An object of the invention is to provide a multilayer glass which can be manufactured by a simple process. To solve the above problem, the multilayer glass according to the invention includes a first glass substrate, a second glass substrate that faces the first glass substrate at an interval of a predetermined space, and a sealing part that seals a periphery of an internal space defined by the first glass substrate and the second glass substrate. The sealing part is formed with a sealing material containing low melting point glass. The internal space is in a vacuum state. The first glass substrate includes an exhaust port that is provided to be included in a projection part of the sealing part when being projected in a lamination direction of the first glass substrate and the second glass substrate. The exhaust port is blocked by the sealing material (see FIG. 3).

An insulating glass unit (IGU) assembly line comprising a registration station capable of interleaving double and triple pane IGUs in accordance with an IOU production schedule. Visual indicators or prompts instruct operators at the assembly line in configuring a sequence of IGUs. Triple pane IGUs are assembled with minimal contamination of a center glass lite. A non-contact Bernoulli pad is used to lift a glass lite off from a horizontal or vertical support that conveys it from a glass washer to the registration 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.

A method for manufacturing a plurality of vacuum insulating glass (VIG) units, wherein the method comprises providing a plurality of first glass panes, applying a soldering material arranged for subsequent connection with a second glass pane to provide a seal between an outside of the VIG unit and an inside void of the VIG unit, moving the first glass panes comprising the soldering material into a treatment compartment, wherein the treatment compartment is pre-heated, drying the soldering material in a heating step by evaporating solvent, wherein the heating is forced convection heating, moving the first glass panes to a cooling compartment, cooling first glass panes and the soldering material thereon in a cooling step, wherein the cooling is by forced convection cooling, moving the first glass panes from the cooling compartment, and subsequently connecting the first glass panes to second glass panes using the dried soldering material.

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.

A six-part conveyor system sharing a common line of dependency for the streamlined manufacturing of windows allowing both sides of the window to be easily worked on without the need for users to lift and move the window from one segment of a conveyor system to another. The window manufacturing conveyor line is designed to streamline the manufacture of windows. This system and method allows a user to easily move glass panels, speeding up productivity and provide efficiency by putting holding clips on glass in a first station, applying fast drying sealant to a tipped piece of glass in a second station, and moving to a final station where the glass window is prepared for shipping wherein the shipping cart is moved into position around the final station and window is lowered onto the cart.

A panel support and panel processing system that provides a single frame assembly for use on a panel processing line in transporting and installing panels, such as glass panels, the frame assembly having a frame with at least one hook that engages a carrier on a processing line to move the frame from one station to the next, and that enables lifting and stacking of multiple frames for transport to and installation at a building site without having to remove the panel, such as a glass panel, from the frame, at which point the frame and panel assembly are secured in situ.

The present invention relates to a double-pane window insulating system. The double-pane window insulating system according to the present invention comprises: a double-pane window having a chamber formed between a pair of windowpanes, a bead inlet via which a plurality of beads and air flow into the chamber, a bead outlet via which the plurality of beads and the air accommodated in the chamber are discharged, and an air entrance/exit opening via which air enters and exits the chamber; and a bead discharge means for discharging the plurality of beads, accommodated in the chamber, to the bead outlet.

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.

A panel support and panel processing system that provides a single frame assembly for use on a panel processing line in transporting and installing panels, such as glass panels, the frame assembly having a frame with at least one hook that engages a carrier on a processing line to move the frame from one station to the next, and that enables lifting and stacking of multiple frames for transport to and installation at a building site without having to remove the panel, such as a glass panel, from the frame, at which point the frame and panel assembly are secured in situ.

A multiple pane insulated glazing unit for a fenestration unit includes a first outer pane including a first thickness defined between a first outer surface and a first inner surface. A first spacer is coupled to the first inner surface. A second outer pane has a second thickness defined between a second outer surface and a second inner surface. A spacer is coupled to the second inner surface, and an intermediate pane is coupled to at least one of the first spacer and the spacer. The intermediate pane has a third thickness defined between a third inner surface and a fourth inner surface that is less than the first thickness and the second thickness. The third thickness is between about 0.2 millimeters (mm) to about 1.2 millimeters (mm), and the first outer pane, the second outer pane and the intermediate pane are composed of boron-free soda lime silicate glass.