A method of forming a build in a powder bed includes providing a first diode laser fiber array and a second diode laser fiber array, emitting a plurality of laser beams from selected fibers of the second diode laser fiber array onto the powder bed, corresponding to a pattern of a layer of the build, simultaneously melting powder in the powder bed corresponding to the pattern of the layer of the build, scanning a first diode laser fiber array along an outer boundary of the powder bed and emitting a plurality of laser beams from selected fibers of the first diode laser fiber array and simultaneously melting powder in the powder bed corresponding to the outer boundary of the layer of the build to contour the layer of the build. An apparatus for forming a build in a powder bed including a first diode laser fiber array and a second diode laser fiber array is also disclosed. The first diode laser fiber array configured to contour the layer of the build.

A laser cutting method includes a step of determining a material to be removed and dividing the material to be removed into a plurality of material chips so as thereby to organize a machining plan for laser cutting; and, a step of, according to the machining plan for laser cutting, moving a laser along a boundary defining the material to be removed on the workpiece to perform cutting in a first direction and a second direction, such that the material chips can be separated from the workpiece orderly piece by piece so as to form a specific pattern. While in laser cutting, the method removes the material piece by piece. With the laser to remove the material chips through cutting along the boundary, the pattern on the workpiece is thus finished equivalently by the laser. Thereupon, the machining time can be significantly reduced.

A method of preparing an elongate web of sheet material for dividing into discrete stacks of web portions after reeling the web onto a drum is provided. The method includes forming transverse discontinuities in the web at spaced intervals corresponding to edges of the discrete stacks to be formed, the intervals progressively increasing along the web so that the discontinuities form angularly-aligned groups when reeled onto the drum.

A device configured for a laser treatment, including a support and objects, each attached to the support via a region absorbing for the laser, the support comprising a system for optically guiding (42, 44, 50, 52) the laser towards at least a plurality of said absorbing regions.

A foreign substance capturing apparatus according to an embodiment of the present invention may comprise: a capturing body unit having an inlet port for introducing the air including magnetic foreign substances and an outlet port for discharging the air from which the magnetic foreign substances have been removed; and a magnetic isolation unit connected to the capturing body unit, including a magnetic member for isolating, by an attractive force, the magnetic foreign substances from the air flowing in the capturing body unit, and provided with a non-magnetic member surrounding the magnetic member.

A beam processing apparatus is a beam processing apparatus that irradiates a workpiece with a processing beam, and performs a removal processing of a first part of the workpiece by irradiating a first surface of the workpiece with the processing beam while moving an irradiation position of the processing beam along a first direction, and performs a removal processing of a second part of the workpiece by irradiating a second surface, which is formed at the workpiece by the removal processing of the first part, with the processing beam while moving the irradiation position of the processing beam along the first direction. A moving range of the processing beam for the removal processing of the second part is smaller than a moving range of the processing beam for the removal processing of the first part.

A beam processing apparatus is a beam processing apparatus that irradiates a workpiece with a processing beam, and performs a removal processing of a first part of the workpiece by irradiating a first surface of the workpiece with the processing beam while moving an irradiation position of the processing beam along a first direction, and performs a removal processing of a second part of the workpiece by irradiating a second surface, which is formed at the workpiece by the removal processing of the first part, with the processing beam while moving the irradiation position of the processing beam along the first direction. A moving range of the processing beam for the removal processing of the second part is smaller than a moving range of the processing beam for the removal processing of the first part.

A system for welding a first component to a second component. The system includes a first laser head configured to emit a first laser beam and be movably disposable on a first side of the first component. The system further includes a second laser head configured to emit a second laser beam and be movably disposable on an opposing second side of the first component. The system further includes a controller configured to independently control a first power of the first laser beam and a second power of the second laser beam. The controller is also configured to independently and simultaneously control movement of the first laser head and movement of the second laser head relative to the first component.

A welding method includes: emitting a laser beam to a workpiece including a metal; and welding a portion of the workpiece to which the laser beam is emitted by melting. The laser beam includes a main power region and at least one auxiliary power region, power in the main power region is equal to or higher than power in each of the at least one auxiliary power region, and a power ratio of the power in the main power region and a total of the power in the at least one auxiliary power region is within a range of 144:1 to 1:1.

A welding method includes: emitting a laser beam to a workpiece including a metal; and welding a portion of the workpiece to which the laser beam is emitted by melting. The laser beam includes a main power region and at least one auxiliary power region, power in the main power region is equal to or higher than power in each of the at least one auxiliary power region, and a power ratio of the power in the main power region and a total of the power in the at least one auxiliary power region is within a range of 144:1 to 1:1.