A novel cutting method and apparatus includes a cutting blade adapted to consistently and easily form a desirable kerf in a concrete substrate while capturing substantially all resulting concrete dust.

Devices and methods for processing animal or human tissue are provided. The devices may include a vacuum surface to secure the tissue in place and an apparatus for removing fat or other material from the tissue. The apparatus can include one or more blades and/or a fluid jet system.

Devices and methods for processing animal or human tissue are provided. The devices may include a vacuum surface to secure the tissue in place and an apparatus for removing fat or other material from the tissue. The apparatus can include one or more blades and/or a fluid jet system.

A distributor valve for a hydrocutting system. The valve automatically diverts a flow of liquid and solid food products flowing from a source to one or both of two destinations. An entry conduit receives the suspended food products in liquid, and an angled plate deflects the food products downwardly. The food products and liquid enter a drum that is perpendicular to the entry conduit, causing rotational circulation in the drum. The food products and liquid flow into one or both of two longitudinally opposite outlets, depending on whether the path downstream of the outlets is flowing. Upon actuation of a valve on one side, or essentially complete blockage of one side, the fluid and products flow to the other side automatically. No moving parts are needed in the valve to change the flow path; the only change is to the flow downstream, which automatically affects the flow in the valve.

A device for cutting paper webs comprises a substantially continuously operated region of a papers supply, a discontinuously operated region of transverse severing of a separating the paper web, and a buffer region (15) for coupling the continuously and discontinuously operated regions. At least one receptacle (17) open at the top is provided in the buffer region, into which the paper web(s) (3, 3) are guided so as to be looped in a freely suspended manner. The buffer region is arranged after a longitudinal cutting device (9) for producing at least two longitudinal webs (3, 3), whereby at least two webs extending separately and adjacently to one another are guided in the receptacle or at least two receptacles are arranged adjacently to one another or adjacently to one another at an offset, wherein the paper webs are guided into the receptacles.

A method of delivering a discrete cord to a transfer member, wherein the method includes providing a supply path fluidly connected to a metered cord supply. The supply path comprises a fluid flow, a transfer member, and a cutting apparatus. The transfer member comprises a first surface, a second surface, and a plurality of orifices on the first surface. The method also comprises moving a deployed cord supply towards the transfer member through the supply path by the fluid flow. The method further comprises moving a portion of the deployed cord supply into an orifice of the transfer member and cutting the deployed cord supply to create a discrete cord comprising a first end and a second end; wherein a portion of the discrete cord is in the orifice to the transfer member.

Provided is a microtomic system and process for the preparation of sections for microscope examination. A cutting edge in the system can cut through a sample block and produce a section one end of which remains attached to the cutting edge. A voltage generator can generate a voltage and apply the voltage between the cutting edge and a section receiver such as a semiconductor chip grid. Through electrostatic force caused by the voltage, another end of the section can anchor to the section receiver. The section is then spread on the receiver. The system is automatable, highly efficient, and does not need liquid to float sample sections, and can therefore maintain the integration of the sample sections.

Provided is a process of using a microtomic system for the preparation of sections for microscope examination. A cutting edge in the system can cut through a sample block and produce a section one end of which remains attached to the cutting edge. A voltage generator can generate a voltage and apply the voltage between the cutting edge and a section receiver such as a semiconductor chip grid. Through electrostatic force caused by the voltage, another end of the section can anchor to the section receiver. The section is then spread on the receiver. The system is automatable, highly efficient, and does not need liquid to float sample sections, and can therefore maintain the integration of the sample sections.

Devices and methods for processing animal or human tissue are provided. The devices may include a vacuum surface to secure the tissue in place and an apparatus for removing fat or other material from the tissue. The apparatus can include one or more blades and/or a fluid jet system.

A glass tube cleaning and cutting device includes a glass tube cutting device configured to cut an end portion of a glass tube while the glass tube cutting device rotates the glass tube having a predetermined length about a tube axis of the glass tube and conveys the glass tube in a direction orthogonal to the tube axis, at least one blower configured to blow air into an opening located on a first end portion side of the glass tube, and at least one cutting blade provided at a position opposite to the at least one blower interposing the glass tube therebetween, the at least one cutting blade being configured to impose thermal shock and scratches on an outer circumference surface of a second end portion side of the glass tube to cut the second end portion side of the glass tube.