A method and a device for machining a workpiece rotating about a rotational axis. The machining point moves along the cutting edge of a cutting edge plane and the surface to be machined in a rolling movement on an advancement plane not intersected by the rotational axis. A pivot drive implements a large enough pivot angle so that a first workpiece surface is machined by a machining point moving along the first cutting edge in a first machining step. In a second machining step, a second workpiece surface is machined, wherein the machining point moves along the second cutting edge and the second workpiece surface. The cutting edge has a curvature radius smaller than the distance from the pivot axis of the holder to the cutting edge. The holder can additionally be displaced on the advancement plane with a movement component in a direction transverse to the rotational axis.

An insert according to the present disclosure includes a base and a coating layer covering a surface of the base. The base is made of cermet. The coating layer is made of Ti.sub.1abcdAl.sub.aM.sub.bW.sub.cSi.sub.d(C.sub.xN.sub.1x) (M is one or more metal elements selected from Nb, Mo, Ta, Hf, and Y, where 0.40a0.55, 0.01b0.1, 0.01c0.1, 0.01d0.05, and 0x1). The insert according to an embodiment of the present disclosure includes an intermediate layer containing Ti and located between the base and the coating layer. The intermediate layer has an average thickness of 20 nm or more and 80 nm or less.

The cutting insert includes an upper surface, a front side surface, a first corner side surface, a front cutting edge, and a first corner cutting edge. The upper surface includes a front land surface extending along the front cutting edge, a first corner land surface extending along the first corner cutting edge, a front groove extending inwardly with respect to the front land surface, and a first corner groove extending inwardly with respect to the first corner land surface. The length of the first corner groove is shorter than the length of the front groove.

A cutting insert for a machining tool having a cutting edge and a flute extending along the cutting edge is described. A chip breaker element which projects into the interior of the flute is disposed in the flute. Said chip breaker element comprises a chip guiding surface and each point of the chip guiding surface has a spacing from a flute contour that is greater than zero. The chip guiding surface furthermore either extends parallel to the flute contour and/or curved along two directions. A machining tool having such a cutting insert is presented as well.

This cutting insert is a plate-shaped cutting insert having a center line, and includes an upper surface that forms one surface of two surfaces facing each other in an axial direction along the center line; a lower surface that forms the other surface of the two surfaces facing each other; a side surface that connects the upper surface and the lower surface in the axial direction; and a mounting hole that passes through the cutting insert in the axial direction, in which the side surface extends obliquely inward in a radial direction perpendicular to the center line from the upper surface toward the lower surface in the axial direction.

An insert includes a base of a cermet including hard particles and a binder phase. The base includes first and second surfaces, a cutting edge on at least a part of a ridge line of the first and second surfaces, a third surface opposite to the first surface, and a through hole from the first surface to the third surface. An inner wall constituting the through hole includes a binder-phase-riched layer having a higher content of the binder phase than an inside of the base, at least in a center part. A thickness of the binder-phase-ricked layer in the center part is larger than a thickness of the binder-phase-ricked layer in an end part of the inner wall. A cutting tool includes a holder which has a pocket located at an end, the insert located in the pocket, and a clamp inserted in the through hole of the insert.

An insert includes a base which includes a first surface, a second surface connecting to the first surface, and a cutting edge located on at least a part of a ridgeline of the first surface and the second surface. The first surface includes a plurality of grooves located at a position away from the ridgeline and extended at an angle of 20-90 relative to the ridgeline. The grooves are away from the ridgeline in a range of 40-700 m. A width W of the grooves is 50-700 m, and a depth D of the grooves is 20-700 m. Spacing S between the grooves adjacent to each other is 50-700 m. A cutting tool includes a holder, which has a length extending from a first end to a second end and includes a pocket located on a side of the first end, and the insert is located in the pocket.

An insert of the present disclosure includes a boron nitride sintered body including a first surface. In a transmission X-ray diffraction of a cross section of the boron nitride sintered body vertical to the first surface, X-ray intensity at a top of a 111 diffraction peak of cubic boron nitride in a direction vertical to the first surface is IcBN(111)v. X-ray intensity at a top of a 002 diffraction peak of compressed boron nitride is IhBN(002)v. X-ray intensity at a top of a 111 diffraction peak of the cubic boron nitride in a direction parallel to the first surface is IcBN(111)h. X-ray intensity at a top of a 002 diffraction peak of the compressed boron nitride is IhBN(002)h. A compressed boron nitride content value obtained from these X-ray intensities is larger than 0.005. A cubic orientation value is larger than 0.5, and a compressed boron nitride orientation value is larger than the cubic orientation value.

A double-sided tangential cutting insert, having eight different working positions, includes two opposite end faces serving as leading and trailing faces of the cutting insert, two opposite major side faces, two opposite minor side faces, a through hole extending between the two major side faces, cutting edges distributed along a periphery of each end face, and four abutment surfaces arranged on each end face in a grid-like pattern with two first arrays, each of which have two consecutive abutment surfaces that extend between the two major side faces, and two second arrays, each of which have two consecutive abutment surfaces and extend between the two minor side faces. Each abutment surface are inclined inwards in the cutting insert such that each two consecutive abutment surfaces in each array are inclined towards each other.

A cutting insert has a bottom supporting surface, a center cutting edge, two secondary cutting edges, realized on both sides of the center cutting edge and offset in relation to the center cutting edge, and two transition edges connecting the center cutting edge to the secondary cutting edge adjacent in each case. The two secondary cutting edges are realized in each case vertically offset and, where applicable, also offset in depth with respect to the center cutting edge and are laterally spaced from the center cutting edge. The transition edges, in each case in a non-edge-overlapping region, have at least over a portion an inclination n where 2n20 in relation to a height direction which extends at right angles with respect to a main extension plane of the supporting surface.