A laser processing device comprising: a light source configured to output laser light; a spatial light modulator configured to display a modulation pattern for modulating the laser light output from the light source; a condenser lens configured to condense the laser light modulated by the spatial light modulator, on an object; and a control unit configured to control the spatial light modulator to adjust the modulation pattern in accordance with a traveling direction of a condensing point of the laser light with respect to the object.

A laser soldering system using dynamic light spot and a method thereof are provided. A laser module is controlled to radiate toward multi-lens to form a light spot on a soldering target for soldering, and a lens distance between the multi-lens is adjusted to adjust a light spot size. The disclosure may provide multiple heating densities respectively adequate to different soldering status via adjusting the light spot size when using same laser power, so as to improve the soldering quality.

A laser processing apparatus includes two chuck tables for holding workpieces on their holding surfaces, an X-axis feed unit for moving the chuck tables which are being arrayed in an X-axis direction, a laser beam applying unit for applying a laser beam to the workpiece on one at a time of the chuck tables to process the workpiece, and a pair of delivery areas arrayed in the X-axis direction on both sides of the laser beam applying unit, for delivering workpieces to and from the chuck tables. The laser beam applying unit includes a laser oscillator, a beam condenser, and a laser beam scanning unit for displacing a position where the laser beam is applied to the holding surface of the one of the chuck tables.

A processing method of a workpiece used when the workpiece is processed is provided. The processing method of a workpiece includes a disposing step of disposing the workpiece in a gas containing a substance that generates an active species that reacts with the workpiece, a measurement step of measuring the distribution of the thickness of the workpiece disposed in the gas, and a laser beam irradiation step of irradiating the workpiece in the gas with a laser beam of which the power is adjusted based on the distribution of the thickness measured in the measurement step. In the laser beam irradiation step, the removal amount by which a region irradiated with the laser beam in the workpiece is removed by the active species is controlled by irradiating the workpiece with the laser beam of which the power is adjusted.

A method for producing a cavity in a substrate composed of hard brittle material is provided. A laser beam of an ultrashort pulse laser is directed a side surface of the substrate and is concentrated by a focusing optical unit to form an elongated focus in the substrate. Incident energy of the laser beam produces a filament-shaped flaw in a volume of the substrate. The filament-shaped flaw extends into the volume to a predetermined depth and does not pass through the substrate. To produce the filament-shaped flaw, the ultrashort pulse laser radiates in a pulse or a pulse packet having at least two successive laser pulses. After at least two filament-shaped flaws are introduced, the substrate is exposed to an etching medium which removes material of the substrate and widens the at least two filament-shaped flaws to form filaments. At least two filaments are connected to form a cavity.

A marking system for decorating one or more workpieces includes a plurality of marking stations that can mark product images on blank workpieces to produce product workpieces, at least some of which have different sizes, shapes, materials, or a combination thereof, a control system that can select one of the plurality of marking stations and send product image data to the selected one of the plurality of marking stations, and a robotic manipulator that can transport a blank workpiece to the selected marking station under the control of the robotic manipulator. The selected marking station can mark the product image the blank workpiece based on the product image data which produces a product workpiece. The robotic manipulator can remove the product workpiece from the selected one of the plurality of marking stations.

A method for laser keyhole welding is disclosed to weld two pieces together made of a metal alloy. The method independently adjusts power in a focused center beam and power in a concentric focused annular beam. At the termination of a weld, the power of the annular beam is reduced, motion of the focused beams is stopped, the power of the center beam is increased, and the power of both beams is initially ramped down rapidly and then ramped down slowly. Increasing the power of the center beam equalizes the temperature of both pieces prior to solidification and cooling at the termination of the weld. An additional pulse of power may be applied to prevent the formation of defects or to erase any defects.

A laser beam application unit of a laser processing machine includes a laser oscillator that emits a laser beam, an fθ main lens that focuses and applies the laser beam which has been emitted from the laser oscillator, to a workpiece held on a holding table, a scan unit that is arranged on an optical path between the laser oscillator and the fθ main lens, scans the laser beam, and guides the resulting scanned laser beam to the fθ main lens, and an fθ sub-lens that is arranged on the optical path between the laser oscillator and the scan unit and converts the laser beam from parallel light into diffused light.

A laser beam irradiation unit of a laser processing apparatus includes a first splitting unit that causes a laser beam emitted from a laser oscillator to branch into a first optical path and a second optical path, a first beam condenser that focuses the laser beam having been introduced to the first optical path, and a second beam condenser that focuses the laser beam having been introduced to the second optical path. The laser beam irradiation unit further includes a second splitting unit on the first optical path between the first splitting unit and the first beam condenser that splits the laser beam into at least two laser beams, and a laser beam scanning unit on the second optical path between the first splitting unit and the second beam condenser that executes scanning with the laser beam and introduces the laser beam to the second beam condenser.

Methods of separating a glass web include exposing a separation path on the glass web to a laser beam that produces thermal stress along the separation path without damaging the glass web. The methods further include redirecting a portion of the laser beam to create a defect on the separation path while the separation path is under thermal stress produced during the exposing the separation path on the glass web to the laser beam, whereupon the glass web separates along the separation path in response to creating the defect. Apparatus are further provided for separating a glass web with at least one laser beam generator that produces a laser beam to heat a separation path and a mirror configured to reflect an end portion of the laser beam to create a defect at a location of the separation path on the glass web.