Discussed is a cutting device to cut at least a portion of an uncoated portion of an electrode assembly that includes a separator, a first electrode sheet and a second electrode sheet wound in a stack. The cutting device includes a first cutter portion to form first cut lines in the uncoated portion at an axial direction of the electrode assembly while moving in the axial direction; and a second cutter portion to form a second cut line in the uncoated portion at a peripheral direction of the electrode assembly while moving in a radial direction of the electrode assembly, the second cutter portion forming a cut surface portion in the uncoated portion of the electrode assembly by connecting the second cut line to the first cut lines and cutting out a portion of the uncoated portion defined by the first cut lines and the second cut line.

The method serves for operating a cutting device, which is designed for cutting a process material, particularly foodstuff and which has at least one blade, which is driven by a drive device and to which ultrasonic energy is supplied from a ultrasound unit via at least one energy converter and a coupling element. A control unit is provided, which controls the ultrasound unit in such a way, that the frequency of the ultrasonic energy which is supplied to the blade via only one coupling element is keyed between at least a first and a second operating frequency or that the ultrasonic energy is supplied to the blade via a first coupling element with a first operating frequency and via a second coupling element with a second operating frequency, which frequencies are fixed or keyed between at least two operating frequencies.

Systems and methods utilizing stationary and/or moveable cutting components provide limited interference with web processing operations, such as pad spin and pitch alteration. Heat, laser, fluid, or mechanical cutting operations may be used, including respectively, a heated element (e.g., wire, ribbon, bar, or embossing or perforating element) that may be triggered inductively, water or steam jets, or improved knife/anvil cooperation.

Systems and methods utilizing stationary and/or moveable cutting components provide limited interference with web processing operations, such as pad spin and pitch alteration. Heat, laser, fluid, or mechanical cutting operations may be used, including respectively, a heated element (e.g., wire, ribbon, bar, or embossing or perforating element) that may be triggered inductively, water or steam jets, or improved knife/anvil cooperation.

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.

The disclosure relates to a method for producing a fiber preform, wherein: at least one dry and textile fiber material is provided; the fiber material is assembled into a plurality of individual layers; the plurality of individual layers is provided with a binder; the plurality of individual layers is layered to form a package; and a plurality of interconnected fiber preforms is formed by pressing the package. A separation of the plurality of interconnected fiber preforms and activation of the binder occur in a common process step. The disclosure furthermore relates to a corresponding system.

The present invention relates to an ultrasonic vibration system (1) comprising a sonotrode which has two sonotrode end faces (8, 8) and a circumferential lateral surface that connects said sonotrode end faces (8, 8) with each other. The sonotrode has an elongate core element (2) and at least one wing element (3, 4), each core element (2) and wing element (3, 4) longitudinally extending from the one sonotrode end face (8) to the other sonotrode end face (8). The wing element (3, 4) has a sealing surface (7) which is designed to be in contact with a material for the purpose of processing same and which is connected to the core element (2) via a plurality of longitudinally interspaced connecting portions (5, 6). The ultrasonic vibration system further comprises a converter (9) which is optionally connected to the sonotrode via an amplitude transformer (11). According to the invention, the converter (9) or the amplitude transformer (11) is connected to the lateral surface of the sonotrode

The invention relates to a method for applying an adhesive tape on a flange of a stiffener, each flange extending longitudinally and including an outer profile, the method comprising a step for driving the stiffener from upstream to downstream along a circulation path; a step for measuring the outer profile of a portion of the flange of the stiffener in a first position of said circulation path; a step for applying said adhesive tape on the flange of the stiffener; then a step for cutting said adhesive tape, in a second position of said circulation path situated downstream from the first position, based on said measured outer profile.

A unit for cutting thin films of synthetic material has a worktable and a cutting head. The cutting head has a shoe with a smooth bearing surface and a cutting member that can project from the smooth bearing surface. The smooth bearing surface is intended to be applied against the thin film of synthetic material, while the shoe is moved substantially parallel to the worktable so that it can cut the thin film of synthetic material. The worktable has a non-slip coating with a static coefficient of friction in relation to the synthetic material, while the smooth bearing surface has a dynamic coefficient of friction in relation to the synthetic material. The dynamic coefficient of friction is lower than the static coefficient of friction.

The present application discloses a microtome. The microtome includes: a blade cutting a soft material in a first direction, the first direction being a feeding direction of the soft material; a blade holder holding the blade; an actuator providing a vibration in a second direction along a cutting edge of the blade; and a frequency-tunable resonator driven by the actuator into vibration and fixedly connected to the blade holder to transfer the vibration to the blade holder and the blade, the resonator having a tunable resonant frequency in the second direction.