A circle cutting system with a blade coupled to a body that rotates and is pressed into sheet material for the separation of circular portions from a larger sheet of the material, such as roofing material.

A cutter roll and an anvil roll, with which it is possible to control deformation in the axial direction, and a rotary cutter having the same. A roll 101, 210 for a rotary cutter includes: a barrel portion having a circumferential surface and a pair of end surfaces located respectively at opposite ends of the circumferential surface; a pair of first depressions 113, 213 having a ring shape or a cylindrical shape and located respectively at the pair of end surfaces of the barrel portion, the pair of first depressions each having a depth direction that is parallel to an axis of the barrel portion; a pair of first bearings 152, 252 located respectively in the pair of first depressions and being in contact with outer walls of the first depressions; and a pair of first bearing boxes 156 located on an outside of the pair of first depressions and having support portions 151b, 251b to be in contact with a support frame or a pressure mechanism, the pair of first bearing boxes supporting the respective bearings.

A Tool for making controlled cuts using a template cutting guide to facilitate the registration and cutting of a workpiece including, an elongated body portion having a top face and a bottom face separated by a thickness, a cutting guide slot sized to receive and control a cutting blade and extending through the thickness of the elongated body which may include guide lines with equidistant spacing. Additionally, the cutting guide may utilize push pins or fasteners to secure the cutting guide to the workpiece. The cutting guide allows the user to execute precise cuts in material such as mat board using a standard utility knife.

A method and apparatus are provided for die cutting label stock comprising a facestock, an adhesive and optionally a liner to form labels where a liner of the linered pressure sensitive adhesive label stock may be a thin or ultrathin liner.

A cutting device includes a platen, a mounting portion, a movement mechanism, 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 including acquiring a hardness-correspondence value corresponding to a hardness of a cutting object placed on the platen, acquiring cutting data for cutting a pattern from the cutting object, setting, based on the hardness-correspondence value, an offset amount used for a rotation correction to a greater value when the hardness of the cutting object is hard than when the hardness of the cutting object is soft, correcting, using the set offset amount, data, of the cutting data, corresponding to a direction change section, and performing cutting processing to cut the cutting object using a cutting blade, by controlling the movement mechanism in accordance with the corrected cutting data.

The present invention comprises: a support roller part rotating while supporting the lower side of a transferred sticker sheet; a half-cutting roller part provided at the top of the support roller part so as to rotate by engaging with the support roller part, and having a half cutter for cutting a printed part of the sticker sheet passing the support roller part; and an anti-adhesion fluid supplying unit for applying an anti-adhesion fluid on the surface of the half cutter coming into contact with the printed part of the sticker sheet.

A system for cutting a three-dimensional portion from a foodstuff includes a conveyor for carrying a foodstuff to be portioned, a scanner located adjacent to the conveyor for scanning the foodstuff, a computer coupled to the scanner for receiving scan information to determine one or more cutting paths for the foodstuff, and a cutter for portioning the foodstuff according to the determined cutting path(s). The computer performs generally four steps: (i) receiving scan information from the scanner; (ii) building a three-dimensional map of the foodstuff based on the received scan information; (iii) fitting at least one desired shape, which is stored in the memory of the computer, onto the built three-dimensional map; and (iv) determining one or more cutting paths for portioning the foodstuff to produce one or more portioned foodstuffs corresponding to the at least one desired shape.

A laser plotter, a device and a method for cutting of a graphic is disclosed. The method may comprise preparation or loading of a processing job with a graphic and identification features at a display; application of the recognition features and of the graphic to the workpiece; arrangement of the workpiece in a processing area of a laser plotter; acquisition or detection of identification features in order to determine the position and alignment of the applied graphic in the processing area; carrying out the processing after successful identification of the graphic; after the insertion of the workpiece, a laser-pointer is positioned on any selected identification feature, whereupon, a processing image represented on a display element, with the identification feature, is moved at the display element in such a way that a laser position displayed at the display element coincides with the identification feature.

A method for converting a flat substrate (W) in a station (3) for converting a flat substrate (W) that includes a rotary cutting unit (9) and at least one rotary deformation unit (7, 8) positioned upstream of the rotary cutting unit (9) in the direction of movement (L) of the flat substrate (W), the method including: determining the conversion parameters of the flat substrate (W), such as the deformation layout and cutting layout; choosing a sleeve (13) carrying a form for carrying out the deformation depending on the deformation layout; mounting the sleeve (13) on a mandrel (12) in the rotary deformation unit (7, 8); choosing the cutting tools (91, 92) depending on the cutting layout; mounting the cutting tools (91, 92) in the rotary cutting unit (9); and starting the conversion of the flat substrate (W).

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.