An apparatus and method for detecting edges or for seam tracking when machining workpieces by means of a laser beam, e.g. joining or cutting. The present invention provides an apparatus for seam tracking of the process in the laser material processing, comprising at least two separate illumination elements, each emitting differently polarized light and a polarization camera.

A method for trimming a bent tube along an actual cutting contour, wherein a virtual tolerance envelope is calculated for the tube and a laser beam cutting the actual cutting contour is guided along a desired cutting contour related to the tolerance envelope, wherein the actual cutting contour is produced as a projection of the desired cutting contour or the laser beam is guided along the corrected desired cutting contour, which then corresponds to the actual cutting contour.

A system that uses a scalable array of individually controllable laser beams that are generated by a fiber array system to process materials into an object. The adaptive control of individual beams may include beam power, focal spot width, centroid position, scanning orientation, amplitude and frequency, piston phase and polarization states of individual beams. Laser beam arrays may be arranged in a two dimensional cluster and configured to provide a pre-defined spatiotemporal laser power density distribution, or may be arranged linearly and configured to provide oscillating focal spots along a wide processing line. These systems may also have a set of material sensors that gather information on a material and environment immediately before, during, and immediately after processing, or a set of thermal management modules that pre-heat and post-heat material to control thermal gradient, or both.

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.

A plurality of values measured are relatively compared to determine an optical axis deviation direction in which an optical axis of a measurement beam S deviates from a laser beam L. In performing laser welding in the optical axis deviation direction, an irradiation position of the measurement beam S is changed so that the irradiation position of the measurement beam S is moved to a rear side of the center of the optical axis of the laser beam L in the welding direction.

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.

An evaluation apparatus includes an obtaining circuit, a detecting circuit, a generating circuit, and an evaluating circuit. The obtaining circuit is configured to obtain track information indicating positions of a laser target spot in relation to time. The laser target spot is made by a laser beam on a workpiece for welding. The detecting circuit is configured to detect intensity information indicating intensities of return light in relation to time. The return light is generated by radiating the laser beam onto the workpiece. The generating circuit is configured to generate intensity distribution information indicating the intensities corresponding to the positions by correlating the track information and the intensity information based on time. The evaluating circuit is configured to evaluate a welding state of the welding based on the intensity distribution information.

A laser welding head with movable mirrors may be used to perform welding operations, for example, with wobble patterns and/or seam finding/tracking and following. The movable mirrors provide a wobbling movement of one or more beams within a relatively small field of view, for example, defined by a scan angle of 1-2. The movable mirrors may be galvanometer mirrors that are controllable by a control system including a galvo controller. The laser welding head may also include a diffractive optical element to shape the beam or beams being moved. The control system may also be used to control the fiber laser, for example, in response to the position of the beams relative to the workpiece and/or a sensed condition in the welding head such as a thermal condition proximate one of the mirrors.

A laser welding head with movable mirrors may be used to perform welding operations, for example, with wobble patterns and/or seam finding/tracking and following. The movable mirrors provide a wobbling movement of one or more beams within a relatively small field of view, for example, defined by a scan angle of 1-2. The movable mirrors may be galvanometer mirrors that are controllable by a control system including a galvo controller. The laser welding head may also include a diffractive optical element to shape the beam or beams being moved. The control system may also be used to control the fiber laser, for example, in response to the position of the beams relative to the workpiece and/or a sensed condition in the welding head such as a thermal condition proximate one of the mirrors.

A laser welding head with movable mirrors may be used to perform welding operations, for example, with wobble patterns and/or seam finding/tracking and following. The movable mirrors provide a wobbling movement of one or more beams within a relatively small field of view, for example, defined by a scan angle of 1-2. The movable mirrors may be galvanometer mirrors that are controllable by a control system including a galvo controller. The laser welding head may also include a diffractive optical element to shape the beam or beams being moved. The control system may also be used to control the fiber laser, for example, in response to the position of the beams relative to the workpiece and/or a sensed condition in the welding head such as a thermal condition proximate one of the mirrors.