Method and system for a laser welding process employing the use of a single pulsed fiber laser source configured to generate a radiative output with a wavelength spectrum extending from about 1.8 microns to about 2.6 microns. In a specific case, the laser output from the single pulsed fiber laser source is focused onto the interface of the two pieces of materials at least one of which includes any of glasses, inorganic crystals, and semiconductors.

A rechargeable battery is produced by welding a metal foil to a contact element to make electrical contact with an electrode of the rechargeable battery. An edge region of the metal foil is brought into contact with a first surface of the contact element and welded to the contact element by applying a laser beam to a second surface of the contact element. The second surface being averted from (opposite to) the first surface of the contact element. The metal foil and further planar constituents of the rechargeable battery are wound to provide the rechargeable battery with an at least essentially cylindrical design. The contact element-is oriented at right angles to the metal foil.

A refractive index writing system includes a pulsed laser source, an objective lens for focusing an output of the pulsed laser source to a focal spot in an optical material, and a scanner for relatively moving the focal spot with respect to the optical material along a scan region. A beam multiplexer divides the output of the laser source into at least two working beams that are focused to variously shaped focal spots within the optical material. A controller controls at least one of a temporal and a spatial offset between the focal spots of the working beams together with the relative speed and direction of the scanner for maintaining an energy profile within the optical material along the scan region above a nonlinear absorption threshold of the optical material and below a breakdown threshold of the optical materials.

A method of laser welding together two or more overlapping metal workpieces (12, 14, or 12, 150, 14) included in a welding region (16) of a workpiece stack-up (10) involves advancing a beam spot (44) of a laser beam (24) relative to a top surface (20) of the workpiece stack-up along a first weld path (72) in a first direction (74) to form an elongated melt puddle (76) and, then, advancing the beam spot (44) of the laser beam (24) along a second weld path (78) in a second direction (80) that is opposite of the first direction while the elongated melt puddle is still in a molten state. The first weld path and the second weld path overlap so that the beam spot of the laser beam is conveyed through the elongated melt puddle when the beam spot is advanced along the second weld path.

Devices and methods for cutting an opening from a workpiece. The apparatus comprises a first emitter and a second emitter, a power of a first laser emitted by the first emitter being smaller than a power of a second laser emitted by the second emitter. The apparatus further comprises a laser head, an image sensor, and a processing unit. The laser head is coupled to the first and second emitters and adapted to move adjacent to a first side of a workpiece and direct the first and second lasers onto the first side. The image sensor is configured to receive the first laser to form an image of the first laser. The processing unit is configured to determine a difference between a profile of the image of the first laser and a predetermined profile of an opening to be cut from the workpiece.

A processing device to form a pattern on a surface of an object to be processed using diffraction of a laser beam emitted from a laser source, the device including: a main body providing a space to process the object using the laser beam emitted from the laser source; a laser transmission unit formed at a first portion of the main body, and configured to diffract the laser beam so that a diffracted laser beam is emitted toward the object; an actuator formed at a second portion of the main body, and connected to the laser transmission unit so as to change an emission pattern of the diffracted laser beam while rotating the laser transmission unit vertically/horizontally or in a set radius; and a controller provided at a third portion of the main body, and connected to the actuator to control an operation of the actuator.

A laser welding control method, apparatus and system, and an electronic device are disclosed, the method includes: receiving a current position of a welding head fed back by an encoder; determining whether the current position reaches a set position; and in response to the welding head reaching the set position, sending a laser control signal to a laser device to control the laser device to output laser at the set position.

Disclosed is a bridge and body embodiment used in laser cutting machines. The embodiment has two bodies located facing each other and extending along at least a first guide component on an inner surface longitudinally, a bridge moving back and forth on the first guide component by at least one second guide component connected in between the bodies in perpendicular form and connected onto both side surfaces, a first driving component located on both side surface of the bridge or the inner surface of the body providing moving of the bridge, and a second driving component located on the body inner surface and providing movement of the first driving component on the inner surface of the body.

Described are a method and laser plotter for processing a job for cutting, engraving, marking and/or lettering a flat workpiece having at least one housing with a processing chamber formed for positioning a workpiece. The chamber has at least one irradiation source in the form of a laser and a control unit for controlling the sledge, which may be operated via a belt drive and has a focusing unit arranged movably thereon. Between the sledge and a processing surface of the processing chamber, an extraction bar is arranged for extracting the exhaust gases or vapors, respectively, produced by a laser beam during the processing of the workpiece. One or more extraction openings of the extraction bar are arranged or aligned, respectively, parallel to the processing surface for generating a horizontal extraction flow.

A processing system includes: a processing apparatus for processing an object; a rotation apparatus for rotating a holding part holding the object; a movement apparatus for moving at least one of the processing apparatus and the holding part; a measurement apparatus for measuring at least a part of the object held by the holding part; and a control apparatus for controlling the movement apparatus and the rotation apparatus based on a measured result by the measurement apparatus to rotate the holding part and to move at least one of the processing apparatus and the holding part