An automatic device and an automatic method for filling with gas other than air the insulating glazing unit composed of at least two glass panes and at least one spacer frame. The device comprises mechanisms for flattening the glass panes when they are not sufficiently flat, for example in the case of laminated or tempered panes. This allows to perform in an optimum manner the filling with gas and to process insulating glazing units with special spacer frames.

There is provided a multi-layered glass in which two glass plates are placed such that they form a space via a spacer placed in a peripheral part of glass plates, wherein at least one low-emissivity film, which includes a plastic film and a Fabry-Perot interference filter formed on one side or both sides of the plastic film, is placed in the space, whereby space is divided; each of gaps between the glass plates and the spacer, and between the low-emissivity film and the spacer is sealed with a primary sealing material; a gap between the glass plates outside of the primary sealing material and the spacer is sealed with a secondary sealing material; and a reinforcement material is placed inside of the secondary sealing material. The multi-layered glass has a good appearance and excellent heat-insulating properties.

A corner connector for connecting two hollow profile spacers of insulating glazing units, includes a first leg and a second leg, which are connected to one another via a corner region, and a first electrical supply line, wherein the first leg and the second leg enclose an angle , where 45<<120, the first leg, the second leg, and the corner region are formed in one piece, at least the corner region surrounds the first electrical supply line, and the first electrical supply line protrudes out of the corner region.

A spacer with an integrated ribbon cable for insulating glazings includes a main body including two pane contact surfaces, a glazing interior surface, an outer surface, a hollow chamber, and at least one ribbon cable on the outer surface, wherein the ribbon cable is materially bonded to the outer surface.

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.

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.

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%.

An insulating glazing includes at least one first pane element, at least one spacer, and at least one connector. 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. The connector has at least one first electrically conductive conductor element such that an electrical connection can be established between an external power source and the first pane element via the first conductor element.

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 glass panel support structure supports multi-glazed glass of which a circumferential edge part is bonded to a frame that frames all sides. The glass panel support structure includes a first structural sealant that bonds an indoor-side glass plate of the multi-glazed glass and the frame over an entire circumference, and a spacer provided between glass plates of the multi-glazed glass over the entire circumference. Along a first direction perpendicular to an indoor and outdoor direction of the multi-glazed glass, a position of an inner circumferential surface of the spacer is identical with a position of an inner circumferential surface of the first structural sealant or is located on outer circumferential side with respect to position of the inner circumferential surface of the first structural sealant.