A machine for working a workpiece made of wood, plastic, glass, fiberglass, metal, ceramic, and the like including an entry station for the entrance of the workpiece to be worked and an exit station for the exit of the worked workpiece; a conveyor group for moving the workpiece to be worked, according to a forward direction, from the entry station towards the exit station; at least one working unit of the workpiece, arranged overhead with respect to the conveyor group including at least one working tool of the workpiece; the machine including a laser system configured for carrying out further working operations on the workpiece. Also disclosed is a laser system that can be installed on a machine for machining a workpiece and an operation method of a machine for machining a workpiece.

A method for verifying a marking (8), wherein compressed air is continually supplied to a needle piston (2), which oscillates in a needle head housing (7) of a marking head (1) and which has a needle (3) on one end, which inserts the marking (8) into a surface (4), pressure fluctuations are formed in a compressed air supply line (10) during the oscillation, compressed air is continually measured in the compressed air supply line (10), a pressure profile is created and is compared to a reference pressure profile stored in an evaluating unit (12) and is evaluated.

A groove engraving device and a groove engraving method are provided. The groove engraving device includes: a processing chamber for containing a piece to be processed, a cutter for groove engraving on the piece to be processed, a clamping mechanism for clamping the piece to be processed, a driving mechanism for driving the clamping mechanism to rotate, and a temperature controlling device for controlling a temperature inside the processing chamber to be within a preset temperature range. The clamping mechanism and the cutter are disposed inside the processing chamber, and the clamping mechanism is rotatable with respect to the processing chamber. The temperature controlling device is disposed inside the processing chamber. The groove engraving device can improve the processing efficiency and quality of the groove engraving on the piece to be processed.

Pantograph machine (1) equipped with cutting blades hot punches pre-shaped, and drills, for machining panels, in particular slabs and ICF panels, with foamed materials or extruded, comprising at least a first station (1) consisting of at-least a castle (1′), supported by a base (2) which houses a supporting surface (3), the castle (1′) comprising: at least one frame (5) carrying punches-cutting blades (6) connected operatively to a frame-carrier carriage (9) sliding on guides, and moved by means of a transmission; at least two slides (23) for milling, performed by a tool (24) mounted on an electro-spindle (25), place on a carriage (14); at least-one frame (15) carrying wires (16) operatively connected to a frame-carrier carriage (19) sliding on guides (10) and moved by means a transmission.

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 method of forming a non-optically detectable identifiable marking invisible to the naked eye is formed from plural recesses of multiple levels at an outer surface of an article formed from a solid-state material. The method includes forming plural recesses of multiple levels within a predetermined region of a photoresist applied to an outer surface of an article formed from a solid-state material. The plural recesses are formed by grayscale lithography and the recesses extend at least partially through the photoresist and towards the outer surface of the article formed from a solid-state material. The method also includes applying an etching process such that at least a portion of the outer surface of said article is exposed and etched to form plural etched portions extending into the article from its outer surface and corresponding to plural recesses; wherein said predetermined region of said photoresist defines an identifiable marking to be applied to the outer surface of said article; wherein said plurality of etched portions forms the non-optically identifiable marking on the outer surface of said article.

Provided are an automatic continuous image engraving device capable of decreasing in size of an installing space of the device. The device comprises an unengraved medium accommodating part, an engraved medium accommodating part, a medium dispenser, a medium positioning and conveying part, and an image engraving part, wherein the medium dispenser releases the unengraved card-shaped engraving medium to cause the same to be succeeded at the succeeding position, the medium positioning and conveying part returns the engraved card-shaped engraving medium after image engraving from the engraving position to the succeeding position, and the medium dispenser adsorbs the engraved card-shaped engraving medium at the succeeding position, moves the same upward, travels above the engraved medium accommodating part, and releases the engraved card-shaped engraving medium to be accommodated.

Provided are an automatic continuous image engraving device capable of decreasing in size of an installing space of the device. The device comprises an unengraved medium accommodating part, an engraved medium accommodating part, a medium dispenser, a medium positioning and conveying part, and an image engraving part, wherein the medium dispenser releases the unengraved card-shaped engraving medium to cause the same to be succeeded at the succeeding position, the medium positioning and conveying part returns the engraved card-shaped engraving medium after image engraving from the engraving position to the succeeding position, and the medium dispenser adsorbs the engraved card-shaped engraving medium at the succeeding position, moves the same upward, travels above the engraved medium accommodating part, and releases the engraved card-shaped engraving medium to be accommodated.

The present invention provides for a wall mountable system for automated drawing of an image upon a wall which includes a horizontal mounting track for mounting on a wall, a robot having a y-track rigidly mounted it where the robot and the mounted y-track travel along the horizontal track. An end effector, which includes a pen holding mechanism holding a pen, is in electrical communication with the robot and travels along the y-track of the robot. The present invention provides a system and device that can attach to a wall or vertical surface in a damage-free manner and draw fast any complexity or style image of custom size in both the horizontal (X) and vertical (Y) directions, that is easy to remove and transport and require small floor space to operate.

The present disclosure provides an identification code recognition system, including: a camera configured to capture an image of an entire area of an identification code (ID code) engraved on a workpiece; a scanner configured to scan a partial area including at least one misrecognized character in the entire area of the ID code; and an image analyzer including a memory and a processor, wherein the memory is configured to store the ID code, data related to the ID code, an image captured by the camera, and an image scanned by the scanner, and the processor is configured to analyze the image captured by the camera and the image scanned by the scanner based on an image analysis logic.