An additive manufacturing device may include a laser source configured to generate a laser beam, a build material holder configured to hold an additive build material, a controllable deflector having a first scan rate, an AOD having a second scan rate faster than the first scan rate, and a controller. The controller may be configured to control the controllable deflector and the AOD to scan the laser beam relative to the build material holder to additively manufacture a workpiece in successive layers from the additive build material.

A processing apparatus is equipped with: a first stage system that has a table on which a workpiece is placed and moves the workpiece held by the table; a beam irradiation system that includes a condensing optical system to emit beams; and a controller to control the first stage system and the beam irradiation system, and processing is performed to a target portion of the workpiece while the table and the beams from the condensing optical system are relatively moved, and at least one of an intensity distribution of the beams at a first plane on an exit surface side of the condensing optical system and an intensity distribution of the beams at a second plane whose position in a direction of an optical axis of the condensing optical system is different from the first plane can be changed.

A system and method for automated laser ablation includes an end effector for performing laser ablation at a location with restricted access. The systems and methods of the present disclosure specifically provide for a miniature laser end effector which may be inserted through a port or bore in order to ablate the surface of an internal component of a complex assembly. In several embodiments of the present subject matter, the end effector is mounted on a machine and coupled to a laser system.

An optical device that is intended for laser treatment of internal surfaces of a covering part of the leading-edge type, including a collimator that is intended to be connected to a laser source via an optical fibre to produce a laser beam having a collimated and flat spatial pulse profile, a cylindrical lens that is configured to focus the laser beam along a spatial line that is transverse to the propagation of the laser beam thus forming a line-laser-beam, a reflecting optical component that is configured to be able to be introduced into the interior of the covering part and to uniformly reflect the line-laser-beam onto at least one internal surface of the covering part and in directions of incidence that are almost normal to at least one internal surface.

A resin curing system provided by stereolithography (SLA) three-dimensional (3D) printer includes a pair of Risley prism for optical steering of laser energy to achieve improved resolution.

An additive manufacturing system is disclosed that comprises two or more lasers for precisely heating a fiber-reinforced thermoplastic feedstock and a fiber-reinforced thermoplastic workpiece in preparation for depositing and tamping the feedstock onto the workpiece. The system employs feedforward, a variety of sensors, and feedback to ensure that the feedstock and workpiece are properly heated.

A laser beam irradiating apparatus includes a laser oscillator configured to emit a laser beam, a first polarization beam splitter configured to separate the laser beam into a first laser beam of s-polarized light and a second laser beam of p-polarized light, a first spatial light modulator configured to modulate the first laser beam according to a phase pattern, and emit the resulting first laser beam, a second spatial light modulator configured to modulate the second laser beam according to a phase pattern, and emit the resulting second laser beam; a second polarization beam splitter configured to synthesize the first laser beam emitted from the first spatial light modulator and the second laser beam emitted from the second spatial light modulator, and an imaging unit configured to image the synthesized laser beam, and irradiate a target object with the resulting laser beam.

An automated or manual laser ablation system and method of use to enable safe, non-user-contact, rapid, and remote cleaning of industrial tubular equipment, e.g. heat-exchangers and reactors. The laser ablation system comprises: a fiber optic cable (12) with a laser probe output end (20), connected to an optics unit (5 or 6) enclosed within a laser probe housing (14). The optics unit comprises: a double convex and/or one or two plano-convex lens; and an Axicon prism, mirror cone, and/or galvo-scanning mirror to emit a rotating or a fixed circular beam. The laser beam cleans a plurality of reactor tubes' internal wall to cause the evaporation of deposit buildups and rust. The laser ablation system further comprises: an air vacuum system (30) positioned to cool the ablation system while removing the debris to a vacuum generator (35); and/or a push motor (60) that pushes and pulls the system through the tubes.

The present disclosure provides a device and a method for laser-based separation of a transparent, brittle workpiece, comprising a laser that emits a laser beam having an intensity (I.sub.L) along an optical axis (P), and an optical device. The optical device has at least one one-piece double axicon. The double axicon has an entrance surface and the optical device has an exit surface. The entrance surface is such that in the double axicon, a ring beam is formed. The intensity (I.sub.L) in the double axicon is lower than the threshold intensity (I.sub.S) of the material of the double axicon. The exit surface is such that a line focus having a maximum intensity (I.sub.max) and a length (L.sub.T) is generated in the direction of the laser beam behind the exit.

A laser system is configured for providing a laser line in a working plane for line illumination of an object. The laser line extends in a first direction over a significant length and in a second direction over a small extent. The laser system comprises a laser source for providing a laser beam as basis for an elongated input laser beam propagating along a propagation direction, and a homogenization and focussing unit for homogenizing the elongated laser beam to form the laser line. The laser system is in particular suitable for providing a laser line that can be stitched to another laser line of a respective further laser system.