An installation system to fabricate the multiple glazing units at the installation site is provided. The installation system includes a primary glazing unit, a secondary glazing unit, a spacer element, a primary sealant, a fixture, a secondary sealant and a dispenser. The installation system includes a fixture to apply the primary sealant on the spacer element. The installation system also includes a dispenser to apply the secondary sealant to a clearance between the primary glazing unit and the secondary glazing unit.

A sash for doors or windows includes two spaced apart glass sheets, a spacer element interposed between the sheets to define a closed inner perimeter zone and an open outer perimeter zone. A structural sealing/adhesion component runs along the outer perimeter zone and occupies a volume to permit contact with the spacer element and the glass sheets. An element for housing accessory components for supporting and/or operating the sash is associated with the structural component, for each side of the glass sheets. Each element includes a rigid profile associated with the structural component and having a closed base side, two flaps each formed by a stretch perpendicular to the base side and a recessed stretch, parallel to the base side, to form a channel with an opening. A rigid plate is adhesively associated with one of the glass sheets to cover an outer edge thereof.

A spacer for multipane insulating glazing units includes a polymeric main body having two pane contact surfaces running parallel to one another, a glazing interior surface and, an adhesive bonding surface. The pane contact surfaces, and the adhesive bonding surface are connected directly or via connection surfaces. The spacer also includes an insulation film, which is applied on the adhesive bonding surface.

A glass panel unit according to an example of the present disclosure includes a first glass panel and a second glass panel disposed to face the first glass panel. The glass panel unit includes: a seal having frame shape and hermetically binding the first glass panel and the second glass panel together; and a depressurized space surrounded by the first glass panel, the second glass panel, and the seal. The glass panel unit includes spacers between the first glass panel and the second glass panel. The spacers include a macromolecular resin material including molecular chains. Of the molecular chains, the number of molecular chains oriented in an orthogonal direction is larger than the number of molecular chains oriented in a counter direction. The orthogonal direction is a direction orthogonal to the counter direction, which is a direction in which the first and second glass panels face each other.

According to some implementations, a multi-pane window assembly and a multi-pane window insert are described. The multi-pane window insert includes a first pane formed of polycarbonate resin thermoplastic material and a second pane formed of polycarbonate resin thermoplastic material that is separated from the first pane by a spacer. A planar surface of each the first pane and the second pane are oriented substantially parallel to one another. A framing structure is provided for housing the plural panes and a gasket is provided for sealing the multi-pane window to a frame on installation. The multi-pane window insert is configured to be installed on an interior surface of a pre-existing window frame to improve the thermal, acoustic, and light transmittance properties of a multi-pane window assembly.

A method for manufacturing a glass panel unit includes a glue arrangement step, an assembly forming step, a first melting step, an evacuation step, and a second melting step. The first melting step includes melting a hot glue, bonding a first and second panel with the glue, and forming an internal space. The first melting step includes a first temperature raising step, a first temperature maintaining step including maintaining the temperature of the assembly at a temperature equal to or higher than a softening point of the hot glue, and a first temperature lowering step, which are performed in this order. The first temperature lowering step includes: an anterior temperature lowering step including lowering the temperature of the assembly; a middle temperature maintaining step including maintaining the temperature of the assembly; and a posterior temperature lowering step including lowering the temperature of the assembly, which are performed in this order.

Embodiments described include bus bars for electrochromic or other optical state changing devices. The bus bars are configured to color match and/or provide minimal optical contrast with their surrounding environment in the optical device. Such bus bars may be transparent bus bars.

A connecting element, in particular for contacting an electrically conductive coating and/or an electrically controllable functional element in an insulated glazing, includes at least one flat conductor, which is arranged on a first side of an electrically insulating carrier film, and the flat conductor has at least one first connection region with at least one first solder deposit and at least one second connection region with at least one second solder deposit, and at least one second adhesive layer, which is arranged below and/or next to the second connection region on a second side of the carrier film facing away from the first side.

A side glazing for a transport vehicle, particularly glazing for a train, the glazing being fixed multiple glazing, the glazing including at least one connecting bridge which is separate from the glazing frame structure and makes a connection between a peripheral edge of the lamination and a surface, situated transversely opposite, on the other side of the glazing cavity.

An embodiment window includes a first transparent plate, a second transparent plate spaced apart from the first transparent plate, a spacer located between an outer edge portion of the first transparent plate and an outer edge portion of the second transparent plate to space the first transparent plate and the second transparent plate apart from each other, a gas duct configured to allow a gas space to communicate with a region outside the window, wherein the gas space is defined by the first transparent plate, the second transparent plate, and the spacer, and a gas managing device comprising a gas injection part connected to the gas duct and configured to inject a gas into the gas space.