Apparatus (1) for additively manufacturing of three-dimensional objects by means of successive layerwise selective irradiation and consolidation of layers of a build material which can be consolidated by means of an energy beam, with a carrier device (2) with at least one carrier element (3) for carrying build material and/or at least one object to be built and a driving unit (4) configured to drive the at least one carrier element (3), wherein the driving unit (4) is coupled with the carrier element (3) via at least one coupling means (5), wherein at least one securing unit (10) is provided that is configured to secure the coupling of the carrier element (3) with the at least one coupling means (5), wherein the securing unit (10) is configured to apply a securing force directed axially on the coupling means (5).

Laser cutting systems and methods are described herein. One or more systems include a laser generating component, an optical component, a fixture for holding a support with a part positioned on the support, and a control mechanism for adjusting at least one of the laser generating component, the optical component, and the fixture such that a ratio of a laser energy applied to the part and a part material thickness is maintained within a predetermined acceptable range at each point along a cut path to cut through the part while maintaining the integrity of the support. Other systems and methods are disclosed herein.

A method for metallization includes providing a transparent donor substrate (34) having deposited thereon a donor film (36) including a metal with a thickness less than 2 pm. The donor substrate is positioned in proximity to an acceptor substrate (22) including a semiconductor material with the donor film facing toward the acceptor substrate and with a gap of at least 0.1 mm between the donor film and the acceptor substrate. A train of laser pulses, having a pulse duration less than 2 ns, is directed to impinge on the donor substrate so as to cause droplets (44) of the metal to be ejected from the donor layer and land on the acceptor substrate, thereby forming a circuit trace (25) in ohmic contact with the semiconductor material.

In a laser machining apparatus, a scanner is configured to scan a laser beam emitted from a laser beam emission device. A first part of a workpiece is exposed through an opening formed in the workpiece. A controller is configured to perform: acquiring shape data indicative of a shape of the workpiece; acquiring machining pattern data indicative of a machining pattern to be machined on the first part; acquiring a length of the machining pattern based on the machining pattern data; calculating an unmachinable position on a setting surface using the length and the shape data, the unmachinable position resulting from a second part of the workpiece hindering the laser beam reaching the first part, at least a part of the machining pattern being unmachinable on the first part in a state where the workpiece is set on the unmachinable position; and displaying the unmachinable position on a display.

Methods and systems for crystallizing a thin film provide a laser beam spot that is continually advanced across the thin film to create a sustained complete or partial molten zone that is translated across the thin film, and crystallizes to form uniform, small-grained crystalline structures or grains.

The present disclosure provides a laser peen forming device and method with an adjustable absorbing layer. The laser peen forming device with the adjustable absorbing layer includes a laser peening system, an x-y-z three-axis machining platform, and a working tank, where the working tank is secured on the x-y-z three-axis machining platform; the laser peening system is located above the working tank; a laser irradiation system and a three-dimensional information acquirer are further arranged above the working tank; a workpiece, a tool anode, a heating device, and a temperature sensor are arranged in the working tank; the workpiece is connected to a cathode of an electric box; the tool anode is connected to an anode of the electric box; the tool anode is located above the workpiece and keeps a predetermined distance from the workpiece; and the working tank is connected to a phosphating solution flowing system.

A method for fabricating a protonic ceramic energy device includes: coating an electrolyte layer on an anode layer; and densifying the electrolyte layer by a rapid laser reactive sintering (RLRS) process on the electrolyte layer and/or the anode layer to form a half-cell comprising a dense electrolyte and a porous anode.

A laser annealing device includes: a CW laser device configured to emit continuous wave laser light caused by continuous oscillation to preheat the amorphous silicon; a pulse laser device configured to emit the pulse laser light toward the preheated amorphous silicon; an optical system configured to guide the continuous wave laser light and the pulse laser light to the amorphous silicon; and a control unit configured to control an irradiation energy density of the continuous wave laser light so as to preheat the amorphous silicon to have a predetermined target temperature less than a melting point thereof, and configured to control at least one of a fluence and a number of pulses of the pulse laser light so as to crystallize the preheated amorphous silicon.

A laser doping device includes: a solution supply system configured to supply a solution containing dopant to a doping region; a pulse laser system configured to output pulse laser light including a plurality of pulses, the pulse laser light transmitting through the solution; a first control unit configured to control a number of pulses of the pulse laser light for allowing the doping region to be irradiated, and to control a fluence of the pulse laser light in the doping region; and a second control unit configured to control a flow velocity of the solution so as to move bubbles, from the doping region, occurring in the solution every time of irradiation with the pulse.

This invention provides a decorating device for vehicle-interior components, which can accurately provide gradation on the design of the surface of a resin component. The decorating device comprises a laser-irradiating device and a control device. The control device comprises a virtual-decorating surface 5a that is deformed so as to have a different curvature than the surface of the actual decorating surface 5, thus allowing for the drawing of designs thereon. The control device prepares laser-irradiating data based on the drawing-data, and it controls the laser-irradiating device based on the laser-irradiating data. The laser-irradiating device irradiates the laser L1 focused on the virtual-decorating surface 5a and conducts the laser processing on the actual decorating surface 5, with the focal point of the laser L1 having been shifted from the actual decorating surface 5.