A glass panel includes a first glass substrate, a second glass substrate, a spacer profile at the periphery of the glass panel between the first and the second glass substrate. There is an intermediate substrate in the intermediate space between the first and the second glass substrates, the substrate having a first coefficient of thermal expansion, and means to maintain the intermediate substrate within the intermediate space. The panel also includes a second profile, having a second coefficient of thermal expansion, positioned facing the inner face of the spacer profile within the intermediate space between the first and second glass substrates of the glass panel. The second profile carries the means to maintain the intermediate substrate within the intermediate space. A difference between the first coefficient of thermal expansion and the second coefficient of thermal expansion is less than or equal to 20%.

A spacer for insulating glazing units with a polymeric main body composed of a first pane contact surface and a second pane contact surface running parallel thereto, a first glazing interior surface, a second glazing interior surface, an outer surface, a first hollow chamber, and a second hollow chamber, is realized with a groove to accommodate a pane runs parallel to the first pane contact surface and second pane contact surface between the first glazing interior surface and the second glazing interior surface, the first hollow chamber being adjacent the first glazing interior surface and the second hollow chamber being adjacent the second glazing interior surface, where the lateral flanks of the groove are formed by the walls of the first hollow chamber and the second hollow chamber, and a gas-permeable insert is contained in the groove or at least two inserts are mounted at a distance of at least 1 mm from one another.

A spacer for insulating glazing units is presented. The spacer has a polymeric main body with features that include a first pane contact surface, a second pane contact surface, a first glazing interior surface, a second glazing interior surface, an outer surface, a first hollow chamber, and a second hollow chamber. A groove to accommodate a pane is formed between the first glazing interior surface and the second glazing interior surface, with the first hollow chamber being adjacent the first glazing interior surface and the second hollow chamber being adjacent the second glazing interior surface. Lateral flanks of the groove are formed by walls of the first and second hollow chambers.

Insulated glazing units comprising first and second sheets of glazing material with a low pressure space there between are described. The major surface of the second sheet of glazing material not facing the low pressure space has a low emissivity coating comprising at least one layer of fluorine doped tin oxide thereon. There is a first anti-iridescence coating between the low emissivity coating and the second sheet of glazing material. Also described are insulated glazing units comprising three (first, second and third) sheets of glazing material with a low pressure space between first and second sheets of glazing material, and a second space between the first and third sheets of glazing material. There is a low emissivity coating on one or both major surfaces facing the low pressure space. The third sheet of glazing material has a low emissivity coating on both opposed major surfaces thereof.

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 materials and sealants suitable for these devices are also disclosed. Incorporation of EC devices in insulated glass system (IGU) windows is also disclosed.

An insulating glazing having at least two panels made of transparent or semi-transparent material is provided. At least one of these panels is a luminescent solar concentrator.

The invention relates generally to the field of construction, and in particular to the use of a glass unit instead of the opening sashes of windows and doors, without using sash profiles into which conventional insulating glass units or insulating glass units with one protruding outer pane are usually fixed. The adaptive insulating glass unit is intended for use on windows and doors pre-installed in an opening or facade, as well as for use in the production of new windows and doors, which in turn are used for glazing door and window openings (fixed glazing or one with a sash opening inward, sideways, outward or upward off the frame) in residential buildings, in public and industrial buildings, display structures. The technical result of the invention is a quicker and more accurate assembly of multi-chambered insulating glass units with glued-in profiles, increased light transmission, thermal insulation and soundproofing properties of existing window and door systems without the need to reconfigure production processes, without the need to readjust and replace equipment used in the production of windows, as well as increased light transmission, thermal insulation and soundproofing properties of window and door systems pre-installed in the openings and facades of buildings without the need to reinstall them. The adaptive insulating glass unit designed to be used instead of the opening sashes of windows and doors, without the use of sash profiles into which conventional insulating glass units or insulating glass units with one protruding outer pane are usually fixed, offers new prospects for the design of new window and door systems. The adaptive insulating glass unit contains two outer panes and at least one inner pane, spaced from each other by spacer frames placed between the panes. Moreover, the outer panes are always larger than the inner ones, and between them there is a profile inserted all the way to all the inner panes and simultaneously to one of the outer panes and glued to said outer pane by means of hard glue with additional fixation of the glued profile to another outer pane through the aid of a spacer element, with the gap formed between the profile and the outer pane to which the profile is not glued by means of hard glue filled with elastic glue and sealant, with the outer part of the profile adapted to fixing fittings and seals, which adapt the adaptive insulating glass unit to specific window systems.

Insulated assemblies, insulation units including an assembly, and methods of forming the assemblies and units are disclosed. Exemplary assemblies include a first pane of material, a second pane of material, and one or more monolithic insulating layers interposed between the first pane of material and the second pane of material. The insulating layer can exhibit a thermal conductivity less than 26 mW/(K.m).

An insulating glazing, in particular a triple glazing or a multiple glazing, with at least one first pane element, at least one spacer, and at least one connector, wherein the spacer and the connector are arranged next to each other such that they extend along a common longitudinal axis, wherein the spacer and the connector accommodate and position the first pane element. An electrically conductive coupling element is provided in the receiving groove of the connector such that an electrical coupling can be established between the connector and the first pane element for electrically connecting an external power source to the first pane element.

Disclosed is a pane unit (10), which comprises a frame structure (12) formed from a plurality of profiles (14), at least two outer panes (16, 16′), and at least one middle pane (18). The panes are each connected or attached to the frame structure (12). The pane unit (10) moreover comprises at least one functional element (20) used for the illumination of the at least one middle pane (18), which functional element (20) is inserted into at least one chamber (24) provided in the profiles (14). The plurality of profiles (14) are coupled with each other by means of at least one connection element (28), wherein the at least one connection element (28) engages with the profiles (14) in such a manner that the pane unit (10) is hermetically sealed.