A broaching tool is held during the conduct of repetitive duplicate rotary broaching operations on serially presented workpieces. The broaching tool is engaged serially with each workpiece for rotation with the engaged workpiece during a corresponding rotary broaching operation. Each workpiece has a given configuration and the broaching tool has a prescribed configuration placed at an initial orientation for establishing a broached configuration placed at a same predetermined orientation relative to the given configuration of each workpiece. Upon completion of a rotary broaching operation on a workpiece, the broaching tool is returned to the initial orientation of the prescribed configuration in preparation for a duplicate rotary broaching operation on a subsequent serially presented workpiece.

A smart cutting tool system for use in precision cutting, comprising a cutting insert (1), an upper cutter arbor (2), a lower cutter arbor (3), a first pressure sensor (4), a second pressure sensor (5), a signal processing module (6), a Bluetooth transmission module (7), and a power supply (8), wherein the cutting insert (1) is fixed to a front end of the upper cutter arbor (2), the cutting insert (1) is provided at its rear end with a microgroove, in which the first pressure sensor (4) and the second pressure sensor (5) are inserted. The cutting tool system solves the problem of mutual coupling of various cutting forces, and has higher sensitivity.

A vibration-cutting condition setting device capable of facilitating a selection of a tool and a setting of parameters. The vibration-cutting condition setting device for a machine tool includes a display unit and a control unit. The control unit accepts a setting for controlling an object to be fed with an vibration. The setting includes a feed speed without the vibration (F) of the object, a first parameter (A) regarding a cycle of the vibration, and a second parameter (E) regarding an amplitude of the vibration. The control unit calculates a maximum feed speed (Fmax) of the object according to the feed speed without the vibration (F), the first parameter (A), and the second parameter (E) and then displays a value representing the calculated maximum feed speed (Fmax) on the display unit.

A turning tool (1) that does not easily interfere with other tools and can supply a sufficient amount of coolant is provided. The turning tool (1) includes: a cutting insert (10) which is mirror-image symmetric with respect to a first and second symmetric surfaces (M1, M2); and a tool body (2) which has a first discharge port (5) to supply coolant to a first cutting edge (21E) of the cutting insert (10) from a first rake surface (21R) side. The first discharge port (5) is disposed between a second flat surface (32) and a first reference surface (Vxz) which is parallel with the second flat surface (32) and includes an edge line of the first cutting edge (21E).

An external turning tool includes an elongated tool body with opposite clamping and cutting portions which define an axial direction therebetween. The cutting portion includes a damping mechanism with an elongated damping member which defines an elongation axis. The elongation axis forms a non-zero damping member angle with the axial direction.

A cutting tool for cutting an object, or a holder for retaining the cutting tool, configured so that a current-carrying path for measuring a change in a member of the cutting tool or the holder is formed directly or indirectly in all or a portion of the member. This configuration makes it possible to objectively perceive a change occurring in the cutting tool or the holder or a change in the surrounding environment thereof at extremely low cost.

A cutting tool for cutting an object, or a holder for retaining the cutting tool, configured so that a current-carrying path for measuring a change in a member of the cutting tool or the holder is formed directly or indirectly in all or a portion of the member. This configuration makes it possible to objectively perceive a change occurring in the cutting tool or the holder or a change in the surrounding environment thereof at extremely low cost.

This method is a machining method using a tool body (10, 110) to which a distance sensor (31, 32) is attached, the method including a coordinate setting step of setting each of a cutting edge coordinate with a point of a cutting edge (22, 122) provided at the tool body (10, 110) as reference and a sensor coordinate with a reference point of the distance sensor (31, 32) as reference, a machining step of forming a machined surface using the cutting edge coordinate, and a measurement step of measuring a dimension of the machined surface using the sensor coordinate.

This method is a machining method using a tool body (10, 110) to which a distance sensor (31, 32) is attached, the method including a coordinate setting step of setting each of a cutting edge coordinate with a point of a cutting edge (22, 122) provided at the tool body (10, 110) as reference and a sensor coordinate with a reference point of the distance sensor (31, 32) as reference, a machining step of forming a machined surface using the cutting edge coordinate, and a measurement step of measuring a dimension of the machined surface using the sensor coordinate.

A fly-cutting system is disclosed, and in particular one that comprises a dynamically-controllable actuator for controlling the position, orientation, or both position and orientation of a cutting element carried by a fly-cutting head. In certain embodiments, the actuator can adjust the position or orientation of a cutting element, or both, hundreds or thousands of times per second, enabling precise control over the shape of features formed by the cutting element in a surface of a workpiece.