A tube cutter includes a handle, a carrier, a circular knife, a knob, a threaded rod and a spring. The handle includes an aperture. The carrier is movably connected to the handle, and includes a screw hole. The circular knife is supported on the carrier. The knob is rotationally connected to the handle and includes a non-circular recess. The threaded rod includes a threaded section inserted in the screw hole, a shank inserted in the aperture, and a non-circular head inserted in the non-circular recess. The spring is compressed between the handle and the non-circular head to render the threaded rod smoothly movable relative to the handle.

A tube cutter includes a handle, a carrier, a circular knife, a knob, a threaded rod and a spring. The handle includes an aperture. The carrier is movably connected to the handle, and includes a screw hole. The circular knife is supported on the carrier. The knob is rotationally connected to the handle and includes a non-circular recess. The threaded rod includes a threaded section inserted in the screw hole, a shank inserted in the aperture, and a non-circular head inserted in the non-circular recess. The spring is compressed between the handle and the non-circular head to render the threaded rod smoothly movable relative to the handle.

A cardboard box dividing device includes lower conveyors on which a plurality of connected cardboard box bodies are stacked and transported; a pressing device pressing, from above, the plurality of connected cardboard box bodies stacked on the lower conveyors; a cutting blade disposed along a width direction of the connected cardboard box body and dividing the plurality of connected cardboard box bodies stacked on the lower conveyors into a front part and a rear part; a lifting/lowering device relatively moving the plurality of connected cardboard box bodies on the lower conveyors and the cutting blade along an up-down direction; and a control device controlling the pressing device based on a lifting/lowering height of a loading upper conveyor at a time when a pressing reaction force at a time when the loading upper conveyor presses the plurality of stacked connected cardboard box bodies reaches a preset reference pressing reaction force.

A tissue chip core-making system based on image recognition and positioning and a core-making method thereofincludes a cutting system and a computer control system. The cutting system includes a numerical control cutting machine, XYZ-axis translation worktables, a 360 rotation turntable, a recipient wax block rack, a freezing table and an image recognition and positioning module. A core-making process based on the core-making system includes: lofting, sample position recognition, tissue sample image acquisition, tissue sample image processing, cutting parameter setting, tissue sample cutting, tissue core information recognition and storage to obtain a tissue core with information traceability. The method obtains a coring region through visual recognition, and has the characteristics of high automation degree and high work efficiency.

A cutting machine for cutting a foam product from a foam blank. The cutting machine has a blank holder adapted to receive the foam blank and a cutting blade. At least one of the blank holder and the cutting blade is mounted for movement relative to the other. The blank holder has a first component having a die projection formed on a front surface of the first component. A second component has a cutting surface and an aperture. A third component has a cutting surface and is locatable in the aperture. At least one of the first component and the second component is mounted for movement relative to the other between a first configuration, in which the first and second components are distal to one another, and a second configuration, in which the first and second components are proximal to one another.

A cutting machine for cutting a foam product from a foam blank. The cutting machine has a blank holder adapted to receive the foam blank and a cutting blade. At least one of the blank holder and the cutting blade is mounted for movement relative to the other. The blank holder has a first component having a die projection formed on a front surface of the first component. A second component has a cutting surface and an aperture. A third component has a cutting surface and is locatable in the aperture. At least one of the first component and the second component is mounted for movement relative to the other between a first configuration, in which the first and second components are distal to one another, and a second configuration, in which the first and second components are proximal to one another.

A bundle breaker has upstream and downstream breaking supports and first and second platens located above the breaking supports that are configured to be raised and lowered by actuators to selectively clamp a log between the platens and the breaking supports. A third actuator applies a shifting force to the downstream breaking support to shift an input end of the downstream breaking support relative to an output end of the upstream breaking support to break a second portion of the log from a first portion of the log. A controller controls the first actuator and the second actuator and the third actuator. Also, the controller is configured to stop or reduce the application of the shifting force in response to a determination that the second portion of the log has broken off the first portion of the log.

An optical fiber cutting device includes: a pair of grippers that grip an optical fiber having a glass portion exposed from the optical fiber; a gripping force applier disposed in one or both of the pair of grippers and that generates and changes a gripping force; a tension applier that applies tension to the optical fiber by separating the pair of grippers from each other in a longitudinal direction of the optical fiber; a tension measuring sensor that measures the tension; a controller that controls the gripping force; and a blade disposed between the pair of grippers in the longitudinal direction and that forms a scratch on the glass portion.

An optical fiber cutting device includes: a pair of grippers that grip an optical fiber having a glass portion exposed from the optical fiber; a gripping force applier disposed in one or both of the pair of grippers and that generates and changes a gripping force; a tension applier that applies tension to the optical fiber by separating the pair of grippers from each other in a longitudinal direction of the optical fiber; a tension measuring sensor that measures the tension; a controller that controls the gripping force; and a blade disposed between the pair of grippers in the longitudinal direction and that forms a scratch on the glass portion.

The cutting device includes a blade (1), in which either the blade (1) can move relative to a sheet of flexible material (4) or the sheet of flexible material (4) can move relative to said blade (1), and the blade (1) is associated with a plurality of independent flexible bristles (2), which press and stabilize the flexible material vertically and/or horizontally against a base (5) where the flexible material to be cut is supported. The device can be used to apply constant and well-distributed pressure on the flexible material in the cutting zone, preventing the material from wrinkling and securing the same in an optimal manner relative to the blade, thereby facilitating the cutting.