A laser processing apparatus includes a plurality of laser sources, an optical fiber connected to each of the plurality of laser sources, the optical fiber being one of a plurality of the optical fibers, and diffractive optical elements on which laser light beams are incident, laser light beams being emitted from the plurality of optical fibers. Diffracted light reflected by each of the diffractive optical elements forms an image on an object at a substantially identical intensity distribution and at a substantially identical focal position.

A laser processing system configured to provide a processing beam is provided. The laser processing system includes a laser, a beam splitting module, a first adjustment module, and a second adjustment module. The laser is configured to provide a laser beam. The beam splitting module is configured to split the laser beam into a first laser beam and a second laser beam. The first adjustment module is disposed on a transmission path of the first laser beam and configured to adjust the first laser beam to a central portion of the processing beam. The second adjustment module is disposed on a transmission path of the second laser beam and configured to adjust the second laser beam to an outer ring portion of the processing beam.

A processing head including a first laser array element in which a plurality of first photonic crystal lasers are arranged in a first direction, and a second laser array element in which a plurality of second photonic crystal lasers are arranged in the first direction, the first laser array element and the second laser array element emit laser light in a third direction intersecting the first direction and a second direction to a processing target object while being relatively moved with respect to the processing target object in the second direction intersecting the first direction, and when viewed from the second direction, the second end photonic crystal laser and the second intermediate photonic crystal laser overlap each other.

A laser engraving machine with a three-point suspension system and an inverted X-Y axis support system wherein the X-axis beam is to and mounted below the Y-axis beams and the Y-axis beams are mounted inwardly of the outer ends of the X-axis beam and are structurally integrated with the machine housing. In addition, a counterweight in the form of a second, independently activatable laser is added to the drive belt to reduce or eliminate vibration during rapid reciprocal movement of the tool during an engraving process.

Systems and processes of cutting and drilling in a target substrate uses a laser (e.g., a pulsed laser) and an optical system to generate a line focus of the laser beam within the target substrate, such as a glass substrate sheet, are provided. The laser cutting and drilling system and process creates holes or defects that, in certain embodiments, extend the full depth of the glass sheet with each individual laser pulse, and allows the laser system to cut and separate the target substrate into any desired contour by creating a series of perforations that form a contour or desired part shape. Since a glass substrate sheet is brittle, cracking will then follow the perforated contour, allowing the glass substrate sheet to separate into any required shape defined by the perforations.

An additive manufacturing apparatus and corresponding method for building an object by layerwise consolidation of material, where the apparatus includes a build enclosure containing a build support for supporting the object during the build, a material source for providing material to selected locations for consolidation, a radiation device for generating and directing radiation to consolidate the material at the selected locations and an acoustic sensing system. The acoustic sensing system may be arranged to detect acoustic signals generated in the build enclosure by consolidation of the material with the radiation. The acoustic sensing system may be a passive acoustic sensing system arranged to detect acoustic signals generated in the build enclosure that are indicative of at least one condition of the building process and/or the object.

Provided is a multi-junction solar cell in which two or more absorption layers having different bandgaps are stacked on one another. The multi-junction solar cell includes a first cell including a first absorption layer, and a second cell electrically connected in series onto the first cell, wherein the second cell includes a second absorption layer having a higher bandgap compared to the first absorption layer, and a plurality of recesses penetrating through the second absorption layer.

An apparatus and a method for thermal processing within a processing region (1) at a workpiece surface (2) by means of a laser beam (6) emitted by at least one radiation source (5). Arranged in the beam path of the laser beam (6) between the at least one radiation source (5) and the processing region (1) on the workpiece surface (2), there is at least one element (10, 11, 12) by means of which the intensity of the laser beam (6) is modifiable in a locally defined manner within the processing region (1). As an alternative or in addition thereto, the intensity of at least one of the laser beams (6) is modifiable in a locally defined manner within the processing region (1) by a defined actuation of the plurality of radiation sources (5) such that a locally defined distribution of the intensity of the laser beam (6) striking the workpiece surface (2) is achievable within the processing region (1).

For processing a workpiece held by a chuck table with branched pulsed laser beams, if it is assumed that branch intervals at which adjacent ones of the branched pulsed laser beams are spaced from each other on a surface of the workpiece are represented by L, a value calculated by dividing a processing feed speed at which the chuck table is moved with respect to a condensing lens by a processing feed unit by the frequency of the pulsed laser beam at a processing point where the branched pulsed laser beams are applied to the workpiece is represented by S, and any integer is represented by n, then the branching intervals, the processing feed speed, and the frequency of the pulsed laser beam are established to satisfy the relationship of L≠n×S.

Described are a method and a control data generation device (54, 54′) for use therein for generating control data (PSD) for a device (1) for the additive manufacture of a manufacturing product (2) in a manufacturing process, in which build-up material (13) is built up and selectively solidified, wherein, for the solidification process, the build-up material (13) is irradiated with at least one energy beam (AL) on a build field (8), and an area of incidence (AF) of the energy beam (AL) on the build field (8) is moved in order to melt the build-up material (13). The control data (PSD) are generated such that the energy beam (AL) has an intensity distribution (GIV), at the area of incidence (AF) on the build field (8), in a section plane (x, y) running perpendicularly to the beam axis (SA) of the energy beam (AL), which intensity distribution has at least one local minimum (MIZ) in a middle region along at least one secant of the intensity distribution (GIV) in the section plane (x, y) and has an intensity profile curve (IPK), running along the edge (R) of the intensity distribution (GIV), which intensity profile curve has, at least at one point, a maximum value (MAX), and, at least at one point in a region opposite the maximum value (MAX) on the intensity profile curve (IPK), a minimum value (MIN).

Also described are a method and a control device (50) for controlling a device (1) for the additive manufacture of a manufacturing product (2) using this control data (PSD), and a device (1) for the additive manufacture of manufacturing products.