A processing data generation device includes 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 processing of acquiring a pattern represented by a contour, division processing of dividing the pattern into a plurality of pattern pieces, and offset setting processing of setting an offset line disposed at a position separated to an outside, from an adjacent portion, by a predetermined distance. The processes include processing line setting processing of setting, for each of the plurality of pattern pieces, a processing line including the offset line and surrounding a pattern piece and processing line processing of generating processing line processing data, for each of the plurality of pattern pieces, for processing a sheet-shaped workpiece along the processing line, using a processing device configured to perform processing on the workpiece.

A cutting machine for cutting a flat surface having a graphical design with optical registration features is disclosed. The cutting machine includes a working surface for receiving at least one object, a first camera unit arranged so that the field of vision encompasses the whole working surface, a working group above the working surface, and at least one cutting device for cutting the at least one object. A computing unit with a circuit and program code for controlling the cutting machine includes a storage unit, a circuit and program code for evaluating images of the first camera unit to identify registration features of the at least one object in an image of the first camera unit, and being designed to define a cutting path for the cutting device according to at least one stored instruction and based on positions of the registration features in the image.

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.

Systems and methods for producing printed goods from textile material to address shortcoming of existing approaches for article production. According to the systems and methods described herein, the harvested and woven cotton may be shipped directly to garment decorators who may perform all remaining steps to provide customers with finished goods. As such, the systems and methods herein may eliminate the steps of the blank goods trade and current manufacturing processes.

A cutting support apparatus includes an input unit that receives shoe last data, a storage in which a shape and a type of a plurality of plate-like parts are stored, a processor that generates a cutting pattern for cutting the plurality of plate-like parts from a plate-like member having a predetermined size based on the shoe last data and the shape of the plurality of plate-like parts, and an output unit that outputs the cutting pattern. The processor divides an area of the plate-like parts to be arranged in the plate-like member into a plurality of areas in accordance with the type of the plate-like parts that form the shoe last, determines positions of the plurality of plate-like parts to be arranged in each of the areas based on an arrangement condition, and generates the cutting pattern.

A method and system for automatic cutting of defective parts in a fabric with a pattern repeating at a certain pitch, includes the steps of producing a theoretical layout of parts to be cut on a theoretical representation of the fabric whilst respecting layout constraints, spreading out at least one layer of fabric on a cutting table, checking at least one portion of the spread-out fabric to ascertain actual features, modifying the theoretical layout in order to generate an actual layout taking into account the actual features of the fabric, identifying in the actual layout, defective parts which will contain defects once cut in the fabric and which will need to be cut again, and automatically allocating each defective part to a new theoretical layout by adjusting the layout constraints associated with the defective parts according to the actual layout.

Method for producing composite components having an undevelopable surface. To be able to maintain the tolerances when manufacturing especially large components in the case of composite components with undevelopable surfaces, it is proposed according to the invention to drape a cut-to-size blank on a molding tool and to determine the deviation of the cut-to-size blank edge from the setpoint cut-to-size edge. Then, on the basis of the deviation, a new cut-to-size blank edge is calculated, and a new cut-to-size blank is created and re-draped for examination purposes. The method is repeated until the deviations are below a tolerable threshold value. The method is furthermore carried out for each textile ply of the composite component.

A method and system are provided for automatically detecting characteristic points of a herringbone fabric with a view to automatically cutting pieces. The herringbone patterns are formed by V-shaped features with vertices that are aligned along a plurality of parallel axes. The method proceeds with a step of acquiring an image of a segment of the fabric, a detection initialization step including, on the basis of predefined parameters or on the basis of the image, acquiring geometric parameters of the herringbone patterns and defining lines of operation perpendicular to the axes of the herringbone patterns, and a step of determining, in the image, coordinates of points of passage of axes of the herringbone patterns along lines of operation via the optimization of a criterion of symmetry of two mirror sub-images acquired along lines of operation.

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.

A cut data generating device includes a control device which causes the generating device to acquire data indicating a pattern, to extract outlines of plural subpatterns contained in a design, to determine the number of layers associated with the number of sheets with respect to the extracted outlines, and to determine a sequence for stacking plural layers. The control device further causes the generating device to generate an integrated outline obtained by integrating the outline of first and second subpatterns contained in the extracted outlines, to specify the outline of the first subpattern on a first layer, to generate cut data for cutting the outline of the first subpattern from a first sheet associated with the first layer and for cutting the integrated outline from a second sheet associated with the second layer, and to output the generated cut data via the communication unit to the cutting apparatus.