Disclosed is an ultrasonic cutting method employing a straight-blade sharp knife. The ultrasonic cutting method employing the straight-blade sharp knife includes the following steps: S1, measuring parameters of the straight-blade sharp knife; S2, initially rotating, by the straight-blade sharp knife, around an axis thereof, such that a rear knife surface of the straight-blade sharp knife is attached to or is away from a machined surface, and performing ultrasonic vibration cutting on a material according to a machining track; S3, performing quality detection on the machined material surface obtained by the ultrasonic vibration cutting, completing the machining if the surface passes the detection, and performing step S4 if the surface does not pass the detection; S4, further increasing an amount of rotation of the straight-blade sharp knife during initial rotation around the axis thereof, performing the ultrasonic vibration cutting on the material according to the machining track, and performing step S3.

In one embodiment, systems and methods include using an ultrasonic cutter in a ground detection system to prevent damage to a substrate. The method of detecting a substrate comprises attaching a workpiece clamp to the substrate. The method further comprises cutting a layer of coating disposed on the substrate with an ultrasonic cutter, wherein the ultrasonic cutter operates at a frequency of about 20 kHz to about 40 kHz, wherein the layer of coating is non-conductive. The method further comprises contacting the substrate with the ultrasonic cutter.

Systems and methods include using an ultrasonic cutter tool to cut a seal. The system comprises an ultrasonic cutter tool disposed onto a railing system coupled to a platform, wherein the ultrasonic cutter tool is configured to translate along the railing system. The system further comprises a power source electrically coupled to the ultrasonic cutter tool, and an alignment mold disposed parallel to the railing system and offset by a distance. The system further comprises one or more roller bearing carriages coupled to the railing system, wherein each of the one or more roller bearing carriages comprises a set of roller bearings, wherein each set of roller bearings is disposed over the alignment mold, wherein each set of roller bearings is configured to translate along the alignment mold as each of the one or more roller bearing carriages translates along the railing system.

There is provided a cutter or mold having at least one sidewall defining a cavity, wherein the cavity draft angle varies. In some embodiments, the cutter may also include a base, i.e., the cutter can be a mold. The cutter or mold exhibits better release properties of food products molded or cut therewith than conventional cutters or molds having no cavity draft angle, or a uniform cavity draft angle. Rotary cutting wheels, that in some embodiments may be ultrasonically activated, as well as systems incorporating the cutters or molds are also provided, as are methods of forming food products using the cutters or molds.

A device for processing a flexible sheet includes a worktop for placement thereon of a flexible sheet to be processed. A processing device is provided above the worktop and a positioning device is provided for positioning the processing device on the flexible sheet and moving it along a straight processing line in the plane of the flexible sheet. The device also includes orientation device for setting the orientation of the processing line as desired.

Disclosed embodiments describe a reconstructed filament comprising natural protein fibrils and an additive. Disclosed embodiments also describe a wool comprising: a plurality of staple fibers formed of reconstructed filaments, wherein the reconstructed filaments comprise natural protein fibrils and an additive. Disclosed embodiments also describe a yarn spun from staple fibers, the yarn comprising: staple fibers comprising reconstructed filament, wherein the reconstructed filament comprises natural protein fibrils and an additive. Disclosed embodiments also describe an item comprising a reconstructed filament, wherein the reconstructed filament comprises natural protein fibrils and an additive.

An anvil in which a plurality of convex portions are formed on the surface of a roll, a plurality of horns that are ultrasonically vibrated to repeatedly make contact with the convex portions through an elastic sheet so as to perform melting and cutting and a plurality of vibration devices that ultrasonically vibrate the horns are included, the tip ends of the horns are arranged so as to be opposite the anvil and the horns are arranged in different positions in the axial direction of the roll so that the horns make contact with different convex portions of the convex portions.

Systems and methods are described for controlled crack propagation in a material using ultrasonic waves. A first stress in applied to the material such that the first stress is below a critical point of the material and is insufficient to initiate cracking of the material. A controlled ultrasound wave is then applied to the material causing the total stress applied at a crack tip in the material to exceed the critical point. In some implementations, the controlled cracking is used for wafering of a material.

Disclosed is a cutting-off machine for cutting logs of sheet material, including at least one cutting blade placed on a plane perpendicular to the axis of the logs, in order to perform transverse cuts over the same and produce rolls of smaller length than the logs, wherein the at least one cutting blade is associated with an ultrasonic device apt to generate a vibrating force on the blade.

A method for manufacturing a hollow protruding implement (1) including a fine hollow protrusion (3) having an opening (3h) of the present invention includes a protrusion forming step of inserting a projecting mold part (11) into a base material sheet (2A) from one face (2D) side thereof, the base material sheet containing a thermoplastic resin, thereby forming a non-penetrated hollow protrusion (3) projecting from another face (2U) side of the base material sheet (2A). Subsequently, an opening forming step is performed in which an opening (3h) that penetrates the hollow protrusion (3) is formed by using a contactless opening forming means disposed on the other face (2U) side of the base material sheet (2A).