A method performed by a laser machine includes: before a laser-beam machining process, recording an influence of a change in a position of at least one movable laser machine component on a lateral position of a focal point of a laser beam in a focal plane or relative to a reference point, storing an association between the position of the movable laser machine component and the lateral position, and then, setting, based on the stored association, the focal point to a preset lateral position in the focal plane or relative to the reference point by setting the position of the movable laser machine component. The movable laser machine component can include at least one of at least one optical element in a beam path of the laser beam, a laser-beam machining head in a work area of a laser machine, or a movable part of the laser-beam machining head.

A universally usable device for producing a predetermined breaking line in an equipment part of a vehicle. The device includes a laser beam generator, a laser scanner and a linear or matrix-shaped first sensor arrangement with first individual sensors of an identical first sensitivity and at least one identical linear or matrix-shaped second sensor arrangement of second individual sensor, which is arranged with an offset to the first sensor arrangement of first individual sensors, and the second individual sensors have an identical second sensitivity which differs from the first sensitivity.

A laser irradiation apparatus includes: a laser generation apparatus configured to generate first laser light for performing heat treatment of an object to be processed; a measurement-laser emission unit configured to emit linearly-polarized second laser light toward an irradiation area on the object to be processed to which the first laser light is applied; a first polarizing plate configured to let, of the whole reflected light of the second laser light reflected by the object to be processed, a part of the reflected light that has a first polarization direction pass therethrough; and a measurement-laser detection unit configured to detect the reflected light that has passed through the first polarizing plate.

The present disclosure relates to a beam analysis device for determining a light beam state, e.g., determining the focal position of a light beam, where the device has a partial beam imaging device having at least one first selection device for forming a first partial beam from a first partial aperture region of the first measurement beam, and an imaging device for imaging the first partial beam for generating a first beam spot onto a detector unit having a spatially-resolving detector. The beam analysis device also can have an evaluation unit for processing the signals of the detector unit, for determining a lateral position (a.sub.1) of the first beam spot, and for determining changes in the lateral position (a.sub.1, a.sub.1′) of the first beam spot over time. An optical system for focal position control with a laser optics and with a beam analysis device. Additionally, the disclosure relates to a corresponding beam analysis method and methods for focal position control of a laser optics and for focal position tracking of a laser optics.

Provided is a laser scattered light measuring device capable of easily confirming the safety of laser scattered light to a human body. The laser scattered light measuring device includes a light receiving unit, a calculation unit, and a display unit. The light receiving unit receives laser scattered light generated by irradiating an object with laser light and detects intensity of the laser scattered light. The calculation unit compares the intensity of the laser scattered light received by the light receiving unit with a predetermined threshold value and calculates a degree of risk of the laser scattered light to a human body based on a comparison result. The display unit displays the degree of risk calculated by the calculation unit.

A laser processing apparatus includes a laser oscillator configured to emit a laser beam, a slit configured to narrow a width of the laser beam emitted from the laser oscillator to a width corresponding to a dividing groove to form the dividing groove of a predetermined width, a slit moving mechanism configured to move the slit in a direction corresponding to a width direction of the dividing groove, and an adjusting unit configured to make the center of the slit and the cross-sectional center of the laser beam entering the slit coincide with each other in a direction in which the slit moving mechanism moves the slit.

A laser machining device includes a laser light source, a spatial light modulator which includes a display unit, an objective lens, an image-transfer optical system, a camera and a controller. The controller executes first display processing and second display processing. According to first display processing, when the camera captures the image, the display unit displays a first phase pattern for adjusting a condensing position of laser light condensed by the objective lens to a first condensing position. According to second display processing, when the camera captures the image, the display unit displays a second phase pattern for adjusting the condensing position of the laser light condensed by the objective lens to a second condensing position different from the first condensing position in an irradiation direction of the laser light.

An apparatus calibrates a laser processing machine and includes an imaging sensor and a controller. The controller directs output of a beam from the machine’s low power pointer laser and directs an actuator at measurement conditions. Images of the beam are obtained by an imaging sensor, and the controller measures a parameter of at least one of the machine’s optical components. The controller then outputs an indication of the machine indicative of the measured parameter. For example, the controller can calculate a focus position of the beam from the laser head so the Z-position of the laser head can be adjusted for any discrepancies. In other examples, the controller can determine an offset of the fiber tip of the head so adjustments to operations can be made, or the controller can determine centering of the beam in the head’s nozzle so adjustments can be made.

Additive manufacturing can include use of a laser-machining technique. Laser machining can be used to form cavities, trenches, or other features in an additively-manufactured structure. Spectroscopy can be performed to monitor a laser machining operation. For example, a laser-enhanced additive manufacturing process flow can include depositing a conductive layer on a surface of a dielectric layer, and conductively isolating a first region from a second region of the conductive layer using ablative optical energy, including applying ablative optical energy to the conductive layer, monitoring a spectrum of an ablative plume generated by applying the ablative optical energy, and controlling the ablative optical energy in response to a characteristic of the spectrum of the ablative plume.

An invention for 2D and/or 3D scanning devices. The invention discloses a method and an apparatus for precise control and regulation of laser processing in order to provide a desired energy density delivered by the scanner across the work surface for printing and/or sensing applications.