Systems and methods of the present disclosure relate generally to facilitate performing a task on a surface such as woodworking or printing. More specifically, in some embodiments, the present disclosure relates to mapping the surface of the material and determining the precise location of a tool in reference to the surface of a material. Some embodiments relate to obtaining and relating a design with the map of the material or displaying the current position of the tool on a display device. In some embodiments, the present disclosure facilitates adjusting, moving or auto-correcting the tool along a predetermined path such as, e.g., a cutting or drawing path. In some embodiments, the reference location may correspond to a design or plan obtained from obtained via an online design store

The invention relates to a method (100) for cutting cut parts (1, 2, 3, 4, 5, 6; 12, 13, 14, 15, 16, 17, 18), wherein the cut parts (1, 2, 3, 4, 5, 6; 12, 13, 14, 15, 16, 17, 18) produce a cutting pattern (7), said method having the following method step: cutting (106) the cut parts (1, 2, 3, 4, 5, 6; 12, 13, 14, 15, 16, 17, 18), wherein the cut parts (1, 2, 3, 4, 5, 6; 12, 13, 14, 15, 16, 17, 18) are arranged in a rectangular, repeating portion (9, 9) of an endless single ply material web (19), wherein the portion (9) at least one cut part (1, 2, 3, 4, 5, 6; 12, 13, 14, 15, 16, 17, 18) or at least one cutting pattern (7) is contained in part (10, 11). The method additionally comprises a computer program product and a device for cutting by means of a cutting tool.

A cutting device includes a placement member on which an object to be cut is placed and a mounting portion to which a cutting blade is mounted. The cutting device detects, in the course of the mounting portion moving, a pressure correspondence value corresponding to a pressure applied to the mounting portion, and a movement amount of the mounting portion, decides a cutting pressure correspondence value that is the pressure correspondence value corresponding to a cutting pressure, on the basis of the pressure correspondence value and the movement amount after the cutting blade has come into contact with the object to be cut, and acquires cutting data. The cutting device further applies in accordance with the acquired cutting data, the cutting pressure corresponding to the decided cutting pressure correspondence value to the mounting portion, and cuts the object to be cut, using the cutting blade mounted to the mounting portion.

Systems and methods are described for managing articles. The systems and methods described herein may comprise an example method for manufacturing an article. The systems and methods provides an end-to-end manufacturing value chain as a closed system and feedback loop.

Disclosed herein is a planning and impositioning technique for industrial printing orders that evaluates and ranks potential planning and impositioning schemes for a given print order based on available printing apparatus, media, and die-cutter specifications. The printing schemes make use non-die cutter operations to subdivide a media sheet, followed by a series of die-cutter operations each subdivision to take advantage of industrial printer efficiency. This printing operation is enabled by planning and impositioning phases that generate print instructions allows a change in media size from printer apparatus to dies. Specifically, during the planning phase of the print order, a printer apparatus and a die or set of dies are selected where the media size used by the printer apparatus is larger than the die(s) is/are designed for.

A method and system are provided for automatically portioning workpieces, such as food products, by simulating portioning the workpieces in accordance with the one or more desired shapes of the final piece(s) as a directly controlled physical characteristic (parameter/specification) as well as one or more resulting indirectly controlled physical characteristics (parameters/specifications). The desired shape(s) of the final piece(s) are defined by a plurality of manipulatable reference coordinates. A workpiece is scanned to obtain scanning information, then portioning of the workpiece is simulated in accordance with the desired shape(s) of the final piece(s) defined by the directly controlled reference coordinates, thereby to determine the one or more indirectly controlled physical characteristics of the one or more final pieces to be portioned from the workpiece. The simulated portioning of the workpiece is performed for multiple combinations of directly controlled shapes as defined by the modified or edited reference coordinates and indirectly controlled physical characteristics until an acceptable set of a directly controlled shape and resulting one or more indirectly controlled physical characteristics is determined.

A galvanometric laser for cutting and/or etching textile embellishments such as transfers or applique's and a method of operation thereof that is capable of visually capturing an incoming graphic image and referencing a cut pattern to the captured image and dynamically adjusting the cut pattern during cutting, etching and/or application of energy from the laser to thereby compensate for distortions in the fabric. The device includes a conveyor with an imaging station at which the graphic product is indexed under a high-resolution static camera with color recognition capability for the purposes of image capture. A high intensity bottoms-up light source resident at the imaging station provides ample illumination regardless of whether the design elements are face up toward the camera or face down toward the light source, or a combination of both. The system includes a computer at which the captured product image is analyzed, and the analytics are used to adjust the input cut file specifying the location and power settings for laser application. The product is then advanced in a controlled manner by means of the conveyor into a galvanometric cutting station where laser energy is applied. After completion the product is advanced out of the galvanometric cutting station for packaging.

A cutting device includes a platen, a mounting portion, a first movement mechanism, a second movement mechanism, a detector, a processor, and a memory. The memory is configured to store computer-readable instructions that, when executed by the processor, instruct the processor to perform processes. The processes include acquiring cutting data, acquiring a contact position output by the detector when the cutting blade comes into contact with the holding member, and controlling the first movement mechanism in accordance with the cutting data to move the mounting portion and the holding member to a cutting start position. The processes include controlling the second movement mechanism, at the cutting start position, to move the mounting portion in the third direction to a cutting position set on the basis of the contact position, and controlling the first movement mechanism in accordance with the acquired cutting data to perform cutting processing.

A cutting machine having a table with a working surface is disclosed. The working surface including a crossbeam above the working surface configured to be linearly positioned parallel to a first horizontal axis, a module, mounted on the crossbeam configure to be positioned parallel to a second horizontal axis, which extends perpendicularly to the first horizontal axis, a tool holder mounted in the module configured to move in a vertical axis and rotate about the vertical axis, and to accept one of a plurality of different interchangeable tools, and a control unit, wherein the tool holder has a connection device designed to supply the tool with power and a fluid, wherein the supply with the fluid is provided via a rotary joint, and wherein the power is provide via a rotary transmitter.

The present disclosure relates to an Artificial Intelligence (AI) enabled smart facial hair grooming device designed to groom, design, or shave facial hair automatically. Aspects of the present disclosure relate to a grooming device 100 capable of grooming, designing or shaving facial hair of a user, the grooming device 100 including a face shield 102 configured with a plurality of razors 108 installed on at least one inner surface of the face shield 102, at least one micro-controller configured to control movement of the plurality of razors 108, and an Artificial Intelligence (AI) based pixel identifier (PI) module configured to visualize a desired facial hair style on face of the user and program the micro-controller with or without additional motors to move each of the plurality of razors 108 in a desired direction to allow cutting of facial hair of the user as per the desired facial hair style.