A method for laser welding a pair of metal pins delivers a laser beam to a work-side of the pair of metal pins where a respective pair of surfaces of the metal pins are adjacent to each other and face in the same direction. The laser beam first traces a first path on the work-side to form a melt pool by keyhole welding. The first path crosses an interface between the metal pins. After tracing the first path, the laser beam is switched to trace a second path on the work-side with the laser beam at a delivered rate of energy per unit path length that is less than the one used for the first path. The second path crosses the interface and is within the first path. The method is well-suited for welding of hairpin and I-pin stators.

According to one embodiment, a disk device includes a disk-shaped recording medium, a head which processes data on the recording medium, and a housing accommodating the recording medium and the head. The housing includes a base with a side wall, and a cover having a welded portion welded to the side wall by laser welding. The welded portion includes a first welded portion welded to a first region of the side wall and having weld beads with a first shape, and a second welded portion welded to a second region of the side wall and having welded beads with a second shape different from the first shape.

According to one embodiment, a disk device includes a disk-shaped recording medium, a head which processes data on the recording medium, and a housing accommodating the recording medium and the head. The housing includes a base with a side wall, and a cover having a welded portion welded to the side wall by laser welding. The welded portion includes a first welded portion welded to a first region of the side wall and having weld beads with a first shape, and a second welded portion welded to a second region of the side wall and having welded beads with a second shape different from the first shape.

Method for joining a first and a second steel blanks, at least one of the blanks comprising aluminium. The method comprises providing a support being made of a magnetic material for each blank, the supports being arranged distanced apart by a central space; providing a coil winding around one support, arranging the first blank on one support and the second blank on the other support, such that a butt end of the first blank that is facing the second blank is brought into contact with a butt end of the second blank that is facing the first blank defining a contacting area that closes a path for magnetic flux. The method further comprises applying a laser beam onto the contacting area, while applying an alternating current to the coil winding, wherein an alternating magnetic field is created across the contacting area in a direction substantially in-line with the blanks.

Method for joining a first and a second steel blanks, at least one of the blanks comprising aluminium. The method comprises providing a support being made of a magnetic material for each blank, the supports being arranged distanced apart by a central space; providing a coil winding around one support, arranging the first blank on one support and the second blank on the other support, such that a butt end of the first blank that is facing the second blank is brought into contact with a butt end of the second blank that is facing the first blank defining a contacting area that closes a path for magnetic flux. The method further comprises applying a laser beam onto the contacting area, while applying an alternating current to the coil winding, wherein an alternating magnetic field is created across the contacting area in a direction substantially in-line with the blanks.

A device and a method for beam shaping and beam movement during laser material processing with a laser beam source (1) for continuously emitting a laser beam (2), a first optical deflection element (3), a second optical deflection element (4), and an optical focusing element (5) arranged between the second optical deflection element (4) and a workpiece surface (7) to be processed. The second optical deflection element (4) is configured to displace a point of incidence of the laser beam (2) on the workpiece surface (7), and the first optical deflection element (3) is configured to alter a position of a focal plane of the laser beam (2) relative to the workpiece surface (7) by means of a translational movement and/or to change an intensity distribution within a beam cross section of the laser beam.

A method is provided for producing a body part of a vehicle. The method includes, but is not limited to providing a first profile part with at least one first welding flange and with a first opening as well as a second profile part with at least one third welding flange. The welding flange is at least partially arranged on the third welding flange subject to the formation of an at least partially closed form of the body part. The first welding flange and the third welding flange are arranged within the at least partially closed form. A first laser beam is guided through the first opening onto the first welding flange subject to the formation of at least one first laser weld seam between the first welding flange and the third welding flange.

A method is provided for producing a body part of a vehicle. The method includes, but is not limited to providing a first profile part with at least one first welding flange and with a first opening as well as a second profile part with at least one third welding flange. The welding flange is at least partially arranged on the third welding flange subject to the formation of an at least partially closed form of the body part. The first welding flange and the third welding flange are arranged within the at least partially closed form. A first laser beam is guided through the first opening onto the first welding flange subject to the formation of at least one first laser weld seam between the first welding flange and the third welding flange.

Methods and systems for welding are disclosed, including generating electromagnetic radiation from an ultrashort pulse laser; coupling the electromagnetic radiation from the ultrashort pulse laser to a scanner comprising a scanning and focus range, wherein the scanner is configured to receive the electromagnetic radiation from the ultrashort laser and to scan and focus the electromagnetic radiation onto a joining interface of one or more materials; using a computer to adjust the pulse repetition rate and the average power of the ultrashort pulse laser; using one or more stages to position the joining interface; using a dichroic filter positioned between the scanner and the one or more materials; and focusing an imager and processor through the dichroic filter and onto the joining interface to monitor the joining interface of the one or more materials within the scanning and focus range of the electromagnetic radiation. Other embodiments are described and claimed.

According to one embodiment, a welding method includes preparing a welding member that includes aluminum. The welding method includes welding a weld area of a surface of the welding member by irradiating a laser on the weld area in a state in which a gas including oxygen is supplied to the weld area. A concentration of the oxygen in the gas is not less than 1.5 vol % and not more than 10 vol %. The weld area includes aluminum oxide after the irradiating of the laser.