A processing apparatus includes an articulated robot having an arm distal-end portion to which a processing tool configured with a cutting edge portion and a profiling portion and a shape measurement unit are attached, and a processor. The processor, in a workpiece set state, recognizes, by measuring a shape of the workpiece using the shape measurement unit, a tilt of a profiled surface portion of the workpiece and a position of a process portion of the workpiece to generate processing-target-portion information based on the position of the process portion, generates processing-point information indicating a processing point, moves the arm distal-end portion to the processing point based on the processing-point information, controls an orientation of the processing tool in accordance with the tilt of the profiled surface portion of the workpiece to perform the specified processing on the workpiece using the processing tool.

A food product slicer includes a base, a knife mounted for rotation relative to the base, a carriage assembly mounted to the base for reciprocal movement back and forth past a cutting edge of the knife, and an adjustable gauge plate mounted for movement between a closed position that prevents slicing and multiple open positions that permit slicing at respective thicknesses. A slice thickness identification system includes: at least one sensor for determining a position of the gauge plate; and a display for displaying a slice thickness indicator corresponding to the determined position.

The technology as disclosed herein includes a method and apparatus for deboning a meat item, and more particular for deboning a poultry item including performing an initial shoulder cut for removing boneless breast meat from the poultry carcass or frame. The method and apparatus disclosed and claimed herein is a combination of a robotic arm including an ultrasonic knife implement and a vision system for varying the cut path based on the shape and size of the poultry item. The combination as claimed including the ultrasonic knife can perform a meat cut while penetrating the meat with less force than the typical penetration that occurs when using a traditional knife.

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 slitter device includes an upper rotary shaft and a lower rotary shaft that are supported so as to be able to rotate. An upper slitter head that is supported by the upper rotary shaft so as to be able to rotate therewith. A lower slitter head that is supported by the lower rotary shaft so as to be able to rotate therewith and that is disposed on one side of the upper slitter head in the axial direction of the lower rotary shaft. An upper movement device that can move the upper slitter head in the axial direction of the upper rotary shaft. A lower movement device can move the lower slitter head in the axial direction of the lower rotary shaft. A control device that controls movement of the upper movement device and the lower movement device.

Electrode and electrode assembly manufacturing apparatuses include an electrode transfer unit for transferring an electrode with electrode coating layer on surface of the electrode, a cutter for cutting the electrode transferred by the electrode transfer unit to form a unit electrode, a separator transfer unit disposed at one surface of the electrode transfer unit and configured to transfer a separator, a sensor unit for sensing the position of the unit electrode and an alignment unit for adjusting transfer speeds of outer peripheries of the unit electrode parallel to a unit electrode transfer direction to adjust the interval between unit electrodes seated on a separator surface . Whether positive and negative electrodes are aligned before stacking and laminating electrodes having different polarities is determined. The positive and negative electrodes are then stacked, whereby the occurrence of a defective electrode due to misalignment between the positive and negative electrodes is preventable.

The calibrating system 100 includes a conveyance system 102 for carrying work products 104 arranged in multiple lanes extending along the conveyor to be trimmed and/or cut into portions P. A scanner 110 scans the work product and a cutter system 120 consisting of one or more cutters are arranged in an array or series of cutter assemblies for cutting the work products into end pieces P of desired sizes or other physical parameters. A processor/computer 150, using a scanning program or portioning program, determines how the work product may be portioned into one or more end piece product sets. The processor/computer using the portioning software then functions as a controller to control the cutter system 120 to portion the workpiece 104 according to the selected end product/pieces P.

A method and an apparatus for correcting a feeding distance of a strip or cutting, involves feeding the strip over the feeding distance in a feeding direction towards a cutting line that extends at an oblique cutting angle to the feeding direction; detecting a lateral position of a first longitudinal edge of the strip in a lateral direction perpendicular to the feeding direction; wherein, when the detected lateral position is offset over an offset distance in the lateral direction with respect to a reference position for the first longitudinal edge at the measuring line, and adjusting the feeding distance with a correction distance that is related to the offset distance in a ratio that is defined by the cutting angle.

A method and an apparatus for correcting a feeding distance of a strip or cutting, involves feeding the strip over the feeding distance in a feeding direction towards a cutting line that extends at an oblique cutting angle to the feeding direction; detecting a lateral position of a first longitudinal edge of the strip in a lateral direction perpendicular to the feeding direction; wherein, when the detected lateral position is offset over an offset distance in the lateral direction with respect to a reference position for the first longitudinal edge at the measuring line, and adjusting the feeding distance with a correction distance that is related to the offset distance in a ratio that is defined by the cutting angle.

A sheet-processing machine has a shaping device for processing sheets. The shaping device has at least one shaping point. The sheet-processing machine comprises at least one separating device. The at least one separating device is designed to remove at least one remaining piece from at least one sheet of the sheets. The at least one separating device is arranged downstream of the at least one shaping point along a transport path provided for transporting the sheets. At least one inspection device is arranged, downstream of the separating device in the transport direction of the sheets, to determine an actual state of the at least one sheet of the sheets. The invention additionally relates to a method for inspecting at least one remaining part of at least one sheet of sheets, which part has been processed by a shaping device, and to a method for inspecting at least one sheet of sheets.