The disclosure describes a tempered vacuum glass, which comprises: at least two glass sheets arranged parallel to each other; surrounding edges of adjacent glass sheets being sealed using an edge sealing structure; and support members placed in an array between the adjacent glass sheets to form a vacuum space. The edge sealing structure is a metallic edge-sealing structure. The structure comprises a first transition layer, a first metallized layer, a first intermetallic compound layer, a solder layer, a second intermetallic compound layer, a second metallized layer, and a second transition layer stacked in that order. The first and second metallized layers are in a spongy skeleton structure formed by sintering a metal paste. The first and second transition layers are formed by sintering the metal paste on the adjacent glass sheets, and contain a glass phase layer including metallic particles and a metal oxide layer with a net structure.

The invention relates to a process for manufacturing a vacuum insulated glazing wherein the glazing is prepared by supplying glass panes, pillars and edge metallic seal elements, said edge metallic seal elements are brazed simultaneously together and with a functional layer previously deposited onto the peripheral zone of the glass panes.

A glass panel unit manufacturing method includes a bonding step, a pressure reducing step, and a sealing step. The bonding step includes bonding together a first substrate and a second substrate with a first sealant to create an inner space. The pressure reducing step includes producing a reduced pressure in the inner space through an exhaust port that the first substrate has. The sealing step includes irradiating a second sealant, inserted into the exhaust port, with an infrared ray through a region, where a low emissivity film is nonexistent, of the second substrate.

An object is to enable sealing of a peripheral portion of a glass panel with less effort and time. A first metal introduction device 5A is moved from one first corner A at which two sides intersect each other of a pair of rectangular glass plates, toward another end of a first side Vab of the two sides, while performing filling with a metal material. Before the metal material filling the first corner A is solidified, a second metal introduction device 5B is moved from the first corner A toward another end of another second side Vad, while performing filling with a metal material. After the first side Vab and the second side Vad are filled with the metal material, both glass plates are rotated by 180 degrees, and the first metal introduction device 5A is moved toward another end of a fourth side Vcd of two sides intersecting each other at a second corner C diagonal to the first corner A, while performing filling with a metal material. Before the metal material filling the second corner C is solidified, the second metal introduction device 5B is moved from the second corner C toward another end of another third side Vbc, while performing filling with a metal material.

An object is to enable suppression of thermal leakage at a peripheral portion of a pair of glass plates disposed so as to be opposed to each other with a gap interposed therebetween. A pair of glass plates 1A, 1B are disposed so as to be opposed to each other with a gap V interposed therebetween, and a periphery sealing metal material 3 is provided which joins the pair of glass plates 1A, 1B at a peripheral portion V1 thereof so as to seal the gap V in an airtight state. The periphery sealing metal material 3 interposed between opposed inner surfaces of the pair of glass plates 1A, 1B contains, in a mixed manner, a thermal insulation material 30 having lower thermal conductivity than that of the periphery sealing metal material 3.

This glass bonding material (21) is made of a cladding material (1) in which at least a first layer (11) made of an Al-based alloy and configured to be bonded to glass and a second layer (12) made of an FeNi based alloy having a thermal expansion coefficient from 30 C. to 400 C. of 11.510.sup.6 (K.sup.1) or less are bonded.

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).

Certain example embodiments relate to vacuum insulating glass units having edge seals formed in connection with solder alloys that, when reactively reflowed, wet metallic coatings pre-coated on the glass substrates' perimeters, and/or associated methods. The alloys may be based on materials that form seals at temperatures that will not de-temper glass and/or decompose a laminate, and/or remain hermetic and lack porous structures in their bulks. Example alloys may be based on inter-metallics of Sn and one or more materials selected from post-transition metals or metalloids; Zintl anions (e.g., In, Bi, etc.) from Group 13, 14, 15, or 16; and transition metals (e.g., Cu, Ag, Ni, etc.); and excludes Pb. Thin film coatings in certain example embodiments work with the solder material to form robust and durable hermetic interfaces. Because low temperatures are used, certain example embodiments can use compliant and visco-elastic spacer technology based on lamellar structures and/or the like.

A vacuum glass panel includes a first glass plate, a second glass plate facing the first glass plate, a frame member having a frame shape and bonding the first glass plate to the second glass plate, and a heat reflective film disposed on an inner surface of the first glass plate. A vacuum space is provided between the first glass plate and the second glass plate. The heat reflective film separates the first glass plate from the vacuum space without a gap. The frame member is in contact with the first glass plate.

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.