A feed head apparatus for laser additive manufacturing, comprising an optical housing configured to receive a laser beam and a feedstock therein, wherein the feedstock is for use in an additive manufacturing process that includes a build plate or other additive manufacturing work surface; a first reflective optic for receiving and reflecting the laser beam; and a second reflective optic for receiving laser light reflected by the first reflective optic, wherein the second reflective includes a first region of curvature for directing a portion of the laser light received from the first reflective optic onto the feedstock in a cylindrical configuration such that the feedstock and the cylinder of laser light are coaxial with regard to one another; and a second region of curvature for directing a portion of the laser light received from the first reflective optic onto the build or surface only in a ring-shaped configuration, wherein the ring of laser light surrounds the feedstock and the cylinder of laser light and is coaxial therewith.

An arrangement monitors an optical element. The arrangement includes: a light source configured to emit radiation onto a surface of the optical element; a detector configured to detect the radiation that has been at least partially reflected at the surface of the optical element; and a holder for the optical element, in which the light source and the detector are integrated. The holder has a cooling region through which a cooling liquid is configured to flow, the cooling region being in contact with the optical element. The holder has a reservoir, through which a beam path between the light source and the detector extends. The reservoir is configured to receive the cooling liquid leaking out at the optical element in case of a leakage.

To provide a fluid contact member whose corrosion resistance is particularly further improved than that in the related art. In order to solve this problem, a fluid contact member 10 includes a fluid contact portion 1 configured to be in contact with a fluid, the fluid contact portion 1 has a cobalt-based alloy phase 2 having a dendrite, and a compound phase 3 formed in an arm space of the dendrite and containing chromium carbide, and among a plurality of secondary arms 5 extending from one primary arm 4 constituting the dendrite, an average interval between adjacent secondary arms 5 is 5 μm or less. At this time, the average interval is preferably 3 μm or less. Further, the compound phase 3 is preferably formed discontinuously in the dendrite arm space.

A laser apparatus and a method for manufacturing a display device are provided. A laser apparatus includes: a stage; a laser providing unit above the stage and configured to provide a laser beam; a scanner configured to adjust an optical path of the laser beam such that the laser beam is irradiated to an irradiation line formed above the stage; and a control unit to control an operation of the scanner, and the scanner includes a shutter located on an optical path of the laser beam emitted from the laser providing unit and configured to perform an opening/closing operation.

A system that uses a scalable array of individually controllable laser beams that are generated by a fiber array system to process materials into an object. The adaptive control of individual beams may include beam power, focal spot width, centroid position, scanning orientation, amplitude and frequency, piston phase and polarization states of individual beams. Laser beam arrays may be arranged in a two dimensional cluster and configured to provide a pre-defined spatiotemporal laser power density distribution, or may be arranged linearly and configured to provide oscillating focal spots along a wide processing line. These systems may also have a set of material sensors that gather information on a material and environment immediately before, during, and immediately after processing, or a set of thermal management modules that pre-heat and post-heat material to control thermal gradient, or both.

A three-dimensional (3D) printing device may include a pulsed electromagnetic radiation source; a build platform to maintain a number of layers of build material thereon and receive pulsed electromagnetic radiation from the pulsed electromagnetic radiation source; a micromirror array to selectively direct the pulsed electromagnetic radiation from the pulsed electromagnetic radiation source to the build material on the build platform; and a coolant tank with coolant therein to cool the micromirror array.

Embodiments of an integrated laser hot wire deposition head are disclosed. In one embodiment, the deposition head includes a structural frame, a laser process sub-system, a wire feeding device, and a contact tube. The laser process sub-system is mounted within the structural frame to deliver a single beam path laser beam in a longitudinally-oriented direction toward a substrate or a part to be additively manufactured. The wire feeding device and contact tube are mounted within the frame to feed a consumable filler wire toward the substrate or part at an angle with respect to the longitudinally-oriented direction. The deposition head can be moved omni-directionally with respect to the substrate or the part, under the guidance of a motion control system, to additively manufacture the part without having to angularly change an orientation of the single beam path laser beam from the longitudinally-oriented direction or rotate the deposition head.

An end effector (20) for a machine tool (10) for laser machining processes configured to direct a laser beam (L) onto a working surface (16) along an optical axis (OP), the end effector (20) comprising a supporting body (22) which includes a duct (26) having an axis parallel to at least one portion of the optical axis (OP) of propagation of the laser beam (L); the supporting body (22) being configured to couple the duct (26) to an outlet portion, in particular a sensor cone, which comprises a further duct having an axis parallel to at least one portion of the optical axis (OP) of propagation of the laser beam (L), the outlet portion being configured to be coupled to the supporting body (22) and to provide an outlet for the laser beam (L) towards a working surface (16).

The aforesaid supporting body (22) further comprises, formed in a single piece:

a set of auxiliary fluid ducts (520, 522, 523, 524) configured to direct respective fluids used in laser machining processes onto the working surface, configured to couple to the outlet portion; and

a heat exchanger (400) for cooling systems located in the supporting body (22) so as to occupy a volume (400a, 400b) that surrounds at least one portion of the tubular duct (26) of the supporting body (22), wherein the heat exchanger (400) comprises an inlet chamber and an outlet chamber in communication with one another for passage of cooling fluid, and wherein the heat exchanger (400) has a lattice structure of thermally conductive elements (402) configured to allow passage of a cooling fluid in the heat exchanger (400) between the inlet chamber and the outlet chamber.

Laser ablation and laser processing fume and contaminant capture systems are disclosed herein. An example system includes a housing forming a partial enclosure that is configured to be placed against a target surface, a transparent window being integrated into a top surface of the housing, the transparent window being configured to allow for the transmission of a laser scan pattern to the target surface, and an outlet port for establishing a negative pressure inside the housing. Air is drawn into the housing through a first inlet port, the air carries contaminants created during ablation of the target surface by the laser scan pattern out of the outlet port.

Systems and methods are disclosed relating to welding-type power supplies. In some examples, the power supplies may have no vents, which may help prevent environmental contaminants from entering the power supplies. Instead, the power supplies include one or more thermal interfaces configured to conduct heat generated by internal circuitry of the power supply from the interior of the power supply to an exterior of the power supply. Additionally, the thermal interface(s) may be configured for attachment to one or more exterior heat dissipating devices.