The invention relates to a roof or skylight window comprising a frame and an insulated glazing unit, where the insulated glazing unit comprises a first glass pane (10) and a second glass pane (20) each having inner surfaces (11, 21) opposing each other, and a side seal (4) arranged between the first glass pane (10) and the second glass pane (20) creating a sealed cavity (40) between the glass panes (10, 20). The first glass pane (10) comprises an edge surface region (14) overlapping the side seal (4) along at least a first part of the side seal (4), wherein the edge surface region (14) comprises an enamel layer (16) comprising pigments reflecting near infrared light.

A device for delivering a sealant material includes a first nozzle having a first nozzle head and a second nozzle having a second nozzle head. The first and second nozzle heads each independently have an outlet, an inlet opposite the outlet, and an open channel that extends through a body of the nozzle heads from the inlet to the outlet. The first nozzle is spaced apart from the second nozzle to form a space between the nozzle heads to allow a component to enter a first side of the device and exit a second side of the device while passing by the first and second nozzle heads. A notch is formed through the body of each of the first and second nozzle heads at a side where the component exits the device to distribute a sealant material onto each side of the component.

A window glazing assembly that can convert an existing or already-installed window, or be used to assemble new construction windows as a multi-pane or multi-glazed window unit, is provided herein. In particular, the glazing assembly includes an attachment assembly (e.g., peel-and-stick double-sided adhesive tape) and one or more glazing layers. Some embodiments further include a spacer assembly comprising a plurality of spacer bars that may be individually installed, e.g., one by one, around the perimeter of the window such as, to the window sash, window frame, or glass window pane, itself. The glazing layer(s) can then be secured or adhered to the spacer assembly, for example, around the perimeter thereof. Some embodiments may include additional or intermediate glazing layers, providing additional insulating airspaces and enhanced performance.

The present invention deals with integrating methods for manufacturing and applying a spacer frame to a glass plate, particularly in the circumstance of increased sizes thereof, of the rigid type, i.e. which profiles essentially are formed by a hollow body having cross section close to the rectangular, micro-perforated in the wall facing the chamber of the insulating glass, where at least the wall facing the outer cavity intended for the secondary sealant is made of solid metal material or with a metal liner, the remaining walls or all the walls being capable of being made of plastic or metal, e.g. aluminum or stainless steel. Certain innovative elements of the devices implementing such methods are also claimed.

The claimed technical solution belongs to the means used in frame doors, windows or other locking elements, facade elements or internal partitions. The field of application of the claimed technical solution is construction, in particular, decoration of the facade, arrangement of the interior of the premises. In the inner part of the hermetic chamber, a layer of adhesive is applied to each sheet of glass, where the layer is applied in a continuous strip, which has a depth greater than the size of the fastening element used when installing the glass package unit. This ensures an increase in the strength and rigidity of the glass package unit.

A multi-glazed window assembly is presented herein. The assembly includes a plurality of glazing layers arranged in a parallel relation to one another and defining at least one insulating airspace there between. The assembly also includes a perimeter spacer assembly and a resilient foam outer wrapping. The perimeter spacer assembly is attached along a length of an interior surface of the outer wrapping defining at least one interior channel. An intermediate glazing layer is mounted within the channel while outer glazing layers are disposed on opposing sides of the intermediate glazing layer and laterally spaced therefrom. The resilient foam outer wrapping then extends entirely around a collective perimeter of the glazing layers, thereby creating a multi-glazed window assembly formed with a gasket-like foam outer surface and with minimal seams and material.

Examples of the present disclosure provide an overhead door panel. The overhead door panel includes a pair of parallel glass panes, a metal frame with parallel lateral stiles oriented perpendicular to the pair of parallel glass panes, a first seal system located at a first lateral stile, and a second seal system located at a second lateral stile, wherein the first seal system and the second seal system engage with at least one glass pane of the pair of parallel glass panes and a lateral stile of the parallel lateral stiles of the metal frame such that the first seal system and the second seal system are between the at least one glass pane and the lateral stile.

A spacer for insulated glass units includes a main body co-extruded from first and second plastics, the second plastic having lower thermal conductivity and higher flexibility than the first plastic. The main body includes first and second side walls arranged parallel to each other, a glazing interior wall connecting to the side walls, an outer wall, which is arranged substantially parallel to the glazing interior wall and connects the side walls to one another directly or via connecting walls, and a cavity, which is enclosed by the side walls, the glazing interior wall, and the outer wall or by the side walls, the glazing interior wall, the outer wall, and the connecting walls. The main body is designed as a hollow profile formed from the second plastic, in which hollow profile the first plastic is arranged, at least in some regions, on the inside directly adjacent the hollow profile.

In some embodiments, the invention provides a multiple-pane insulating glazing unit having a between-pane space. An aerogel layer is located in the between-pane space. Further, some embodiments of the invention provide a method of manufacturing such a multiple-pane insulating glazing unit. Still further, some embodiments provide a glazing assembly comprising a frame and a multiple-pane insulating glazing unit that includes an aerogel layer and is mounted in the frame. Finally, some embodiments provide a method of handling an aerogel sheet.

An insulating glazing unit includes two panes and a spacer, with two pane contact surfaces. A first and second pane contact surfaces are connected to, respectively, a first and a second pane via a sealant to form a glazing interior space and a glazing exterior space. At least one pane is provided on the side facing the glazing interior space at least partially with an electrically conductive coating and/or an electrically controllable functional element and two bus bars are provided for electrically contacting the electrically conductive coating and/or the electrically controllable functional element. A bus bar includes an electrically conductive adhesive tape. The electrically conductive adhesive tape includes an electrically conductive adhesion layer, a conductor track, and an opaque, electrically insulating cover. The electrically conductive adhesive tape is connected via the electrically conductive adhesion layer to the electrically conductive coating and/or to the electrically controllable functional element.