A glass panel unit having an exhaust pipe not protruding from the glass panel unit and an evacuation port tightly sealed, a glass window. A glass panel unit includes a first panel, a second panel, a seal member having a frame shape, a pore sealing material, and a bonding portion. The seal member hermetically bonds a peripheral portion of the first panel and a peripheral portion of the second panel together such that a hermetically sealed space in an evacuated state is formed between the first panel and the second panel. The pore sealing material hermetically seals an evacuation port formed in one of the first panel and the second panel. The bonding portion is bonded to the first panel and the second panel at part of a peripheral portion of the evacuation port and to suppress the first panel and the second panel from separating from each other.

A door for a refrigerated merchandiser including a case that defines a product display area. The door includes a frame and a first glass pane coupled to the frame. The first glass pane has heat-absorbing glass and is configured to be positioned adjacent an ambient environment surrounding the refrigerated merchandiser to absorb radiation from the ambient environment. The door also includes a second glass pane coupled to the frame and configured to be positioned adjacent the product display area. The second glass pane includes a conductive coating. The door further includes a third glass pane positioned between and spaced from the first glass pane and the second glass pane, and has a low emissivity coating.

An insulating glass unit (10) is formed from a plurality of transparent layers (16, 18, 20), in which at least one illuminable panel (20) is arranged between at least two mineral glass panels (16, 18). The mineral glass panels (16, 18) are held at a defined distance from one another by at least one spacer element (14). The illuminable panel (20) is held at least on one longitudinal marginal edge (24) by the spacer element (14). The spacer element (14) is formed by at least one hollow profile (15), which preferably comprises a plurality of adjoining hollow chambers (26, 28). The outer mineral glass panels (16, 18) each adjoins at least two lateral surfaces of the hollow profile (15). The illuminable panel (20) rests on or against the intermediate hollow chamber (28). An illumination element (32) is arranged within the intermediate hollow chamber (28).

An insulated glass unit is described and includes at least a first glass layer, a second glass layer and a third glass layer disposed therebetween. The third glass layer is separated from the first glass layer and the second glass layer by first and second sealed gap spaces. The third glass layer has a low CTE as compared to the CTE of the first and/or second glass layers. In some instances, the third glass layer has a CTE of less than 7010.sup.7/ C. over a temperature range of 0-300 C.

Methods and materials to fabricate electrochromic including electrochemical devices are disclosed. In particular, emphasis is placed on the composition, fabrication and incorporation of electrolytic sheets in these devices. Composition, fabrication and incorporation of redox layers and sealants suitable for these devices are also disclosed. Incorporation of EC devices in insulated glass system (IGU) windows is also disclosed.

A dynamic multi-pane insulating assembly and system including methods for dynamically maintaining the thermal resistance value of the assembly and system. The dynamic multi-pane insulating assembly and system includes first and second gas permeable panes defining an evacuated gap in communication with a vacuum source; a first exterior pane spaced from the first gas permeable pane defining a first pressurized gap in communication with a source of pressurized gas; and a second exterior pane spaced from the second gas permeable pane defining a second pressurized gap in communication with the source of pressurized gas.

A spacer for insulating glazing units is presented. The spacer includes a main body having first and second pane contact legs that are parallel, first and second glazing interior legs, an outer leg, first and second hollow chambers extending along an extension direction, and a groove for receiving a pane. Arranged in the groove, there is an extruded pane receiving socket formed from a polymer having a Shore hardness A in a range from 10 to 80 as measured per DIN ISO 7619-1. In a surface of the pane receiving socket, a receiving recess running substantially parallel to the groove and decreasingly tapering viewed in cross-section in a direction of the outer leg is implemented. Also described are a method for producing the spacer and a multiple insulating glazing unit having the spacer.

An adapter element for connecting a pane to a spacer having a fastening groove, wherein the adapter element includes at least one receiving profile for securing to the pane and at least one lower part for fixing to the spacer, and the lower part is designed to positively fit the fastening groove of the spacer.

An insulating glazing includes two glass sheets spaced apart by an air- or gas-filled cavity, a spacer arranged at a periphery of the glass sheets and that keeps the glass sheets spaced apart, a transparent spacer made of transparent plastic and placed on at least one of the sides of the glazing, and a first leaktight barrier that is leaktight to water, formed by a structural seal, a material of which is watertight, and a second leaktight barrier that is leaktight to gases and to water vapor, the leaktight barriers being made of transparent material, wherein the spacer includes on at least one of its internal and external faces, the internal and external faces being respectively facing and on the opposite side from the gas-filled cavity, a coating which is thin and constitutes the second transparent barrier, the coating and the transparent spacer forming a single assembly.

An energy-saving security composite window comprising a peripheral side frame and glass installed on the side frame, in which the side frame is of composite structure. A rectangular high strength metal pipe is located centrally to serve as a main body of the side frame and a cavity of the rectangular high-strength metal pipe is filled with a filling material. A plurality of non-metal profiles are respectively fixed on an outer surface of the rectangular high-strength metal pipe, and an installation groove for installing glass is formed between the rectangular high strength metal pipe and the non-metal profile. An external profile is a metal alloy material, a wooden material, a plastic material, or a glass material fixed on an outer surface of the non-metal profile. The performances of external windows of buildings, such as heat insulation, heat preservation, energy saving, sound insulation, and wind pressure resistance, is improved.