The present invention relates to an insulation body based a hard, fine-cell and open-cell polyurethane/polyisocyanurate foam with a barrier film, and a method for producing same.

A multi-layer device comprising a first substrate, a first electrically conductive layer on a surface thereof, and a first current modulating layer, the first electrically conductive layer having a sheet resistance to the flow of electrical current through the first electrically conductive layer that varies as a function of position.

A dwelling wall includes: a vacuum heat-insulating material including an outer cover material, and an inner member which is sealed in a tightly closed and decompressed state on the inside of the outer cover material; and a wall material. In addition, the vacuum heat-insulating material is disposed on a rear surface side of the wall material, and the inner member is configured of a material which does not generate hydrogen in a case of coming into contact with moisture of liquid. According to the configuration, even in a case where the vacuum heat-insulating material used in the dwelling wall is ruptured and water of liquid comes into contact with the inner member, it is possible to realize excellent stability of the dwelling wall.

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 80×10.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 65×10.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 20×10.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 13×10.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 insulated panel (VIP) and a method of manufacturing a VIP includes a rigid core material having high insulation and low conductivity properties. The rigid core may be made of an inorganic material that effectively mimics a porous silica core material. The core material includes large particles of an inorganic material having a diameter in a range of 10 μm to 50 μm. A portion of these large particles may be ground into small particles having a diameter of less than 1 μm. The small particles are mixed with a portion of the large particles to form a core material which is then mixed with a fiber skeleton and compacted under vacuum along with a fibrous skeleton for structure. The resulting structure provides a porosity ranging from 10 nm to 1 μm in diameter.

The disclosed technology provides a module useful in constructing an energy efficient, durable building structure, the module including walls to form a vacuous, sealed chamber substantially void of structural elements, materials and gaseous molecules. One or more ribs are affixed to or formed integral with an exterior surface of the exterior wall of the module, extending the width of the module. The disclosed technology further provides a vacuum apparatus which may be incorporated in communication with the vacuous, sealed chamber, for creating and maintaining a vacuum within the module. A method of controlling heat transfer within a structure is also provided, utilizing the modules as herein disclosed, each module being coupled with a vacuum apparatus in communication with the vacuous, sealed chamber, for creating and maintaining a vacuum within the module.

A vacuum adiabatic body according to the present invention includes at least one reinforcing frame which is installed along a corner of at least one of a first plate member and a second plate member constituting an inner wall and an outer wall of the vacuum adiabatic body and is provided as one body for reinforcing the strength, thereby being capable of reinforcing the strength of the vacuum adiabatic body which is applied to the three-dimensional structure.

An encased insulating panel includes a vacuum insulation panel in the form of a rectangular sheet including a compression-resistant porous material and a barrier envelope which in gastight manner encases the porous material, and at least one fixing strip having a width (l) and a length, the length being greater than the perimeter of the vacuum insulation panel, each fixing strip forming an envelope around at least part of four successive faces of the vacuum insulation panel and including two free ends which can be joined together to form an attachment flap, the or each fixing strip being assembled securely to the vacuum insulation panel.

A method for forming a super-insulating material for a vacuum insulated structure includes disposing glass spheres within a rotating drum. A plurality of interstitial spaces are defined between the glass spheres. A binder material is disposed within the rotating drum. The glass spheres and the at least one binder material are rotated within the rotating drum, wherein the binder material is mixed during a first mixing stage with the glass spheres. A first insulating material is disposed within the rotating drum. The binder material, the first insulating material and the glass spheres are mixed to define an insulating base. A second insulating material is disposed within the rotating drum. The secondary insulating material is mixed with the insulating base to define a homogenous form of the super-insulating material, wherein the first and second insulating materials occupy substantially all of the interstitial spaces.

The disclosed technology provides a module useful in constructing an energy efficient, durable building structure, the module including walls to form a vacuous, sealed chamber substantially void of structural elements, materials and gaseous molecules. One or more ribs are affixed to or formed integral with an exterior surface of the exterior wall of the module, extending the width of the module. The disclosed technology further provides a vacuum apparatus which may be incorporated in communication with the vacuous, sealed chamber, for creating and maintaining a vacuum within the module. A method of controlling heat transfer within a structure is also provided, utilizing the modules as herein disclosed, each module being coupled with a vacuum apparatus in communication with the vacuous, sealed chamber, for creating and maintaining a vacuum within the module.