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.

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.

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.

The present invention discloses a planar glass sealing structure and a manufacturing method thereof, the planar glass sealing structure comprises, in a top-down order: a first glass substrate, an insulating layer, a metal sealing frame and a second glass substrate. The insulating layer is formed as a frame shape, and disposed on a peripheral margin of the first glass substrate; the metal sealing frame is formed by heating to melt a metal solder layer between the first and second glass substrate, and it can keep a fixed gap between the first and second glass substrate, so that an inner space thereof is kept in an excellent sealed condition. The present invention can ensure the sealing structure of two correspondingly assembled glass substrates, so that the inner space thereof is insulated from moisture and oxygen, so as to increase the performance and quality of the device.

The present invention discloses a planar glass sealing structure and a manufacturing method thereof, the planar glass sealing structure comprises, in a top-down order: a first glass substrate, an insulating layer, a metal sealing frame and a second glass substrate. The insulating layer is formed as a frame shape, and disposed on a peripheral margin of the first glass substrate; the metal sealing frame is formed by heating to melt a metal solder layer between the first and second glass substrate, and it can keep a fixed gap between the first and second glass substrate, so that an inner space thereof is kept in an excellent sealed condition. The present invention can ensure the sealing structure of two correspondingly assembled glass substrates, so that the inner space thereof is insulated from moisture and oxygen, so as to increase the performance and quality of the device.

Methods and apparatus for forming a seal are disclosed. In one arrangement, a first panel and a second panel are provided. A sealer material is present between the first panel and the second panel. The sealer material is in contact with the first panel and the second panel along all of a seal path. A first heating process is performed to heat metal particles derived from the sealer material along the seal path to cause fusing of the metal particles along the seal path. A second heating process is performed, separately from the first heating process, to provide a continuous weld along the seal path between the fused metal particles and the first panel and between the fused metal particles and the second panel, thereby generating a seal along the seal path.

Methods and apparatus for forming a seal are disclosed. In one arrangement, a first panel and a second panel are provided. A sealer material is present between the first panel and the second panel. The sealer material is in contact with the first panel and the second panel along all of a seal path. A first heating process is performed to heat metal particles derived from the sealer material along the seal path to cause fusing of the metal particles along the seal path. A second heating process is performed, separately from the first heating process, to provide a continuous weld along the seal path between the fused metal particles and the first panel and between the fused metal particles and the second panel, thereby generating a seal along the seal path.

A method of manufacturing an optical component for an optical semiconductor includes: providing a joined body including: a first member having light transmissivity and containing at least one element selected from the group consisting of oxygen, fluorine, and nitrogen, and a second member, wherein the first member and the second member are joined together via a metal joining member made by directly bonding a first metal film formed on the first member and a second metal film formed on the second member; and irradiating the joining member with a laser beam or a microwave.

A method of manufacturing an optical component for an optical semiconductor includes: providing a joined body including: a first member having light transmissivity and containing at least one element selected from the group consisting of oxygen, fluorine, and nitrogen, and a second member, wherein the first member and the second member are joined together via a metal joining member made by directly bonding a first metal film formed on the first member and a second metal film formed on the second member; and irradiating the joining member with a laser beam or a microwave.

The present invention relates to a method of producing a vacuum insulated glazing unit, the vacuum insulated glazing unit comprises a first tempered glass pane and a second tempered glass pane arranged in parallel, having a surface of each pane opposing each other with pillars arranged as spacers between the opposed surfaces.

A side frit material is peripherally arranged between the first glass pane and the second glass pane creating an internal void between the glass panes. An evacuation opening is provided in the first glass pane and the evacuation opening comprises an evacuation member, preferably a hollow tube, through which evacuation member the internal void can be evacuated. A top frit material made of lead-free solder frit material comprising a glass content, the top frit material being arranged around the evacuation opening and comprising a surface defining an exterior boundary of the top frit material between the outside of the vacuum insulated glazing unit and the inside of the top frit material, wherein the glass content thereof is substantially in an amorphous state only.