Provided is a laser machining method that causes no degradation in magnetic properties for thin electrical steel sheets. An electrical steel sheet machining method comprises machining an electrical steel sheet to a predetermined shape by melt-cutting the electrical steel sheet using a laser, wherein a scanning rate of the laser in the melt-cutting is 10000 mm/min or more.

The present disclosure relates to a brazing structure. The brazing structure may comprise a first portion and a second portion. At least one of the first portion or the second portion may include a connection-reinforcing surface. The connection-reinforcing surface may include a groove region and a filler placement region. The filler placement region may be configured to hold a filler material in solid state before brazing. The groove region may include a plurality of grooves where the filler material flows into after being melted. The first portion and the second portion may be connected by a braze joint formed by the filler material.

An apparatus for manufacturing a display device and a method for manufacturing a display device are provided. An embodiment of an apparatus for manufacturing a display device includes a laser module configured to emit a laser beam and a first optical system disposed on one side of the laser module such that the laser beam is provided to the first optical system, wherein the first optical system controls an energy profile of the laser beam, wherein, on a first irradiation surface positioned at one side in a traveling direction of the laser beam from a focal point of the laser beam, the energy profile of the laser beam includes a first increase and then a first decrease in energy along a line parallel to the first irradiation surface from an outer perimeter of the laser beam toward a center of the laser beam, and wherein the energy profile of the laser beam includes a first peak corresponding to where the energy begins to decrease.

The invention relates to a method for controlling stress in a substrate during laser deposition. The method includes the steps of: providing a laser deposition device including a chamber with a target holder with a target, a substrate holder with a substrate facing the target and a window, the laser deposition device further including a laser beam directed through the window of the chamber onto a spot at the target for generating a plasma plume of target material and depositing the target material onto a surface portion of the substrate in order to form a thin film of target material, wherein the target spot is movable relative to the substrate in order to deposit target material onto a plurality of surface portions of the substrate; defining a plurality of discrete surface portions on the substrate; aligning the target spot one after the other with each of the plurality of discrete surface portions and generating a plasma plume to deposit target material on each of the plurality of discrete surface portions; and adjusting at least one of the parameters of the deposition process depending on the discrete surface portion with which the target spot is aligned, which parameters include temperature, pressure, laser beam pulse duration, laser beam power, distance of target to substrate.

An amorphous metal ribbon includes a plurality of laser irradiation mark rows each including a plurality of laser irradiation marks arranged in a row, in which when a distance between the laser irradiation mark rows that are adjacent to each other is set as d1, a distance between the laser irradiation marks in the laser irradiation mark row is set as d2, a diameter of the laser irradiation mark is set as d3, a depth of the laser irradiation mark is set as d4, and a volume occupancy rate V of the laser irradiation marks is set as (1/d1d3d4)(1/d2)100, the volume occupancy rate V of the laser irradiation marks is 0.00057% or more and 0.010% or less.

A method for trimming a micro electronic element includes: providing a substrate, wherein at least one micro electronic element is disposed on the substrate, heating an interface of the substrate and the micro electronic element by a first pulse laser beam to reduce a bonding force between the micro electronic element and the substrate, and irradiating a surface layer of the micro electronic element by a second pulse laser beam to generate a shock wave due to plasma on the surface layer of the micro electronic element. The shock wave removes the micro electronic element away from the substrate. An apparatus for trimming a micro electronic element is also provided.

A method for analyzing a weld seam formed by a laser welding process includes thermally exciting the weld seam by radiating at least one laser pulse onto the weld seam, acquiring a decay characteristic of a thermal radiation emitted by the weld seam, and determining whether a welding defect is present based on an evaluation of the acquired decay characteristic.

Disclosed herein is a device for magnetic welding of battery boils comprising a coil holder; where the coil holder comprises one or more electrical coils that are operative to be activated by an electrical current; a foil holding fixture; wherein the foil holding fixture comprises a plurality of arms; wherein each pair of adjacent arms is operative to move towards one another to crimp a plurality of battery foils; and an anvil; wherein the anvil is operative to support a battery tab and the battery foils.

A method for manufacturing an antenna device comprises melting a brazing material and a removing a part of an insulating film. The antenna device includes an antenna portion formed by winding a coil wire having a coil core covered with the insulating film, and a base having a pad portion to which a part of the coil wire is brazed with the brazing material. In melting the brazing material, the brazing material supplied onto the pad portion is irradiated with a laser beam so that the brazing material melts. In removing a part of the insulating film, the coil wire is immersed in the molten brazing material so that a part of the insulating film is removed from the coil wire, and the coil wire and the pad portion are joined with the brazing material.

A temperature control plate for battery cooling and a method for producing a temperature control plate. The temperature control plate has a plate body having first and second plate elements, and a connecting piece for a temperature control fluid. The connecting piece has an outer flange and a plug-in section, wherein the outer flange abuts an outside of the first plate element and the plug-in section is positioned in a mounting opening of the first plateelement. The mounting opening is in a formation in the first plateelement, wherein a circumferential edge of the mounting opening is displaced relative to a plate plane of the first plateelement. An end section of the plug-in section is formed into an inner flange, wherein an annular groove is formed between the outer and inner flanges, and the circumferential edge of the mounting opening lies in the annular groove.