A laser ablation system, and method, facilitates the execution of user-defined scans (i.e., in which a laser beam is scanned across a sample along a beam trajectory to ablate or dissociate a portion of the sample) and enables the user define additional scans while a scan is being executed.

Laser cutting systems and methods are described herein. One or more systems include a laser, an optical component, a fixture for holding a support with a part positioned on the support, and a controller. The controller is configured to identify a cut path for trimming excess material from a dental appliance, determine adjustment instructions for adjusting a focal length of the laser to cut along the cut path, and trim the excess material from the dental appliance along the cut path with the laser. The focal length is adjusted by adjusting at least one of: the laser, the optical component, and the fixture, and while moving the fixture at a constant speed relative to the laser to avoid increasing a brittleness of a polymer material of the dental appliance along the cut path.

A build plate-clamping assembly may include a work station having a build plate-receiving surface and a lock-pin extending from the build plate-receiving surface of the work station. The lock-pin may include a hollow pin body, a piston disposed within the hollow pin body, with the piston axially movable from a retracted position to an actuated position, and a plurality of detents, with the plurality of detents radially extensible through respective ones of a plurality of detent-apertures in the hollow pin body responsive to the piston having been axially moved to the actuated position. A methods of working on workpieces may include lockingly engaging a build plate at a first work station, performing a first work-step, releasing the build plate from the first work station, lockingly engaging the build plate at a second work station, and performing a second work-step. An additive manufacturing system may include a vision system with a first build plate-receiving surface and an additive manufacturing machine with a second build plate-receiving surface.

A high-efficiency and high-precision combined machining apparatus for a diamond wafer sheet and a combined high-efficiency and high-precision method for machining a diamond wafer sheet are disclosed. The apparatus can comprise a machining motion platform component installed on a base, a laser machining component, a grinding component, a polishing component and a detection component installed on a support frame. In operation, a high-energy laser beam of the laser machining component can focus on the surface of the diamond wafer sheet to be machined and perform a straight reciprocating irradiation on the diamond wafer sheet, thereby realizing the planarization machining of the diamond wafer sheet. Further, the grinding component and the polishing component realize further high-precision grinding planarization and finishing polishing machining under the action of the laser machining component.

A laser etching method for MEMS probes belongs to the technical field of semiconductor processing and testing; first, the MEMS probe laser etching method performs the parameter calculation to obtain the step angle of the motor according to the etching spacing of the single crystal silicon wafer; then it performs the initial position adjustment to rotate the spiral through-groove plate to the initial position and move the first etching point to the optical axis, and adjust the four-dimensional stage; and then it performs the laser etching and progress judgment; and finally adjusts the four-dimensional stage and the motor, including the downward movement distance, left movement distance and clockwise rotation angle of the four-dimensional stage and the rotation angle of the motor; the MEMS probe laser etching method, combined with the MEMS probe laser etching device, not only has higher etching accuracy, but also continuously adjusts the etching spacing.

Provided are a laser machining device and a laser machining method capable of stably operating an autofocus function without causing an unfavorable state such as an overshoot etc. A laser machining device and a laser machining method of the present invention performs a normal AF (autofocus) control when a scan position of the machining laser light and the detecting laser light is located in a work central portion, and performs a slow-tracking AF (autofocus) control with a trackability to a displacement of a main surface of a work reduced to be lower than a trackability of the normal AF control when the scan position of the machining laser light and the detecting laser light is located in a work end portion.

The invention relates to a method for the additive manufacture of three-dimensional metallic components (12), said components (12) being built layer-by-layer or section-by-section under vacuum conditions by fusing a metallic material with the component (12) at a machining point by means of a radiation source with a high energy density. In order to keep the energy applied to the machining point by the radiation itself relatively low, the metallic material is supplied in the form of a wire (28) which is preheated under vacuum conditions before reaching the machining point.

A laser oscillator support table includes a base, a fixed plate supported over the base with intermediary of a Z-axis direction movement unit, and a Y-axis direction moving plate mounted on the fixed plate, movable orthogonal to an X-axis direction. An optical path direction of the beam emitted from a laser oscillator supported by the laser oscillator support table is defined as the X-axis direction. The laser oscillator support table further includes a rotating plate that is mounted on the Y-axis direction moving plate rotatably around a rotation center pin fixed to the Y-axis direction moving plate and supports the laser oscillator, a Y-axis direction movement unit that moves the Y-axis direction moving plate in the Y-axis direction, and a rotational movement unit that rotates the rotating plate around the rotation center pin in a plane parallel to a plane formed by the X-axis direction and the Y-axis direction.

A device for processing microstructure arrays of polystyrene-graphene nanocomposites, including a laser generator, a vacuum chamber, an object stage, an ultraviolet filter and a gas flow control unit. The object stage is detachably fixed to a bottom of the vacuum chamber with a passage that can be opened or closed. The ultraviolet filter is provided in the vacuum chamber. A laser light emitted by the laser generator arrives at the object stage through the ultraviolet filter. The object stage is configured to place a sample to be processed. The gas flow control unit is communicated with the vacuum chamber and is configured to control the flow of the gas entering the vacuum chamber. The vacuum chamber is fixed on a three-axis precision positioning platform via a vacuum chamber clamp. The device disclosed herein aims to solve the existing difficulty in processing microstructure arrays of polystyrene-graphene nanocomposites.

A cutting method includes: forming a reformed region in a workpiece; and after forming the reformed region in the workpiece, cutting the workpiece along an intended cut line. In the cutting the workpiece, a dry etching process is performed from a front surface toward a rear surface of the workpiece while the workpiece is fixed on a support member at least under its own weight or by suction, to form a groove from the front surface to reach the rear surface of the workpiece.