In forming modification layers by radiating laser light to an inside of a processing target object from a modifying device periodically while rotating the processing target object held by a holder relative to the modifying device by a rotating mechanism and by moving the modifying device relative to the holder in a diametrical direction by a moving mechanism, a boundary position of the laser light in the diametrical direction is calculated, the boundary position being a position where a circumferential distance between the modification layers becomes a required threshold value, and a diametrical distance between the modification layers is reduced in a moving direction of the modifying device from the boundary position and/or a frequency of the laser light is reduced.

A method for monitoring the process in laser material processing and provides a corresponding method, comprising the steps of taking a real-time image comprising the position and surrounding of the process where material processing occurs by a camera that is arranged in or on a laser material processing head; determining at least one image section in the real-time image and its position on a camera sensor; determining an actual position of the process in the material processing, and a nominal position of the relevant image detail using a projection of programmed path data for controlling the laser material processing head in the section of the real-time image, and the transfer of the at least one image section from the camera to a computer.

A machining process, associated with a workpiece, may include controlling, by a control device, a pulse repetition frequency (PRF) of an ultrashort pulse laser. The PRF may be controlled to maintain a substantially constant distance, on the workpiece, between adjacent pulses on a path. The substantially constant distance may be maintained despite changes in a speed of the path relative to the workpiece. An amount of energy of each pulse on the path may be substantially constant despite changes to the PRF associated with controlling the PRF.

A laser controller is configured to output a laser beam in response to the input of command power. The laser controller receives the input of the command power and the input of an acceleration of the relative movement of a laser machining head and a workpiece, calculates output power based on the command power and a coefficient corresponding to the acceleration, and outputs the laser beam according to the calculated output power.

Aspects of continuous feed fabric cutting are described. In one example, a system includes a textile cutter having a cutting table and a laser cutting assembly. The laser cutting assembly includes a set of laser cut modules arranged in a row to provide a combined laser cutting span across at least a portion of the cutting table. The laser cut modules provide respective laser cutting spans which, collectively, form the combined laser cutting span across the cutting table. As a textile sheet is fed across the cutting table of the textile cutter, one or more textile panels or pieces of fabric can be cut out from the textile sheet using laser beams along the region where the textile sheet intersects or crosses the combined laser cutting span. The laser cutting assembly can provide continuous cutting as a sheet is being fed across the cutting table.

A method for monitoring the process in laser material processing and provides a corresponding method, comprising the steps of taking a real-time image comprising the position and surrounding of the process where material processing occurs by a camera that is arranged in or on a laser material processing head; determining at least one image section in the real-time image and its position on a camera sensor; determining an actual position of the process in the material processing, and a nominal position of the relevant image detail using a projection of programmed path data for controlling the laser material processing head in the section of the real-time image, and the transfer of the at least one image section from the camera to a computer.

A method and apparatus for forming a visible symbol or other indicium on a tab portion of a beverage container. The method comprises the steps of advancing a tab stock material through a series of tab-forming stations. The tab portion is at least partially formed from the tab stock at each of the tab-forming stations. The advancement of the tab stock is dwelled or halted while the tab is formed. The tab stock is accelerated from dwell to resume advancement of the tab stock material between the stations. A selected portion of the tab is irradiated with light energy to form the visible indicium. The apparatus comprises a plurality of tab-forming stations, each tab-forming station at least partially forming the tab from a tab stock. A conveyor or track mechanism is configured to advance the tab stock from one tab-forming station to another. An etching apparatus is associated with the conveyor and tab-forming stations to selectively etch the symbol on the tab. A sensor is coupled to the tab stock to sense acceleration of the tab stock from rest during advancement of the tab stock. The sensor is coupled to the etching apparatus to permit the etching apparatus to etch the symbol while the tab stock is accelerated.

A method for manufacturing a crimp terminal having a crimp portion that allows crimp connection to a conductor part of a coated wire includes forming a tubular body by bringing together side edges of a plate material made of metal composed of a copper alloy having a copper content ratio of greater than or equal to 70%, irradiating a periphery of the sides edges, which are brought together, with laser light from a laser irradiation unit to weld the side edges which are brought together, and setting a power density of the laser light and a sweep rate of the laser light in such a manner that a weld bead formed at the side edge portion after the welding has a width of 80 m to 390 m.

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 device and a method for forming a structure on a workpiece by processing radiation while the workpiece is moved by a transport device, in which correction data of the workpiece are acquired by optical sensors. The correction data includes movement data of the workpiece and/or position data of a structure created on the workpiece by the processing radiation, and, dependent on the correction data, the deflection of processing radiation brought about by a deflection unit is determined, in particular corrected.