A spacer construction for insulating glass for windows comprised of thin sheets of metal, such as stainless steel, formed with a first bottom side panel wherein the first bottom side panel joins first and second spaced, typically diverging, lateral side walls or panels. A second inside wall of the spacer assembly is spaced from the bottom side of the first section or channel and joins, typically by welding, to the lateral side walls of the first section thereby forming a tube or chamber into which desiccant may be placed. A cushion material layer is positioned over and on the bottom side panel and is covered by a polymeric sheet affixed or bonded to the lateral sides to form an internal chamber filled with desiccant. The desiccant is positioned to impact against the film or sheet bonded to the bottom side panel and at least a portion of the lateral side walls of the channel enabling the assembly to effectively accommodate bending forces and stress upon bending of the spacer.

A spacer is provided for an insulating glazing unit that includes at least two spaced-apart glazing panes connected along their edges via the spacer in a mounted state in which the spacer is mounted at the edges to limit an interspace, which is defined between the glazing planes and is filled with gas. The spacer has an inner wall (14) connecting side walls (11, 12) on an inner side that faces the interspace. The inner wall (14) includes a recess portion (14rs, 14rt, 14rc) that enables the length of the inner wall to change in the width direction in response to an external pressure force or an external tensional force applied to the side walls (11, 12).

A spacer for multipane insulated glazings, includes a polymeric main body, including two pane contact surfaces running parallel to one another, a glazing interior surface, and a base surface, wherein the pane contact surfaces and the base surface are connected to one another directly or via connecting surfaces and an insulating film, which has at least one metallic or ceramic layer and is applied on the polymeric main body, wherein the insulating film covers the base surface and the two pane contact surfaces completely and the glazing interior surface at least partially.

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.

An insulating glazing unit extends along a plane, P, defined by a longitudinal axis, X, and a vertical axis, Z; having a width, W, measured along the longitudinal axis, X, and a length, L, measured along the vertical axis, Z, and includes a first glass pane that faces outside and has two major surfaces extending along a plane, P. A second glass pane faces inside and has two major surfaces extending along a plane, P. A spacer maintains a distance, D, between the first and second glass panes, creating a space, S. An antenna unit comprises an antenna and is fixed between the first and second glass panes with a fixing portion for fixing the antenna to one of the glass panes and maintaining the antenna at a distance, Da1, from the inner surface of the first glass pane to create a space, SI, through which gas can circulate.

This disclosure provides spacers for smart windows. In one aspect, a window assembly includes a first substantially transparent substrate having an optically switchable device on a surface of the first substrate. The optically switchable device includes electrodes. A first electrode of the electrodes has a length about the length of a side of the optically switchable device. The window assembly further includes a second substantially transparent substrate a metal spacer between the first and the second substrates. The metal spacer has a substantially rectangular cross section, with one side of the metal spacer including a recess configured to accommodate the length of the first electrode such that there is no contact between the first electrode and the metal spacer. A primary seal material bonds the first substrate to the metal spacer and bonds the second substrate to the metal spacer.

A door assembly including a first glass pane, a second glass pane, and a spacer positioned between the first glass pane and the second glass pane such that the first pane and the second pane are separated by the spacer. The door assembly also includes an element that is coupled to the first glass pane and the second glass pane and positioned exterior of the spacer. The spacer and the element cooperate to at least partially define a seal passage, and a clear material is disposed in the seal passage to seal the space, the clear material configured to provide structural support to the assembly.

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.

A network system in an enclosure includes one or more interactive targets such as tintable windows, HVAC components, sensors, computing devices, media display devices, and/or service devices. Diverse types of local and remote interfaces are employed for facilitating remote (e.g., indirect) manipulation of the interactive target(s), for example, using a digital twin (e.g., representative virtual model) of a facility and/or a mobile circuitry of a user. The environment and/or targets may be controlled according to preferences and/or requests of its user(s).

An insulating glazing includes a first a second pane, a spacer between the first and second pane that is fixedly connected to the first and second pane in a water-vapor-tight manner in each case, which spacer has two parallel pane contact walls, an outer wall, and a glazing interior wall and an interior, and a water-tight sealant strip running around the outer wall between the first and second pane. A pressure-equalizing element is inserted into the sealant strip and the spacer, which pressure-equalizing element is open to the surrounding atmosphere and to the interior of the spacer or to the glazing interior between the first and the second pane and is implemented such that it provides a gas connection having a pressure-equalizing function between the atmosphere and the interior of the spacer or the glazing interior which gas connection is temporally limited due to aging and/or atmospheric influences.