A working head for a hydrodynamic cutting tool includes a working head, an electro-hydraulic pump adapted to increase the pressure of a hydraulic liquid, and a pressure tube connected between the pump and the working head to communicate the pressure of the hydraulic liquid from the pump to the working head. The working head may be removably connectable to the pressure tube and includes two jaws movable, in response to the increase of the hydraulic liquid pressure, between an open position and a closed position to perform the cutting. A cutting detector may be used to detect the completion of the cutting. A cutting confirmation transmitter may be connected to the cutting detector and configured for a wireless transmission of a cutting completion confirmation signal to a cutting confirmation receiver of the cutting tool.

A power tool according to the present invention includes a cutting unit that performs a cutting action, and a cutting action input unit for turning the cutting action on and off. The cutting action input unit, when turned on, causes the cutting unit to move in a direction of an end position of the cutting action, and when turned off, causes the cutting unit to stop moving in a case where the cutting action has not ended at a time when the cutting action input unit is turned off, and to move in a direction of a standby position prior to a start of the cutting action in a case where the cutting action has ended at the time when the cutting action input unit is turned off.

A system for adjusting a cutting tool includes a cutting system having a cutting tool configured to cut material thermoformed to a dental model. The cutting system is configured to determine, based on a cut line generated for the cutting tool to cut a dental aligner from the material thermoformed onto the dental model, that the cutting tool is incapable of following the cut line. The cutting system is configured to adjust a position of the cutting tool with respect to the cut line so the cutting tool is capable of following the cut line.

A method and a system for handling slender bodies in a semi-finished production plant includes a cutting station separating slender bodies from a continuous wire, a finishing station of the head ends of the slender bodies, a dimensional verification station downstream of the finishing station, and transporting equipment transporting the slender bodies between stations. At or upstream of the cutting station a marking unit applies a reference marking on the slender bodies, which working identifies an original attitude including angular position. The transporting equipment includes gripping and locking assembly, locking at least the angular position of the reference mark to a relative reference system of the transport equipment. Upstream of the finishing station is a detecting and storing unit for data of the angular position to the relative reference system. A unit determines the original attitude of the slender bodies using the data in the dimensional verification station.

A shearing device and a method for an aluminum material are provided. The shearing device includes an upper pad die, a lower pad die, a first electrode provided on each of the upper pad die and the lower pad die, a heating device provided on the first portion of the upper pad die and the lower pad die, respectively as surface parts; and a shearing die provided on the upper pad die to move up and down with respect to a surface to which the aluminum material is discharged and including a second electrode. In addition, the shearing method for the aluminum material is provided for reducing chips generated during the shearing process.

The invention relates to a cutting tool with a holder, a cutting insert and a screw, wherein the holder has at least one seat with a base, a first side wall and a second side wall, wherein in a plane parallel to the base the first side wall extends in a first direction and the second side wall includes an acute angle (C) with the first side wall, wherein the base has a threaded hole for receiving the screw, wherein the cutting insert has a cut-out for the screw, wherein the cutting insert has a base contact surface, a first positioning surface and a second positioning surface, and wherein in a locked position the base contact surface, the first positioning surface and the second positioning surface of the cutting insert contact the base, the first side wall and the second side wall of the at least one seat, respectively, wherein the second side wall is offset from the threaded hole in the first direction towards a front end of the seat, and in that a screw head of the screw and the cut-out of the cutting insert are provided with complementary conical surfaces, such that when tightening the screw the cutting insert is forced with the first positioning surface and the second positioning surface against the first side wall and the second side wall, respectively.

Hydraulic two-side rolling-cut shears, including: a front transport roller device, a rear transport roller device, a shear body, and a roller carrier. The front transport roller device includes a laser scriber, a magnetic alignment device, and a pinch roller device. The rear transport roller device includes a vertical guide roller. The laser scriber is disposed on the front end of the front transport roller device. The magnetic alignment device is disposed in the middle part of the front transport roller device. The pinch roller device is disposed on the rear end of the front transport roller device in front of the shear body. The roller carrier is disposed longitudinally in the middle of the shear body. The vertical guide roller is disposed on the rear transport roller device and behind the shear body.

A system for adjusting a cutting tool includes a cutting system that includes a cutting tool that includes a tip configured to cut material thermoformed to a dental model. The cutting system is configured to determine, based on a cut line generated for the cutting tool to cut a dental aligner from material thermoformed onto a dental mold, a target tool vector defined by an angle of a tip of the cutting tool with respect to a surface of the dental model at the cut line, compare the target tool vector to a constraint of the cutting tool, and adjust a position of the tip of the cutting tool with respect to the cut line to compensate for the target tool vector being outside the constraint of the cutting tool.

An electric cutting device includes a pair of cutting blades configured to clamp and cut an object, an electric motor configured to generate a driving force necessary for operating the cutting blades, a controller configured to control an operation of the electric motor, and a speed detector configured to detect a speed index, the speed index indicating an operation speed of the cutting blades. The controller is configured to brake the cutting blades based on the speed index.

An electric cutting device includes: a pair of cutting blades clamping and cutting an object; an electric motor generating a driving force for operating the cutting blades; a controller controlling the electric motor; and an operation device switched between an ON state and an OFF state by a user operation. After the operation device enters into the ON state and the pair of cutting blades start operating in a closing direction, the controller is configured to: open the pair of cutting blades when the cutting of the object is completed while the operation device is kept in the ON state; and stop closing the pair of cutting blades when the operation device changes from the ON state to the OFF state at a timing before the cutting of the object is completed.