A liquid supply mechanism is disposed on an upper portion of a holding unit of a laser processing apparatus. The liquid supply mechanism includes: a liquid chamber having a transparent plate positioned such that a gap is formed between the transparent plate and the top surface of a workpiece held on a holding table; a linear-motion mechanism configured to linearly move the transparent plate over the liquid chamber; a liquid supply nozzle configured to supply a liquid from one side of the liquid chamber to the gap; and a liquid discharge nozzle configured to discharge the liquid from another side of the liquid chamber. A laser beam irradiating unit includes a laser oscillator configured to irradiate the workpiece through the transparent plate and the liquid supplied to the gap.

A laser machining apparatus includes a machining correlation data management unit configured to manage machining correlation data which associates a position in an optical axis direction of a focus lens with a focus position for machining when machining light is condensed by the focus lens, a focus confirmation correlation data management unit configured to manage or create focus confirmation correlation data which associates the position in the optical axis direction of the focus lens with a focus position for focus confirmation when the guide light is condensed by the focus lens, and a lens driving mechanism control unit configured to move, in a first mode, the focus lens in the optical axis direction based on the machining correlation data, and to move, in a second mode, the focus lens in the optical axis direction based on the focus confirmation correlation data.

A method of confirming an optical axis of a laser processing apparatus includes placing an image capturing unit so as to be movable in X-axis directions, removing a second mirror and capturing an image of a laser beam with the image capturing unit for receiving the laser beam reflected by a first mirror, installing the second mirror and capturing an image of the laser beam with the image capturing unit for receiving the laser beam reflected by a third mirror, and determining whether an optical axis of the laser beam reflected by the first mirror and an optical axis of the laser beam reflected by the third mirror exist in one XZ plane or not on the basis of the captured images and a reference line in the captured images.

Provided are a laser annealing apparatus and a method of manufacturing a substrate having a poly-Si layer using the laser annealing apparatus. The laser annealing apparatus includes a laser beam source that emits a linearly polarized laser beam, a polygon mirror that rotates around a rotation axis and reflects the laser beam emitted from the laser beam source, a first Kerr cell disposed on a laser beam path between the laser beam source and the polygon mirror, and a first optical element that directs the laser beam reflected by the polygon mirror toward an amorphous Si layer where the laser beam is irradiated upon the amorphous Si layer.

Device and method for laser welding around a circumference of a workpiece. A fixed, non-movable unitary optical reflector has a pair of optical reflecting surface portions on a first side surface and a second side surface, respectively, arranged at an obtuse angle relative to each other. A workpiece is fixed in an assembly having the reflector. During setup, the vertical distance is adjusted between the reflector and workpiece along an axis that is transverse to a longitudinal axis thereof without any adjustment of the reflecting surfaces. The first and second side surfaces define a curve that is transverse to the longitudinal axis. Once setup has been completed, a laser beam is directed so that it moves along the optical reflector to thereby produce a 360 degree circumferential weld around the workpiece. Another assembly is provided to change the laser beam direction multiple times to irradiate a circumference of a fixed workpiece from a fixed laser source.

Provided is a method for refining magnetic domains of grain-oriented electrical steel plates including: a steel plate supporting roll position adjusting step of controlling a vertical direction position of the steel plate while supporting the steel plate; a laser radiating step of melting the steel plate by radiating a laser beam to form grooves on the surface of the steel plate; and a setting and maintaining step of setting and maintaining an internal operation environment of a laser room in which the laser radiation is performed, so as to increase magnetic domain refinement efficiency and improve workability by optimizing equipment and processes, thereby increasing the processing capacity.

A galvano scanner that irradiates an object with a laser beam to perform machining, the galvano scanner comprising: an emission unit that emits the laser beam; a protective glass that protects the emission unit from a scattered matter generated in machining; and a glass holding mechanism that holds the protective glass, the protective glass at least including a triple structure in a vertical direction, the glass holding mechanism holding the protective glass that is the lowermost layer in the protective glass having the triple structure so that the protective glass that is the lowermost layer can be fallen off downward.

An additive manufacturing apparatus includes a platform, a dispenser to dispense a plurality of layers of feed material on a top surface of the platform, and an energy delivery assembly. The energy delivery assembly includes a light source to emit one or more light beams, a first reflective member having a plurality of reflective facets, and at least one second reflective member. The first reflective member is rotatable such that sequential facets sweep the light beam sequentially along a path on the uppermost layer. The at least one second reflective member is movable such that the at least one second reflective surface is repositionable to receive at least one of the at least one light beam and redirect the at least one of at least one light beam along a two-dimensional path on the uppermost layer.

A surface treating method and apparatus include operating a quasi-continuous wave fiber laser and pre-scan shaping the laser beam such that an instantaneous spot beam has predetermined geometrical dimensions, intensity profile, and power; operating a scanner at an optimal angular velocity and angular range to divide the pre-scan beam into a plurality of sub-beams deflected towards the surface being processed; guiding the sub-beams through a post-scan optical assembly to provide the spot beam with predetermined geometrical dimensions, power, and angular velocity and range, which are selected such that the instantaneous spot beam is dragged in a scan direction over a desired length at a desired scan velocity, which allow the treated surface to be exposed for a predetermined exposure duration and have a predetermined fluence distribution providing the treated surface with a quality comparable to that of the surface processed by an excimer laser or a burst-mode fiber laser.

The present disclosure relates to a system for forming a material layer that may make use of an optical light source for generating an optical beam, and a beam shaping subsystem configured to shape the optical beam to generate a complex beam intensity profile. The complex shaped beam may be used to selectively melt at least portions of a bed of powder particles residing on a substrate during formation of the material layer, as the optical light source is moved. A computer may be used to control the optical light source. The complex beam intensity profile enables control over the microstructure of grains formed during melting of the powder particles as the material layer is formed.