A pillar mounting method includes an accommodation step, a mounting step, and a displacement step. The accommodation step is a step of accommodating a plurality of pillars in storage with the plurality of pillars being stacked on each other. The mounting step is a step of pushing one pillar of the plurality of pillars accommodated in the storage out of the storage and mounting the one pillar on a substrate including a glass pane. The displacement step is a step of changing a relative location between the substrate and the storage. The mounting step and the displacement step are alternately repeated to mount the plurality of pillars in a predetermined arrangement on the substrate such that the plurality of pillars are apart from each other.

A vacuum insulated glazing includes first and second spaced apart glass panes having perimeter portions defining a vacuum space between the glass panes. A vacuum valve is positioned at the perimeter portions of the glass panes and includes a valve body extending between the perimeter portions of the glass panes, and having first and second ends and a fluid conduit extending from the first end to the second end of the valve body and in fluid communication with the vacuum space. A one-way valve in the fluid conduit permits fluid flow from the vacuum space, and prevents fluid flow into the vacuum space. A suction fitting is provided for connecting the valve body to a suction device. An end seal between the perimeter portions of the glass panes is provided for hermetically sealing the vacuum space. A valve for a VIG and a method of making a VIG are also disclosed.

Methods and materials to fabricate electrochromic including electrochemical devices are disclosed. In particular, emphasis is placed on the composition, fabrication and incorporation of electrolytic sheets in these devices. Composition, fabrication and incorporation of redox materials and sealants suitable for these devices are also disclosed. Incorporation of EC devices in insulated glass system (IGU) windows is also disclosed.

The present invention relates to an apparatus for manufacturing vacuum glass. An apparatus for manufacturing vacuum glass, according to an embodiment of the present invention, includes an exhaust finishing frit inserted into an exhaust hole of a plate glass assembly so as to seal the exhaust hole in an exhaust process. In addition, the exhaust finishing frit comprises: a frit body having a body top part on which a cap frit is placed; a depressed portion which is upwardly depressed from the bottom of the frit body; and an exhaust guide part which is formed to penetrate the outer circumferential surface of the frit body. Thus, it is possible to prevent bubbles from being generated in the exhaust finishing frit during a finishing process.

A glass panel unit includes: a first substrate including a first glass panel; a second substrate including a second glass panel; and a frame-shaped sealing portion that is hermetically bonded to the first substrate and the second substrate. The sealing portion creates an evacuated space between the first substrate and the second substrate. When viewed from a region where the second substrate is positioned with respect to the first substrate, the first substrate includes a part arranged to stick out of an edge of the second substrate. The part includes a mounting portion used to mount the glass panel unit onto a vehicle.

A glass unit according to the present invention includes a first glass plate having a through hole formed therein, a second glass plate that is arranged facing the first glass plate at a predetermined interval therefrom and forms an internal space with the first glass plate, a sealing member that seals a gap at peripheral edges of the first glass plate and the second glass plate, a cover that closes the through hole, and an adhesive that fixes the cover to the first glass plate. The internal space has been depressurized to a vacuum state, or a predetermined gas has been injected into the internal space, and the first glass plate and the cover are fixed by the adhesive.

The present disclosure relates to a method of applying a seal material in manufacturing a vacuum insulated glazing (VIG) unit, wherein the VIG unit comprises a first glass sheet, having a first interior major surface and a first exterior major surface, a second glass sheet having a second interior major surface and second exterior major surface, the glass sheets are placed in parallel with said interior major surfaces facing each other and providing a gap therein between, and a seal material for providing a seal of said gap, wherein the method comprises the steps of providing a glass sheet, and arranging said seal material on a major surface of at least one of said glass sheets by means of a nozzle having a nozzle opening of elongated shape, such as a rectangular or oval shape, providing a plurality of support structures on the major surface of at least one of the glass sheets, pairing said first glass sheet and said second glass sheet so that the surface of the at least one of said glass sheets comprising the seal material is the interior surface, and evacuating said gap so as to provide said VIG unit. The present disclosure further relates to a method of manufacturing a VIG unit, an application system and a VIG unit.

A glass panel unit includes: a first panel including a glass pane; a second panel including another glass pane; a sealing portion; an exhaust port; and a printed portion. The second panel is arranged to face the first panel. The sealing portion is formed in a frame shape and hermetically bonds respective peripheral edge portions of the first and second panels to create an evacuated, hermetically sealed space between the first panel and the second panel. The exhaust port is provided for one panel selected from the first and second panels. A port sealing member hermetically seals the exhaust port. The printed portion is provided for the other panel selected from the first and second panels. The printed portion is located in an area, facing the exhaust port, of one surface of the other panel. The one surface either faces toward, or faces away from, the hermetically sealed space.

A manufacturing method of a glass panel unit of the present invention includes a bonding step, a pressure reduction step, and a sealing step. In the bonding step, a first substrate and a second substrate are hermetically bonded together with a seal having a frame shape. In the pressure reduction step, a pressure in an inside space formed between the first substrate and the second substrate is reduced through an exhaust port. In the sealing step, sealant melted is dropped toward the exhaust port, thereby sealing the exhaust port with the sealant.

Disclosed are a method of manufacturing double vacuum glass and double vacuum glass manufactured by the method. The double vacuum glass includes: a plate-shaped base panel configured to form one side surface of the double vacuum glass; a plate-shaped cover panel configured to form the other side surface of the double vacuum glass; spacers configured to space the base panel and the cover panel apart from each other so that a space is formed between the base panel and the cover panel; strip members configured to couple the base panel and the cover panel that are spaced apart from each other by the spacers; and a sealer configured to seal a space between the edges of the base panel and the edges of the cover panel by filling the space between the edges of the base panel and the edges of the cover panel outside the strip members.