Abstract: Disclosed are a laser marking equipment and system. The equipment includes: a laser marking machine and a control platform. The laser marking machine is controlled by the control platform, the laser marking machine includes: a laser device and a galvanometer, the galvanometer being configured to move at a predetermined moving speed; and the laser device being configured to output laser; the laser marking equipment further includes: a first obtaining module obtaining coordinate and a gray scale value of the target image pixel dot; a first calculation module calculating output power of the target image pixel dot; a second obtaining module obtaining the material information to be marked; a third obtaining module obtaining corresponding material output power; a secondary calculation module calculating an amended output power; and a control module controlling the laser device to output laser specific to each target image pixel dot.

Abstract: The embodiments of the disclosure provide a correction method for laser marking, comprising: obtaining an image to be marked; in a preset coordinate system of a laser marker, determining a fracture region and a non-fracture region of the image to be marked; correcting the non-fracture region of the image to be marked by using a preset correcting formula; correcting the fracture region of the image to be marked by using a preset standard correction value and a preset weighted coefficient corresponding to coordinate position; and marking with the corrected image to be marked. According to the disclosure, by providing weighted correction for the mark points within the fracture region according to finely divided coordinate positions, the distortion correction for the fracture region can be completed without measuring deviation values of marking region with high density and high precision.

Abstract: Disclosed a laser marking machine, method, equipment and system. The method comprises steps of: the control main board receiving coordinate and gray scale value of the target image pixel dot; calculating output power of the target image pixel dot by using the gray scale value; and controlling the laser device to use corresponding output power according to displacement of the galvanometer, and outputting laser specific to each target image pixel dot. By adjusting the output power of target image pixel dot (marking point), a separate pixel dot may reflect the change of gray scale value, so as to represent the image gray scale value. The coordinate of each pixel dot in the gray scale image may be calculated according to the predetermined resolution, such that, the coordinate of pixel dot is no longer adjusted, ensuring the DPI and the resolution of the gray scale image.

Abstract: The present disclosure discloses a fiber laser, including a laser seed source, an amplifying optical path, an output optical isolator and an optical fiber cylinder; wherein, the amplifying optical path is connected to the laser seed source and the output optical isolator, the laser seed source is used to output optical source, the amplifying optical path includes a first stage amplifying optical path and a second stage amplifying optical path, the first stage amplifying optical path is connected to the laser seed source and the second stage amplifying optical path respectively, the output optical source is output via the output optical isolator after two-stage amplifying; the second stage amplifying optical path comprises a multi-mode active optical fiber; the multi-mode active optical fiber is coiled on the optical fiber cylinder. By the disposing way above, the present disclosure may improve output optical beam quality of the fiber laser.

Abstract: The present disclosure discloses a fiber laser, including a laser seed source, an amplifying optical path, an output optical isolator and an optical fiber cylinder; wherein, the amplifying optical path is connected to the laser seed source and the output optical isolator, the laser seed source is used to output optical source, the amplifying optical path includes a first stage amplifying optical path and a second stage amplifying optical path, the first stage amplifying optical path is connected to the laser seed source and the second stage amplifying optical path respectively, the output optical source is output via the output optical isolator after two-stage amplifying; the second stage amplifying optical path comprises a multi-mode active optical fiber; the multi-mode active optical fiber is coiled on the optical fiber cylinder. By the disposing way above, the present disclosure may improve output optical beam quality of the fiber laser.

Abstract: The embodiments of the disclosure provide a correction method for laser marking, comprising: obtaining an image to be marked; in a preset coordinate system of a laser marker, determining a fracture region and a non-fracture region of the image to be marked; correcting the non-fracture region of the image to be marked by using a preset correcting formula; correcting the fracture region of the image to be marked by using a preset standard correction value and a preset weighted coefficient corresponding to coordinate position; and marking with the corrected image to be marked. According to the disclosure, by providing weighted correction for the mark points within the fracture region according to finely divided coordinate positions, the distortion correction for the fracture region can be completed without measuring deviation values of marking region with high density and high precision.

Abstract: The embodiment of the application discloses an optical isolator, comprising an isolator main component and a magnetic field adjusting module, wherein the center of the isolator main component is provided with a central through hole; the isolator main component includes: at least a group of magnet array, a Faraday optical rotation component and a magnetic field adjusting screw disposed in the central through hole; the magnet array is disposed around the central through hole, the magnetic field adjusting module includes: a magnetic field adjusting electric motor; the magnetic field adjusting screw is connected to the magnetic field adjusting electric motor and the magnet army, respectively, the magnetic field adjusting electric motor is configured to adjust magnetic field strength applied to the Faraday optical rotation component from the magnet array by changing the displacement of the magnetic field adjusting screw.

Abstract: Disclosed a laser marking machine, method, equipment and system. The method comprises steps of the control main board receiving coordinate and gray scale value of the target image pixel dot; calculating output power of the target image pixel dot by using the gray scale value; and controlling the laser device to use corresponding output power according to displacement of the galvanometer, and outputting laser specific to each target image pixel dot. By adjusting the output power of target image pixel dot (marking point), a separate pixel dot may reflect the change of gray scale value, so as to represent the image gray scale value. The coordinate of each pixel dot in the gray scale image may be calculated according to the predetermined resolution, such that, the coordinate of pixel dot is no longer adjusted, ensuring the DPI and the resolution of the gray scale image.