The invention relates to a milling tool made of cemented carbide having a cylindrical shank (16) and a cutting head (18) for the face milling of workpieces made of a hard-brittle material. The cutting head (18) is configured as an end mill with corner radius or a ball nose end mill having a cutting length (L 2.2). The shank (16) has, up to its chucking end (26), at least one clearance segment (28) having a smaller diameter (d3) than the cutting head (18). The tip of the cutting head (18) is coated or tipped with hard mineral along a length (L2) having a diameter (d1) used for finishing, to which is connected a segment (24), which is used for roughing, having the cutting length (L2.2−L2=L2.1) and a reduced diameter (d4), which is smaller than the diameter (d1) of the cutting length (L2) on the cutting head (18) used for finishing and is greater than the diameter (d3) of the clearance segment (28).

The invention relates to a milling tool made of cemented carbide having a cylindrical shank (16) and a cutting head (18) for the face milling of workpieces made of a hard-brittle material. The cutting head (18) is configured as an end mill with corner radius or a ball nose end mill having a cutting length (L 2.2). The shank (16) has, up to its chucking end (26), at least one clearance segment (28) having a smaller diameter (d3) than the cutting head (18). The tip of the cutting head (18) is coated or tipped with hard mineral along a length (L2) having a diameter (d1) used for finishing, to which is connected a segment (24), which is used for roughing, having the cutting length (L2.2−L2=L2.1) and a reduced diameter (d4), which is smaller than the diameter (d1) of the cutting length (L2) on the cutting head (18) used for finishing and is greater than the diameter (d3) of the clearance segment (28).

A cutting tool includes: a cutting section having a cutting edge; a sensor provided in the cutting section; and a communication unit provided in the cutting section. The communication unit transmits, to a processing device provided outside the cutting tool, measurement information relating to measurement results of the sensor and including serial numbers corresponding to the measurement results after a timing of a start of cutting by the cutting edge.

A cutting tool includes a grip part and a cutting part. In the grip part and the cutting part, a channel for guiding fluid supplied from the outside to an outflow port is formed. The channel includes: a first channel extending in parallel to a rotational center axis and linearly from an end part of the grip part on an opposite side to the cutting part; and a second channel extending linearly from the first channel toward a cutting edge of a cutting insert. The first channel is formed such that a center axis thereof is decentered so as not to match the rotational center axis.

A cutting tool includes a grip part and a cutting part. The grip part and the cutting part have a channel for guiding fluid supplied from outside to an outflow port. The channel includes a plurality of first channels that extend at least partially parallel to a rotational center axis, and second channels that extend from the first channels toward cutting edges of cutting inserts. In the cutting tool, the number of first channels is smaller than the number of cutting edges arranged in a circumferential direction.

A cutting tool includes a grip part and a cutting part. The grip part and the cutting part have a channel for guiding fluid supplied from outside to an outflow port. The channel includes a plurality of first channels that extend at least partially parallel to a rotational center axis, and second channels that extend from the first channels toward cutting edges of cutting inserts. In the cutting tool, the number of first channels is smaller than the number of cutting edges arranged in a circumferential direction.

A burr includes a shaft portion and a milling portion. Cutters are separated by main flutes having a main flute depth. The cutters extend helically at a first twist angle. Each cutter has a cutting edge between a rake face and a relief face. The rake face forms a rake angle, and the relief face forms a relief angle. Chip breakers in each relief face have a chip breaker depth. At the largest diameter of the milling portion, the chip breaker depth is between 5 and 25 percent of the main flute depth, the rake angle is between −3 degrees and +14 degrees, the relief angle is between 10 degrees and 20 degrees, the first twist angle is greater than 25 degrees, and the number of main flutes is less than 15.

A burr includes a shaft portion and a milling portion. Cutters are separated by main flutes having a main flute depth. The cutters extend helically at a first twist angle. Each cutter has a cutting edge between a rake face and a relief face. The rake face forms a rake angle, and the relief face forms a relief angle. Chip breakers in each relief face have a chip breaker depth. At the largest diameter of the milling portion, the chip breaker depth is between 5 and 25 percent of the main flute depth, the rake angle is between −3 degrees and +14 degrees, the relief angle is between 10 degrees and 20 degrees, the first twist angle is greater than 25 degrees, and the number of main flutes is less than 15.

Provided are a machining system and a machining apparatus, a machining method, and a machining program that can improve machining precision. The machining system includes: a machining path setting unit that sets first and second machining paths based on a three-dimensional shape of a measured target component; and a movement control unit that moves an end mill along the first and second machining paths. The movement control unit includes a feed direction control unit that moves the end mill in a feed direction in which the end mill is moved along the first and second machining paths, an orthogonal direction control unit that moves the end mill in a direction orthogonal to the feed direction, and a tilt control unit that controls a tilt angle of the end mill about an axis of the feed direction.

A cutting tool includes: a main body portion composed of a cemented carbide; and a front end portion composed of a binderless cubic boron nitride polycrystal, the front end portion being joined to the main body portion. In an axial direction along a rotation axis of the main body portion, the main body portion has a first end and a second end opposite to the first end. The front end portion has a neck portion and an edge portion, the neck portion protruding from the second end along the axial direction, the edge portion being continuous to the neck portion, the edge portion being located at a location distant away from the second end relative to the neck portion in the axial direction. In the axial direction, the neck portion has a third end on the edge portion side and a fourth end opposite to the third end.