A method and device for assembling an insulating glass panel includes: a TPS station for applying a paste-like TPS strand onto a standing glass sheet edge which includes a horizontal conveyor; a rotation station with a horizontal conveyor rotatable about a vertical axis of rotation; a pressing station for joining two glass sheets that have each been provided with a TPS strand to form the insulating glass panel including two horizontal conveyors running parallel to one another; and a controller for directing two glass sheets that are supplied to the rotation station one after another and each provided with a TPS strand into the pressing station by rotating one of the glass sheets and for joining same in said pressing station to form the insulating glass panel.

A method and device for assembling an insulating glass panel includes: a horizontal conveyor and primer station for applying a strip-like primer along a standing glass sheet edge; a horizontal conveyor and TPS station for applying a paste-like TPS strand, that subsequently solidifies, onto a standing glass sheet edge; a rotation station for rotating glass sheets arranged downstream of the TPS station having a horizontal conveyor rotatable about a vertical axis of rotation; a pressing station for joining the glass sheets together including two parallel horizontal conveyors; and a controller for directing two glass sheets supplied to the rotation station one after another into the pressing station by rotating one of the glass sheets and for joining same in said pressing station to form the insulating glass panel. One glass sheet has a primer strip and TPS strand and the other has a primer strip.

Various embodiments provide a method for applying a spacer to a planar substrate, comprising supplying the spacer to be adhered to the planar substrate; defining a first notch, a second notch, and a third notch in the spacer; applying an adhesive to the spacer; translating the spacer in a longitudinal direction; aligning a first end of the spacer with a first corner of the planar substrate; feeding the spacer and the planar substrate between a front carriage and a rear carriage along a longitudinal axis of an unadhered portion of the spacer while pressing the spacer against the planar substrate to adhere a portion of the spacer being pressed by the front carriage to the planar substrate, and rotating, with a six-axis robot, the planar sheet and adhered portion of spacer.

The present invention refers to a Vacuum Insulating Glazing (VIG) able to provide excellent thermal insulation to the transparent components of curtain walling systems in buildings and to cabinets for domestic or commercial refrigerators, and to a process for its manufacture.

An assembly includes: a pair of glass substrates; a peripheral wall disposed between the glass substrates; partitions; an evacuation port; and air passages. The partitions are provided to partition an internal space, surrounded with the glass substrates and the peripheral wall, into an evacuation space and a ventilation space. The evacuation port connects the ventilation space to an external environment. The air passages are used to evacuate the evacuation space through the evacuation port. The air passages include particular air passages arranged in a second direction perpendicular to a first direction, in which the glass substrates face each other, to constitute a ventilation path running through the internal space in the second direction.

A foam spacer applicator may include: a conveyer unit configured to automatically transfer a glass panel; a foam head unit disposed at a predetermined distance from the front side of the conveyer unit, and configured to automatically supply and bond a spacer to the glass panel transferred from the conveyer unit through a combination of an X-axis horizontal operation and a Y-axis elevation operation through an elevation guide plate disposed with a vertical structure; and a magazine unit disposed at a predetermined distance from the rear side of the foam head unit, and configured to inject and apply a sealant to both surfaces of the spacer while adjusting tension of the spacer, and automatically supply the spacer to the foam head unit.

A façade glazing with a metal frame and an insulating glazing unit inserted into the frame, which unit has at least two glass panes and a spacer and sealing profile extending circumferentially therebetween close to their edges, wherein at least one RFID transponder is attached to the insulating glazing unit as an identification element and wherein the frame engages around the edges of the insulating glazing unit and, at the same time, covers the at least one RFID transponder in the through-vision direction (arrow A) through the glass panes, wherein at least one separate metal coupling element is inserted into the frame adjacent the transponder for coupling out and coupling in HF radiation transmitted via the transponder to the outside of the façade glazing and received from the outside.

A glass panel unit assembly includes: a pair of glass substrates arranged to face each other; a peripheral wall; a partition; an air passage; and an evacuation port. The peripheral wall has a frame shape and is disposed between the pair of glass substrates. The partition partitions an internal space, surrounded with the pair of glass substrates and the peripheral wall, into a first space and a second space. The air passage connects the first space and the second space together. The evacuation port connects the second space to an external environment. The partition is lower in height than the peripheral wall.

Certain example embodiments relate to the use of a ceramic frit that dissolves an already-applied thin film coating (disposed via a physical vapor deposition (PVD) process such as sputtering, or other suitable process). In certain example embodiments, the ceramic frit is aggressive in chemically removing the coating on which it is disposed, e.g., when exposed to high temperatures. The frit advantageously fuses well with the glass, provides aesthetically desired colorations, and/or enables components (e.g., insulated glass (IG) unit spacers) to be reliably mounted thereon, in certain example embodiments. Associated coated articles, IG units, methods, etc., are also contemplated herein.

An insulating glazing unit includes a spacer which is shaped around the periphery to form a spacer frame and delimits an inner region, a first glass pane, which is arranged on a pane contact surface of the spacer frame, and a second glass pane, which is arranged on a second pane contact surface of the spacer frame, and the glass panes project beyond the spacer frame and form an outer region, which is filled, at least in sections with a sealing element, wherein an RFID transponder is arranged in the outer region or in the outer edge region of the glass panes, and a strip-shaped coupling element is electromagnetically coupled to the RFID transponder.