A vacuum insulation panel manufacturing method that makes it possible to manufacture low-cost, high-performance vacuum insulation panels, and a vacuum insulation panel are provided. This method of manufacturing a vacuum insulation panel involves: a stacking step in which a first metal plate is stacked on one side of an insulating core material, and in which a backing member having an opening and a second metal plate having an evacuation port are stacked, with the opening and the evacuation port stacking, on the other surface of the core member in the order of backing member and second metal plate from the core member side; a first welding step for welding outwards of where the core member is arranged in the first metal plate and the second metal plate; an evacuating step from the evacuation port to create a vacuum in an inner area which is held between the first metal plate and the second metal plate and in which the core member is arranged; and a laser welding step in which, in a state in which the inner area is made into a vacuum by the evacuating step, the evacuation port is sealed by means of a sealing material and the sealing material, the second metal plate and the backing member are laser welded.

A vacuum insulation panel manufacturing method that makes it possible to manufacture low-cost, high-performance vacuum insulation panels, and a vacuum insulation panel are provided. This method of manufacturing a vacuum insulation panel (1) involves: a stacking step in which a first metal plate (20) is stacked on one side of an insulating core material (10), and in which a backing member (50) having an opening (51) and a second metal plate (30) having an evacuation port (32) are stacked, with the opening (51) and the evacuation port (32) stacking, on the other surface of the core member (10) in the order of backing member (50) and second metal plate (30) from the core member (10) side; a first welding step for welding outwards of where the core member (10) is arranged in the first metal plate (20) and the second metal plate (30); an evacuating step from the evacuation port (32) to create a vacuum in an inner area which is held between the first metal plate (20) and the second metal plate (30) and in which the core member (10) is arranged; and a laser welding step in which, in a state in which the inner area is made into a vacuum by the evacuating step, the evacuation port (32) is sealed by means of a sealing material (60) and the sealing material (60), the second metal plate (30) and the backing member (50) are laser welded.

An optical module includes an optical semiconductor chip having a first surface that includes a laser beam irradiation region and a cleavage region, an optical fiber optically coupled to the first surface, and a support member having a second surface bonded to the first surface, and configured to support the optical fiber. The optical semiconductor chip has an optical signal input and output part located in the cleavage region, and the second surface is bonded to the first surface within the cleavage region.

The present invention relates to an implantable lead comprising at least one conductive wire and one electrical connector, the electrical connector configured to be connected to an implantable medical device such as a cardiac stimulation, defibrillation and/or neuromodulation device, wherein the electrical connection between the conductive wire and the connector is effected by a first hypotube welded to the conductive wire and welded to a second hypotube of the electrical connector. The present invention also relates to a method for electrically connecting the at least one conductive wire of the implantable lead to the electrical connector.

A method for controlling surface asperity during laser sealing of a membrane vent hole. The method includes applying a laser having a laser intensity spatial distribution to the membrane vent hole to form a seal over the membrane vent hole. The seal has a seal surface. The laser pulse includes a primary laser pulse region and a secondary pulse region later in time than the primary laser pulse region, and a time gap between the primary laser pulse region and the secondary laser pulse region. The primary laser pulse region and/or the secondary pulse region include first and second discontinuous laser pulses having a first time gap therebetween and/or third and fourth discontinuous laser pulses having a second time gap therebetween. The seal surface has a controlled surface asperity characteristic.

A method for controlling surface asperity during laser sealing of a membrane vent hole. The method includes applying a laser pulse having a laser intensity spatial distribution to the membrane vent hole to form a seal over the membrane vent hole. The seal has a seal surface. The laser pulse includes a primary laser pulse region and a secondary laser pulse region beginning once the primary laser pulse region ends. The primary laser pulse region has a primary laser power, and the secondary laser pulse region has a secondary laser power. The secondary laser power is less than the primary laser power. The seal surface has a controlled surface asperity characteristic.

A vacuum insulation panel manufacturing method that makes it possible to manufacture low-cost, high-performance vacuum insulation panels, and a vacuum insulation panel are provided. This method of manufacturing a vacuum insulation panel involves: a stacking step in which a first metal plate is stacked on one side of an insulating core material, and in which a backing member having an opening and a second metal plate having an evacuation port are stacked, with the opening and the evacuation port stacking, on the other surface of the core member in the order of backing member and second metal plate from the core member side; a first welding step for welding outwards of where the core member is arranged in the first metal plate and the second metal plate; an evacuating step from the evacuation port to create a vacuum in an inner area which is held between the first metal plate and the second metal plate and in which the core member is arranged; and a laser welding step in which, in a state in which the inner area is made into a vacuum by the evacuating step, the evacuation port is sealed by means of a sealing material and the sealing material, the second metal plate and the backing member are laser welded.

A vacuum insulation panel manufacturing method that makes it possible to manufacture low-cost, high-performance vacuum insulation panels, and a vacuum insulation panel are provided. This method of manufacturing a vacuum insulation panel (1) involves: a stacking step in which a first metal plate (20) is overlaid on one side of a thermally insulating core material (10), and in which a backing member (50) having an opening (51) and a second metal plate (30) having an exhaust port (32) are placed, with the opening (51) and the exhaust port (32) overlapping, overlaid on each other on the other surface of the core member (10) in the order of backing member (50) and second metal plate (30) from the core member (10) side; a first welding step for welding outwards of where the core member (10) is disposed in the first metal plate (20) and the second metal plate (30); a vacuum creating step for evacuating air from the exhaust pert (32) to create a vacuum in an inner area which is held between the first metal plate (20) and the second metal plate (30) and in which the core member (10) is arranged; and a laser welding step in which, in a state in which the inner area is made into a vacuum by the vacuum creating step, the exhaust port (32) is sealed by means of a sealing material (60) and the sealing material (60), the second metal plate (30) and the backing member (50) are laser welded.

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 grain-oriented electrical steel sheet includes: a base steel sheet; a primary film formed on a surface of the base steel sheet; and a tension insulation coating formed on a surface of the primary film, in which a magnetic domain control is performed by irradiating the tension insulation coating with a laser from above. When a strip-like sample having a length of 300 mm in a direction parallel to a rolling direction of the grain-oriented electrical steel sheet and a length of 60 mm in a direction parallel to a transverse direction is extracted from the grain-oriented electrical steel sheet, a range from a surface of the tension insulation coating to a depth position of 5 m toward the base steel sheet side from an interface between the base steel sheet and the primary film is removed by pickling at least one surface of the sample, and a warpage amount of the sample is thereafter measured, the warpage amount satisfies predetermined conditions.