An insulative construction product includes a polyurethane foam core and a mixture of Aerogel and carbon black that is disposed within the polyurethane foam core. The mixture of Aerogel and carbon black includes between 90 and 99 weight percent Aerogel and between 1 and 10 weight percent carbon black. The polyurethane foam core includes between 10 and 90 percent by volume of the of Aerogel and carbon black mixture and the construction product has an R-value of at least 8.0 R/inch.

Embodiments of the present invention are based, at least in part, on the discovery of methods for encapsulating fragile insulation materials within polyisocyanurate foam to thereby provide a construction board having an advantageous balance of insulating properties and mechanical durability.

A foil-wrapped vacuum insulation panel having a core, and an air-tight envelope in the form of a wrapping foil surrounding the core made of powder or granulate, wherein between the core made of powder or granulate and the air-tight wrapping foil, there is provided at least one intermediate layer of cardboard and/or paperboard, which completely envelopes the core made of powder or granulate in a powder-tight manner and is formed cuboid box which has approximately the same shape as the finished vacuum insulation element, wherein the powder or granulate is filled into the cuboid box in such an amount that the body is completely filled up to its very top, and the shape of the vacuum insulation element is acquired only via the cuboid box and not by the powder or granulate, while the structural integrity of the core is not sufficient to retain the shape of the core on its own without the surrounding cardboard or paperboard box.

A vacuum insulating material providing assembly, which can be used to provide the vacuum insulating material to the interior corners, exterior corners and/or window edge portions of a building, includes corner members positioned at the interior corners, exterior corners or window edges of the building, wherein the corner member has: a base plate; a first cantilever plate extending from one end of the base plate in the vertical direction; and a second cantilever plate extending from the base plate in the direction parallel to the first cantilever plate.

A vacuum heat-insulating material includes: an outer cover material; and a core material which is sealed in a tightly closed and decompressed state on the inside of the outer cover material. Outer cover material has gas barrier properties and satisfies at least one of a condition that a linear expansion coefficient is 8010.sup.5/ C. or lower when a static load is 0.05 N within a temperature range of 130 C. to 80 C., inclusive, a condition that an average value of a linear expansion coefficient is 6510.sup.5/ C. or higher when a static load is 0.4 N within a temperature range of 140 C. to 130 C., inclusive, a condition that an average value of a linear expansion coefficient is 2010.sup.5/ C. or higher when a static load is 0.4 N within a temperature range of 140 C. to 110 C., inclusive, and a condition that an average value of a linear expansion coefficient is 1310.sup.5/ C. or higher when a static load is 0.4 N within a temperature range of +50 C. to +65 C., inclusive.

A vacuum insulating material providing assembly, which can be used to provide the vacuum insulating material to the interior corners, exterior corners and/or window edge portions of a building, includes corner members positioned at the interior corners, exterior corners or window edges of the building, wherein the corner member has: a base plate; a first cantilever plate extending from one end of the base plate in the vertical direction; and a second cantilever plate extending from the base plate in the direction parallel to the first cantilever plate.

Method for producing an adjustable vacuum thermal and acoustical insulation panels comprise steps of manufacturing first and second vacuum telescoping insulating panels. The process of making a vacuum thermal and acoustical insulation system for modifying space intended to use for existing thermal insulation in some embodiments is comprised of the steps of providing air impermissibility for an existing space by covering internal surfaces of studs, joist, rafters and walls and space between them with sealant and coating and lining all these surfaces.

Self-standing, thermally-insulating, noise-insulating, seismically-insulating, water-insulating, electromagnetic-insulating superstructure, whose overall internal volume is filled with rigid and lightweight granules, in which the dwelling rooms are immersed. The lightweight granules are spherical, porous or hollow, they have no binder and are scattered. A gas-tight skin clads all the outer surface of the superstructure's shell and the walls of the dwelling quarters. Gas-tight bay-frames of conical outer shape are embedded in the openings and bays. The entire volume, made up of the scattered granules, the plates, the bay-frames and the gas-tight skin, is under gas-vacuum. This gas-vacuum is lifetime-controlled by a vacuum pump which is installed in situ. The outer casing and the inner walls are braced by the volume of granules stiffened by atmospheric pressure. A plurality of ion-polarized layers, vaporized on overlay metallized polymer vacuum sheets, are inserted between the rigid plates and the gasproof skin.

A thermally insulating planar component that extends in an extension plane and has a structural thickness orthogonal to the extension plane, the dimensions of the component in the extension plane being many times greater than its thickness measurement orthogonal to the extension plane, the component comprising a vacuum panel having an air-tight, evacuated metal foil envelope that is filled with highly dispersed ceramic powder, the metal foil envelope having two planar envelope walls arranged spaced from one another in the thickness direction and connected to one another by an edge region that spans the distance between the planar envelope walls in the thickness direction, each planar envelope wall having an inner surface that faces the other planar envelope wall and the highly dispersed ceramic powder and an outer surface that faces away from the other planar envelope wall and the highly dispersed ceramic powder is refined such that at least one of the planar envelope walls is designed in at least one deformation section as having a surface structure that increases the surface area of the planar envelope wall over that of a smooth surface structure, the component being curved about at least one curvature axis in the area of the deformation section such that the planar envelope wall is convex on its outer surface in the deformation section.

A display case door assembly for a temperature-controlled storage device includes an opening into the temperature-controlled storage device and a vacuum panel mounted within the opening. The vacuum panel includes a first vacuum pane of tempered glass, a second vacuum pane of tempered glass, and an evacuated gap between the first and second vacuum panes. The evacuated gap has a predetermined thickness within which a vacuum is drawn, thereby providing a thermal insulation effect for the vacuum panel. The vacuum panel further includes a plurality of spacers disposed within the evacuated gap and configured to maintain the predetermined thickness of the evacuated gap when the vacuum is drawn therein.