A method for slicing an ingot column is provided, including the following steps: immersing the column into a solution; rotating the column; focusing the rotating column with a focusing device; and using a laser device to cut the rotating column into sliced wafers. The slicing equipment of the present invention has a simple structure, easy operation, small kerf of the column, and fast slicing speed.

An apparatus for laser processing of very wide non-woven fabric materials at high speeds. This invention enables a laser beam to sever, perforate and pattern a large piece of fabric materials planarly disposed at regular or irregular spatial intervals over the entire width while the fabric passes from one roller to another roller at high speeds by precisely managing focus and intensity of the beam at the focal point on the web. A control system managing the laser processing system enables rapid reconfiguration of perforation patterns. The fabric can be woven or nonwoven, homogeneous or nonhomogeneous material with uniform or nonuniform thickness. An optical sensor is provided to sense the laser processing as it is performed and provide feedback to a system controller to optimize laser processing performance in real time.

A method is proposed for producing a packaging, having a method step of microperforation of a flexible material as a packaging film, comprising: provision of the flexible material as a packaging film, transport of the flexible material over a transport section, provision of a laser in order to generate a perforation of the flexible material with its beam. For a packaging with improved gas exchange, a laser system with a wavelength in the range of from 150 nm to 1064 nm, preferably from 355 nm to 532 nm, is used for the laser, and the perforation with the laser is carried out during the movement of the flexible material of the packaging film during the transport.

The invention relates to a method for manufacturing an endoscope insertion tube (2).The insertion tube (2) has a proximal passive flexible section (20) and a distal angled section (A). The entire insertion tube, including the passive flexible section (20) and the angled section (A), is formed from a single tube element. The invention further relates to an endoscope having such an insertion tube (2).

The invention relates to a method for manufacturing an endoscope insertion tube (2).The insertion tube (2) has a proximal passive flexible section (20) and a distal angled section (A). The entire insertion tube, including the passive flexible section (20) and the angled section (A), is formed from a single tube element. The invention further relates to an endoscope having such an insertion tube (2).

A method for processing a transparent workpiece includes forming a contour of defect in the transparent workpiece and separating the transparent workpiece along the contour using an infrared laser beam. During separation, the method also includes detecting a position and propagation direction of a crack tip relative to a reference location and propagation direction of an infrared beam spot, determining a detected distance and angular offset between the crack tip and the reference location of the infrared beam spot, comparing the detected distance to a preset distance, comparing the detected angular offset to a preset angular offset, and modifying at least one of a power of the infrared laser beam or a speed of relative translation between the infrared laser beam and the transparent workpiece in response to a difference between the detected distance and the preset distance and between the detected angular offset and the preset angular offset.

Provided is a welding method enabling enhancement of quality of welding between an upper plate and a lower plate. One aspect of the present disclosure is the welding method including welding the upper plate and the lower plate overlapped with the upper plate by irradiating a surface of the upper plate with a laser beam. The welding includes: forming an auxiliary welding path that is continuous and includes a reciprocating or circling path; and forming a main welding path that intersects a welding advancing direction and that includes turning points, after formation of the auxiliary welding path.

Methods of determining a polygon ablation pattern for use in mitigating one or more defects in an optical device are described. A method comprises identifying spatial coordinates of one or more defects areas in a first image of the optical device taken when tinted, defining a region of interest around at least one defect area of the one or more defect areas, and determining a polygon boundary around the at least one defect area in the region of interest to define the polygon ablation pattern.

Methods of determining a polygon ablation pattern for use in mitigating one or more defects in an optical device are described. A method comprises identifying spatial coordinates of one or more defects areas in a first image of the optical device taken when tinted, defining a region of interest around at least one defect area of the one or more defect areas, and determining a polygon boundary around the at least one defect area in the region of interest to define the polygon ablation pattern.

In order to create a laser tool, in particular for the structuring of cylinder running surfaces, that offers the possibility of adjusting the focal position of the laser beam with high process reliability and with high repeatability, it is provided that the laser tool has a laser source for producing laser beams, a collimator for producing a parallel course of the laser beams from the laser source, which are passed through a lens that is located within a rotatable spindle, wherein an optical device for deflecting the laser beams onto a material surface is attached to an end of the spindle facing away from the laser source, wherein the collimator is movable parallel to the laser beam by means of a drive.