A label modification unit may receive a label modification input that indicates a label modification associated with content being written to a label or erased from the label. The label modification unit may identify an area of the label that is associated with the label modification according to the label modification input. The label modification unit may determine, based on a size of the area, a spot size of a light beam that is configured to be emitted by a laser printhead to modify the content within the area. The label modification unit may determine, based on the spot size and the content, an optical path configuration for the laser printhead. The label modification unit may operate the laser printhead according to the optical path configuration to write the content to the area or erase the content from the area.

A label modification unit may receive a label modification input associated with an image. The label modification unit may process, using an image filtering, the label modification input to convert the image to a bitmap for raster printing the image via a laser printhead. The label modification unit may determine, based on the bitmap, an array of power factors for a light beam that is configured to be emitted by a laser of the laser printhead and raster print the image. The label modification unit may control the laser of the laser printhead in association with raster printing the image on a rewriteable label according to the array of power factors.

Provided is an articulated robot arm capable of laser printing. The articulated robot arm includes: a communicator for receiving beverage order information; a grip part gripping and moving a cup; an articulation part having one side coupled to the grip part and including a plurality of articulation units; a controller controlling operations of the grip part and the articulation part; and a laser beam irradiation unit provided on at least a partial area of the grip part and irradiating a laser beam to print the beverage order information on the cup.

Provided is an articulated robot arm capable of laser printing. The articulated robot arm includes: a communicator for receiving beverage order information; a grip part gripping and moving a cup; an articulation part having one side coupled to the grip part and including a plurality of articulation units; a controller controlling operations of the grip part and the articulation part; and a laser beam irradiation unit provided on at least a partial area of the grip part and irradiating a laser beam to print the beverage order information on the cup.

A process for producing, under a lenticular grating, in an etching zone, by laser etching, using a tool, a first image and at least one second image that may be selectively viewed by varying angle of observation, the tool including a laser, a galvanometric head and a lens, and defining an optical axis and a working zone, which includes steps of: placing the etching zone in a first location included in the working zone and on the periphery of the working zone, and, perpendicularly to the optical axis, etching the first image; and then placing the etching zone in a second location, which is different from the first location, included in the working zone and on the periphery of the working zone, and, perpendicularly to the optical axis, etching the second image.

There is described a metal workpiece generally having a surface and an identifier marked on said surface. The identifier has cells each having a corresponding cell size, including bright cells corresponding to a first binary value and dark cells corresponding to a second binary value different from the first binary value. The dark cells include a center portion being recessed relative to the surface thereby leaving a recess bounded by a peripheral wall in the corresponding dark cell, the recess having a depth of at least 100 microns and having an opening with a width ranging between 400 microns and 1750 microns and representing between 30 percent and 99 percent of the corresponding cell size such that the corresponding dark cell appears dark to an optical reader. The depth, the width and the cell size of the dark cells provide a shot blast resistance to the laser-marked identifier.

Embodiments are directed to laser-based processes for forming features on the surface of a part. The feature may include a geometric element, a color element, and/or a surface finish element. In some cases, the laser-formed features are formed as a pattern of textured features that produce an aesthetic and/or tactile effect on the surface of the part. In some cases, the texture features may be sufficiently small that they may not be discerned by the unaided human eye. Also, in some cases, a multiple laser-based processes are combined to form a single feature or a finished part having a specific aesthetic and/or tactile effect.

A marked article includes a substrate including a first surface and a surface material, a raised pad on the first surface, the raised pad including a second surface, and a design on the raised pad. The raised pad is formed on the first surface using a material addition process to prevent mechanical stress from being propagated from the raised pad to the substrate in response to the design being formed on the raised pad.

A laser engraver having a laser, a camera, and a plate for holding a product, wherein an optical path of the laser is directed to the plate, an optical path of the camera is directed to the plate, and the optical path of the camera to the plate and the optical path of the laser to the plate are at least partially the same before and when hitting the plate. The laser engraver includes a controller and a comparator, wherein the controller is configured to have the laser engrave a predefined pattern at a predefined position on the product on the plate to form an engraved pattern on the product and have the camera capture a position of the engraved pattern, have the comparator compare the predefined position and the position captured by the camera to determine a difference therebetween, and use the difference to calibrate the laser.

A laser recording method is for processing a recording object with laser light emitted from a laser light source. The laser recording method includes: detecting a moving speed of the recording object with a location of the laser light source when the laser light source emits laser light, as an observation point, while moving at least one of the recording object and the laser light source; and correcting power output of the laser light set such that an amount of energy applied by the laser light per unit area of the recording object is constant even if the moving speed is changed, to compensate energy loss derived from thermal diffusion occurring on the recording object based on the moving speed detected at the detecting.