exterior building panel includes a panel body having a polymeric framing arrangement including an outer boundary portion extending around an outer perimeter of the panel body and a plurality of crossing frame members extending between opposed first and second sides of the outer boundary portion to define a plurality of cavities surrounded by the outer boundary portion, core insulation material disposed in each of the plurality of cavities, an insulation layer surrounding the framing arrangement and the core insulation material, and an insulating lamina coating covering the insulation layer.

A building structure assembly for use with constructing buildings (e.g., dwellings, offices, and so on) is described. In some embodiments, the building structure assembly includes a fillable container structure formed of a drop stitch fabric or material, and a removable shoring structure configured to position the container structure in a desired configuration when filled by building material, such as cement or concrete. In some cases, the container structure can include reinforcement components, which move into suitable positions when the container structure is filled with the building material.

A method of making an insulated material comprises melting a phase change material to form liquid phase change material, combining the liquid phase change material with an insulating material, and forming a composite insulation material in response to the combining. The insulating material can be a porous material that comprises a plurality of pores, and the liquid phase change material is disposed in the plurality of pores. The phase change material can also be stored in a container and used as layer in an insulation system.

Insulated wallboards are exposed interior insulation panels, for walls and ceilings, in occupiable spaces, that can be taped, finished, textured, and painted, which eliminates the need for gypsum board, and reduces or eliminates the need for other insulation, such as wall cavity insulation and exterior insulation. Insulated wallboard panels are formed by applying various combinations of thermal reflection layers such as aluminum foil; moisture resistance layer; or reinforcement layers over an insulating core. An enhanced surface or enhanced surface layer is provided on the interior-facing surface of the panel, to accept joint compound, paint, plaster, texture, or other interior finish. The core may be phenolic or other material with appropriate insulating and fire-retardant properties. The insulated wallboards may be applied directly to wood or metal framing, masonry, CMU, tilt-up concrete walls; or over existing gypsum board or other interior surfaces to retrofit additional insulation without disrupting exterior walls or roof.

A system includes a plurality of a clip, the clip comprises a securing mechanism, a first side, a second side, a bottom end, and a top end. During installation of an insulation system a plurality of the clip are coupled to a support beam and disposed within a plurality of notches of a second insulation board. The plurality of clips further include a width that is substantially equal to a width of the plurality of notches such that during the installation of the insulation system the plurality of clips are disposable within the plurality of notches to allow a second side of a first insulation board to contact a first side of the second insulation board and the securing mechanism secures a back surface of the first insulation board against the plurality of clips.

A radon gas and/or moisture abatement system (or method) is located under the concrete slab of a building. The system (or method) includes a multilayered mat having a first layer, a second layer, and a third layer sandwiched between the first layer and the second layer. The first layer is non-permeable and faces the concrete slab. The third (or sandwiched) layer is an entangled net. The second layer is permeable layer. The layers are bonded together. Whereby radon gas and/or moisture are inhibited from entering the building by passing through and collecting in the multilayer product.

A building structure assembly for use with constructing buildings (e.g., dwellings, offices, and so on) is described. In some embodiments, the building structure assembly includes a fillable container structure formed of a drop stitch fabric or material, and a removable shoring structure configured to position the container structure in a desired configuration when filled by building material, such as cement or concrete. In some cases, the container structure can include reinforcement components, which move into suitable positions when the container structure is filled with the building material.

A method of making an insulated material comprises melting a phase change material to form liquid phase change material, combining the liquid phase change material with an insulating material, and forming a composite insulation material in response to the combining. The insulating material can be a porous material that comprises a plurality of pores, and the liquid phase change material is disposed in the plurality of pores. The phase change material can also be stored in a container and used as layer in an insulation system.

A polyisocyanurate foam insulation product is produced from an isocyanate component and a polyol-containing component including a blowing agent. The polyol-containing component comprises one or more polyols, a fire retardant, and a hydroxyl-containing low-molecular-weight additive effective to increase the R-value per inch of the insulation product as measured at 40° F., as compared with an otherwise-identical formulation lacking the hydroxyl-containing low-molecular-weight additive. The polyisocyanurate foam insulation product may have an R-value per inch of at least 6.0 when measured at 40° F. and may have an R-value per inch of at least 5.5 when measured at 25° F. Suitable hydroxyl-containing low-molecular-weight additives may include triethanolamine, trimethylolpropane, N-methyldiethanolamine, 1,4 butanediol, or another suitable multi-functional alcohol or combination of multi-functional alcohols.

A polyisocyanurate foam insulation product is produced from an isocyanate component and a polyol-containing component including a blowing agent. The polyol-containing component comprises one or more polyols, a fire retardant, and a hydroxyl-containing low-molecular-weight additive effective to increase the R-value per inch of the insulation product as measured at 40° F., as compared with an otherwise-identical formulation lacking the hydroxyl-containing low-molecular-weight additive. The polyisocyanurate foam insulation product may have an R-value per inch of at least 6.0 when measured at 40° F. and may have an R-value per inch of at least 5.5 when measured at 25° F. Suitable hydroxyl-containing low-molecular-weight additives may include triethanolamine, trimethylolpropane, N-methyldiethanolamine, 1,4 butanediol, or another suitable multi-functional alcohol or combination of multi-functional alcohols.