When being sealed, insulating glass blanks (5) are held in a sealing station (2) gripped at the base by grippers (17) of a gripper arrangement (16) and/or by suction heads (15) and rest at the top against a roller beam (7) fitted with rollers (8). As the insulating glass blank (5) is sealed, only the nozzle (11) of a sealing assembly (10) moves along the outer edge of the insulating glass blank (5), which is stationary during the sealing process. When the lower edge of an insulating glass blank (5) is sealed, grippers (17) engaging the lower edge are released and move away downwards. Sealed insulating glass is removed from the sealing station (2) by a removal robot (24) onto the side opposite the sealing assembly (10), moved to a temporary store and placed therein on A-bearing supports (29) and fan frames (30) sorted according to production lots.

Disclosed are a method and device for sealing insulated glass blanks, wherein the insulated glass blank is moved substantially continuously through a sealing station. When sections of the edge joint of the insulated glass blank that are oriented transverse or oblique to the conveying direction are filled with sealing mass exiting from a filling nozzle, the filling nozzle is likewise moved in the conveying direction. When sealing mass is introduced from the filling nozzle into sections of the insulated glass blank that are parallel to the conveying direction, the filling nozzle is not moved in the conveying direction or is moved in the conveying direction at a velocity V2 deviating from the velocity V1 at which the insulated glass blank is moved.

This invention describes a process flow and method to assemble triple IG units without contaminating the center glass lite. A non-contact vacuum pad is used to lift a glass lite off from a horizontal or vertical support that conveys it from a glass washer to an assembly station. Each of multiple pads has a capacity to lift approximately seven to ten pounds. Use of multiple pads per glass sheet or lite allows lites having dimensions up to 70 by 100 inches (assuming glass thickness of one quarter inch) to be assembled.

This invention describes a process flow and method to assemble triple IG units without contaminating the center glass lite. A non-contact vacuum pad is used to lift a glass lite off from a horizontal or vertical support that conveys it from a glass washer to an assembly station. Each of multiple pads has a capacity to lift approximately seven to ten pounds. Use of multiple pads per glass sheet or lite allows lites having dimensions up to 70 by 100 inches (assuming glass thickness of one quarter inch) to be assembled.

Disclosed are a method and device for sealing insulated glass blanks, wherein the insulated glass blank is moved substantially continuously through a sealing station. When sections of the edge joint of the insulated glass blank that are oriented transverse or oblique to the conveying direction are filled with sealing mass exiting from a filling nozzle, the filling nozzle is likewise moved in the conveying direction. When sealing mass is introduced from the filling nozzle into sections of the insulated glass blank that are parallel to the conveying direction, the filling nozzle is not moved in the conveying direction or is moved in the conveying direction at a velocity V2 deviating from the velocity V1 at which the insulated glass blank is moved.

An insulated glass assembly line generally includes a first and second automated lite picker, a washer, a vertical gas filling and wetting station, a robot, and an applicator station.

A gripping device is configured to hold an insulating glazing subassembly including a spacer frame and at least one central glass sheet received in an internal peripheral groove of the spacer frame. The gripping device includes, on the one hand, members for gripping the spacer frame and, on the other hand, members for gripping the central glass sheet so as to ensure an independent gripping of the spacer frame and of the central glass sheet while allowing a relative movement of one with respect to the other.

A process includes the assembling of an insulating glazing subassembly which includes a spacer frame and at least one central glass sheet, the spacer frame being formed of four profiles angularly assembled at their ends, where each profile has a groove for receiving one edge of the central glass sheet. The assembling of the insulating glazing subassembly includes successive steps wherein: the four edges of the central glass sheet are inserted into the grooves of the four profiles; the ends of the profiles are assembled by welding at each corner of the spacer frame without an alignment bracket, using the edges of the central glass sheet inserted in the grooves of the profiles as a frame of reference for guiding the profiles at each corner of the spacer frame into a configuration where their end faces are aligned by superposition in one and the same plane.

A high speed parallel manufacturing line for manufacturing insulated glass units, the manufacturing line including a front conveyor system, a back conveyor system, a shuttle mechanism that distributes glass lites to the front conveyor system and the back conveyor system, an insulated glass unit spacer applicator having a spacer dispensing head configured to apply perimeter spacer material to one of the glass lites, the spacer head being proportionally movable relative to the glass lite as the glass lite is conveyed on the front conveyor mechanism to apply the perimeter spacer material to create a spacer applied lite and a gas press. A secondary edge sealing unit has a first secondary edge sealing head and a second secondary edge sealing head, each of the first secondary edge sealing head and the second secondary edge sealing head applying edge sealant to portion of a perimeter of an insulated glass unit.

A high speed parallel manufacturing line for manufacturing insulated glass units, the manufacturing line including a front conveyor system, a back conveyor system, a shuttle mechanism that distributes glass lites to the front conveyor system and the back conveyor system, an insulated glass unit spacer applicator having a spacer dispensing head configured to apply perimeter spacer material to one of the glass lites, the spacer head being proportionally movable relative to the glass lite as the glass lite is conveyed on the front conveyor mechanism to apply the perimeter spacer material to create a spacer applied lite and a gas press. A secondary edge sealing unit has a first secondary edge sealing head and a second secondary edge sealing head, each of the first secondary edge sealing head and the second secondary edge sealing head applying edge sealant to portion of a perimeter of an insulated glass unit.