A high-speed cutting device includes a mounting frame, a feeding mechanism, a linear chasing-cutting mechanism, an electrode guide plate, and an acceleration driving mechanism, the acceleration driving mechanism is provided on the discharging side of the electrode guide plate, and configured to perform acceleration driving on a material tape. The acceleration driving mechanism is provided behind the linear chasing-cutting mechanism to realize the acceleration driving of the material tape.

A cutting apparatus for cutting a food object where inlet and outlet conveyors are arranged in an end-to-end arrangement. A moving mechanism is provided for adjusting the relative position between the ends of the inlet and outlet conveyors, a cutting device is provided having a cutting plane extending between the inlet and outlet conveyors, a detection mechanism is provided for detecting at least one characteristics related to the food object, and a control device is provided for controlling the moving mechanism and the cutting device. Controlling the moving mechanism includes utilizing the at least one detected characteristics in determining a target width of an opening between the ends of the inlet and outlet conveyors, and controlling the cutting device includes subsequently cutting the food object into smaller food pieces. The target width of the opening is selected such that it allows smaller food pieces to fall through the opening.

The present disclosure provides a film cutting method, a film cutting device, a composite film, a backlight module and a display device. The film material cutting method includes: using a cutting tool provided with a viscous material to cut a composite film that includes at least two laminated optical films, with the viscous material on the cutting tool being transferred to a cutting end surface of the composite film during cutting; and, curing the viscous material on the cutting end surface.

A device (1) is for processing a body (4) manufactured by an additive manufacturing method from a liquid substance curable by radiation. The device (1) includes a holder (3) for a build platform (2). The device (1) also includes a separating device (5) for separating a body (4) arranged on a build platform (2) held by the holder (3) from the build platform (2), and a method and use employ the device.

A device (1) is for processing a body (4) manufactured by an additive manufacturing method from a liquid substance curable by radiation. The device (1) includes a holder (3) for a build platform (2). The device (1) also includes a separating device (5) for separating a body (4) arranged on a build platform (2) held by the holder (3) from the build platform (2), and a method and use employ the device.

A cartridge adapted to secure reciprocating bread slicer blades including a rectangular frame having a planar surface, the frame having a plurality of pairs of opposed holders, each pair of the opposed holders adapted to releasably secure opposed ends of a corresponding bread slicer blade. The frame is adapted to secure a plurality of aligned bread slicer blades defining a plane offset from the frame planar surface. The frame is adapted to selectively maintain each of the plurality of aligned bread slicer blades in tension.

A cartridge adapted to secure reciprocating bread slicer blades including a rectangular frame having a planar surface, the frame having a plurality of pairs of opposed holders, each pair of the opposed holders adapted to releasably secure opposed ends of a corresponding bread slicer blade. The frame is adapted to secure a plurality of aligned bread slicer blades defining a plane offset from the frame planar surface. The frame is adapted to selectively maintain each of the plurality of aligned bread slicer blades in tension.

Systems and methods for cutting through one or more extrudates to form one or more honeycomb bodies are provided. The systems described herein provide a low inertia vibratory cutting system configured to cut through extrudate to form honeycomb bodies, where the vibratory cutting system comprises a thin, low-inertia cutting element, and one or more sets of fluid bearings configured to mitigate or lessen out of plane vibrations of the cutting element to provide a more stable cutting element. In some examples the vibratory cutting system comprises two sets of fluid bearings arranged at two locations on the cutting element that are configured to mitigate out-of-plane vibrations on the cutting element and between the two locations. In some examples, the cutting element is double-sided to allow for single-sided or double-sided cutting operations.

Systems and methods for cutting through one or more extrudates to form one or more honeycomb bodies are provided. The systems described herein provide a low inertia vibratory cutting system configured to cut through extrudate to form honeycomb bodies, where the vibratory cutting system comprises a thin, low-inertia cutting element, and one or more sets of fluid bearings configured to mitigate or lessen out of plane vibrations of the cutting element to provide a more stable cutting element. In some examples the vibratory cutting system comprises two sets of fluid bearings arranged at two locations on the cutting element that are configured to mitigate out-of-plane vibrations on the cutting element and between the two locations. In some examples, the cutting element is double-sided to allow for single-sided or double-sided cutting operations.

The invention relates to a winding apparatus for winding a material web traveling in a direction of travel, having at least one blade for cutting the material web in a web direction into a plurality of partial material webs, and having a folding apparatus for folding the edges of the partial material webs. To furnish a winding apparatus that enables a material web with folded edges to be wound with as little wrinkling as possible, a folding element is furnished for each edge of the partial material webs. The at least one blade may be moved transversely to the direction of travel using a first oscillating apparatus. Using a second oscillating apparatus, the folding elements for the left-hand edges of the partial material webs, as viewed in the direction of travel, may be moved transversely to the direction of travel. Using a third oscillating apparatus, the folding elements for the right-hand edges of the partial material webs, as viewed in the direction of travel, may be moved transversely to the direction of travel. The first oscillating apparatus, second oscillating apparatus and third oscillating apparatus may be controlled by a control unit in such a manner that the folded edges of the partial material webs may be wound at an offset to one another.