The present disclosure describes methods of forming thermal barriers or breaks in tubular structures configured for inclusion in a variety of construction products and building features, such as doors and windows. Methods involve using one or more connector members to couple complementary extrusion profiles, which may comprise aluminum or other conductive materials. A low-conductivity material may then be deposited directly over the connector members coupling the extrusion profiles to form thermal barriers therebetween. At least a portion of the extrusion profiles may be knurled to improve the bond strength between the low-conductivity material, which may comprise polyurethane, and the extrusion profiles. Specialized components may be unnecessary to form the thermal barriers, such that the same connector members used to couple the extrusion profiles may be used to form the thermal barriers.

The present disclosure describes methods of forming thermal barriers or breaks in tubular structures configured for inclusion in a variety of construction products and building features, such as doors and windows. Methods involve using one or more connector members to couple complementary extrusion profiles, which may comprise aluminum or other conductive materials. A low-conductivity material may then be deposited directly over the connector members coupling the extrusion profiles to form thermal barriers therebetween. At least a portion of the extrusion profiles may be knurled to improve the bond strength between the low-conductivity material, which may comprise polyurethane, and the extrusion profiles. Specialized components may be unnecessary to form the thermal barriers, such that the same connector members used to couple the extrusion profiles may be used to form the thermal barriers.

The present invention relates to an installation structure of a glass fixing gasket and a window glass panel fixing bracket, which fixes a window glass panel of a fixed window included in a sliding window system which comprises a segmented window frame and, more specifically, to an installation structure of a glass fixing gasket and a window glass panel fixing bracket, wherein the glass fixing gasket and the window glass panel fixing bracket are installed between a window frame portion which supports three sides (an upper surface, a lower surface, and one external side surface that is not a middle bar side surface) of a fixed window included in a sliding window and a window glass panel provided as a double-pane, in order to provide a sealing function for preventing ventilation and a function of stably fixing the window glass panel against high wind pressure (wind pressure resistance), and moreover, to ensure maximum heat insulation performance.

A thermal insulating profile includes: a first profile portion made of metal; a second profile portion made of metal; a thermal insulating material made of a foaming resin material, the thermal insulating material being configured to couple the first profile portion and the second profile portion to each other; an injection port formed, along a longitudinal direction of the thermal insulating profile, between the first profile portion and the second profile portion; and a closing member disposed at the injection port to close the injection port.

A thermal insulating profile includes: a metal profile including a first profile portion, a second profile portion, and a cavity forming portion in which an injection port along a longitudinal direction of the first profile portion and the second profile portion is formed and in which a cavity communicated with the injection port is formed between the first profile portion and the second profile portion, the cavity forming portion including a portion on a first profile portion side and a portion on a second profile portion side that are disposed with a gap therebetween; and a thermal insulating material formed from a foaming resin material and disposed in the cavity.

The present invention relates to a thermal insulation structure of a door frame in which a moving window (sliding window) constituting a sliding window system is installed, and more particularly, a two-side supporting frame window supporting both sides of a glass window constituting a sliding window system, more particularly, relates to an insulating structure in a side section of a door frame into which the side portion of the sliding window that is moved when closing the sliding window of the supporting frame window type is pocketed, that is, the insulating structure of the side section of the door frame.

A structural panel includes a shell having spaced first and second exterior panels and frame members adjacent edges of the panels, and at least one polymeric sheet disposed between the exterior panels and bonded to an adjacent exterior panel. The polymeric sheet is made of a thermoplastic material and has a plurality of openings through its thickness spaced apart by flat wall portions of the polymeric sheet. Stiffeners are disposed between the polymeric sheets and are secured by polymeric end caps. The end caps are made of a thermoplastic material and have a plurality of openings through their thickness for receiving the stiffeners. A foam insulation material fills substantially all the space between the polymeric sheets, stiffeners, and frame members in the shell interior. At least one blast- or ballistic-resistant core layer may be disposed adjacent the at least one polymeric sheet.

A method and apparatus for enabling a vacuum insulated glass (VIG) window to be substituted for and/or replace a non-vacuum insulated glass window in an existing window assembly frame structure is disclosed. A width of a VIG window is substantially less than that of existing non-vacuum insulated glass (IG) windows (e.g., a double, triple or quad pane windows). A replacement stop is provided that compensates for the difference between the larger width of a non-vacuum insulated glass window and a VIG window which has a smaller width, thereby enabling the VIG window to be easily and cost effectively installed in existing window configurations originally intended for non-vacuum insulated glass windows. The replacement stop may be used in the manufacture of VIG window units and/or to replace existing and/or already installed non-vacuum insulated glass windows.

There is provided a heat insulating window film disposed on the inside of a window, including: a support; and a fibrous conductive particles-containing layer disposed on the support, in which the fibrous conductive particles-containing layer contains fibrous conductive particles, the fibrous conductive particles-containing layer is disposed on a surface of the support on a side opposite to the surface of the window side, and a resistivity of the fibrous conductive particles-containing layer is equal to or greater than 1,000 /. The heat insulating window film is a heat insulating window film having excellent heat insulating properties and radio-wave transmittance. A heat insulating window glass and a window are provided.

A device adapted to deliver an insulation enhancing polyurethane foam within profiles used in doors, windows and related applications comprising an insulating material supply member (1) extending into a polyurethane forming and discharge member (2) adapted to enter and move linearly along a chamber (25, 35) of a thermally insulated sash or frame profile assembly and deliver therein a polyurethane foam that absolutely abuts onto the walls of the chamber without exerting undesirable stresses thereupon. The insulating material supply member (1) comprises independent pipes (8, 9) delivering a polyol constituent (A) and an isocyanate constituent (B) that are mixed together with a supply of air within a mixing compartment (4) of the polyurethane forming and discharge member (2) to produce the desired insulating material. The polyurethane supplying assembly starts injection at one end of the profile bar having an industrial standard length and moves reawards to fill the chamber with the polyurethane insulating material.