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.

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

According to various examples, an assembly can include a backing. The assembly can also include a polymeric surfacing film adhered to the backing, the polymeric surfacing film. The polymeric surfacing film can include a first geometric shape. The polymeric surfacing film includes a continuous first cut defining the geometric shape and a continuous second cut spaced apart from and substantially congruent with the continuous first cut in at least one of an x and y direction. A portion of the polymeric surfacing film, located between the first cut and the second cut, is removable from the backing. According to some examples, the assembly can provide certain benefits over state of the art assemblies. For example, according to some examples, providing the first and second cut can make removal of at least the first geometric shape to be quicker and easier, which can result in significant savings in time and wasted materials.

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 method for realising articles having a predetermined area and aesthetic appearance, which includes using frames (1A, 1B, 1C) to each of which a portion (P1, P2, P3) of material having a prevalent flat extension can be removably hooked, comprising, in order, following steps: hooking a first portion (P1) of the material to a first frame (1A); carrying out, on the first portion (P1) hooked to the first frame, punching (G1) and stitching (G2) operations; carrying out, on the first portion (P1) hooked to the first frame (1A), cutting operations (G3) for defining a corresponding article (A) having predetermined area and aesthetic appearance defined by the combination of the profile of the article and by the mutual arrangement of the punching (G1) and the stitching (G2); releasing the article (A), and relative scrap (Z),from the first frame (1A).

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 punching/perforation machine for creating a punching/perforation pattern in a material unit/web comprises a punching/perforation tool that includes an upper tool part which can be moved in a direction of stroke and which includes a plurality of punching dies/perforation needles arranged in a predefined grid in a transverse direction. It can be moved by a pressure beam that is operatively connected to a drive unit via a control device in order to produce a punching/perforation stroke. The material unit/web being supplied between the upper tool part and a stationary lower tool part/female die. Means are provided for generating a simultaneous movement of the material unit/web relative to the punching/perforation tool by a predefinable distance both in the direction of travel and in the transverse direction such that the material unit/web can be placed in a different predefinable position relative to the punching/perforation tool prior to each punching/perforation stroke.

Disclosed are modularized garment manufacturing method and system for small quantity batch production of garments. Basic components constituting an ordered garment are generated by analyzing shape graphic data of the ordered garment. For each basic component, basic patterns are generated for each dimension of the ordered garment. The basic patterns are compared with reference garment patterns stored in a garment pattern database to determine a pattern category of each basic pattern. Based on the pattern category of the basic patterns and information on garment production lines currently in operation, subdivided work modules are determined for each basic pattern. A configuration of modular sewing process lines, which include module processing lines for manufacturing the working modules and component-joining process lines for completing production of the ordered garment by joining the basic pattern products produced in each module processing line, is designed based on operation information of a garment production line.

First scanned images of the first container are received from a scanning device that show the contents of the interior of the first container before the first container is cut and opened. Second scanned images that are of the contents of the first container after the first container is cut and opened are also received. The images are analyzed and, based upon the analysis, selective modifications to the operating parameters of the container opening machine are determined and made.