Various approaches for forming holes onto a sheet-metal assembly are described. In one implementation, a sheet-metal assembly is received through a conveyor system within a manufacturing cell. Once received, the type of sheet-metal assembly is identified based on associated information. Corresponding to the identified sheet-metal assembly, a set of position coordinates corresponding to one or more points on the sheet-metal assembly are obtained. Subsequently, a work-performing apparatus may be used for forming holes onto the sheet-metal assembly, at one or more points on the sheet-metal assembly.

A machine for forming packing templates includes a infeed system that can feed multiple feeds of sheet material into the machine without repositioning the infeed system or forming creases or bends in the sheet material. The machine also includes a separation and cutting systems with one or more cutting tables and biased knives that cut the sheet material packaging templates. The machine also includes creasing roller(s) that forms creases in the sheet material. The machine also includes a system for reducing or eliminating the impact of irregularities in the sheet material.

A computer-implemented method for optical element fabrication with optical scanner feedback includes initiating the optical scanner to obtain an optical measurement of an optical layer of a multi-layer film. A rotational orientation for an optical element that is to be cut from the multi-layer film is then determined based on the optical measurement. The method also includes initiating a cutting instrument to cut the optical element from the multi-layer film at the rotational orientation.

Aspects of automated fabric picking are described. In one embodiment, a system includes a textile cutter including a tabletop upon which textile panels can be cut out from a textile sheet, a textile panel picker, and a computing device. The textile panel picker includes a flexible transport tube, a transport tube transfer arm to position the flexible transport tube over the tabletop and the textile panels, a textile hopper to collect the textile panels, and a pneumatic pump assembly to evacuate air from the textile hopper and through the flexible transport tube. The computing device identifies and tracks the textile panels on the tabletop, directs the transport tube transfer arm to position the flexible transport tube over the textile panels, and directs the pneumatic pump assembly to generate suction to pull the textile panels through the flexible transport tube and into the textile hopper.

A post-processing apparatus includes: a moving mechanism configured to move a punching apparatus in a width direction orthogonal to a transportation direction of a sheet; and a sensor configured to optically detect a mark formed on the sheet and indicating a position to be punched. The mark is configured such that an interval in the transportation direction between a plurality of feature portions extending in the width direction is configured to be changed depending on the width direction. The moving mechanism is configured to determine a position of the punching apparatus in the width direction based on a difference between respective timings of detection of the plurality of feature portions.

In order to achieve high product quality and process reliability in a process for manufacturing an endless profile strand of soft plastic and/or rubber material fed to a supply storage for a sealing profile, edge protection profile or the like on a motor vehicle, it is provided that the manufacturing process be divided into two process sections which are carried out on two manufacturing lines that can be operated independently of one another.

A method of processing poultry portions determines at a control unit a target weight of a cut poultry portion; inspects a poultry portion using an inspection unit to determine a mass distribution of said poultry portion and providing said mass distribution to the control unit; calculates a cutting plan of the poultry portion based on the target weight and the mass distribution using the control unit; uses a mechanical gripper so as to grip the poultry portion and arrange said poultry portion for execution of the cutting plan; and cuts the poultry portion using a cutting unit in accordance with the cutting plan so as to produce a cut poultry portion in accordance with the target weight. A system for processing poultry portions is configured to perform the foregoing method, among others.

A processing apparatus includes a cutting blade mounted on a spindle, the cutting blade having a cutting edge for cutting a workpiece held on a holding table, a measuring portion for measuring an edge projection amount of the cutting edge at a predetermined frequency, and a data processing portion. The data processing portion includes a lower limit recording portion for recording a lower limit of the edge projection amount of the cutting edge as an allowable limit for use of the cutting blade, a storing portion for storing blade information including the edge projection amount measured by the measuring portion and a cutting distance traveled by the cutting blade at the time of measurement of the edge projection amount.

A digital flatbed cutter is described. The cutter includes a flatbed on which a workpiece can be positioned. A head unit is movable in a plane above the flatbed. A tape applicator head and a cutter head are mounted to the head unit. The tape applicator head includes an applicator roller for applying a strip of tape to the workpiece that is rotatable about an axis that is normal to the plane so that strips of tape can be applied to the workpiece in any direction. The cutter head includes a knife or blade for cutting the workpiece. A creaser head that includes a creaser wheel for creasing the workpiece can also be mounted to the head unit.

A processing apparatus includes a chuck table, a first and second image capturing units, a display device, and a controller. The first image capturing unit obtains a first image group of images captured of a processed groove in the workpiece at different positions along a thicknesswise direction, each including a piece of first image information representing a shape of the processed groove. The second image capturing unit obtains a second image group of images captured of the processed groove at different positions along the thicknesswise direction of the workpiece, each including a piece of second image information representing a shape of the processed groove. The controller orders the pieces of at least either the first or the second image information into a sequence along the thicknesswise direction, thereby generating a three-dimensional image of the processed groove, and displays the three-dimensional image on the display device.