A damper includes a damper body that is configured to be attached to a workpiece during a machining process. A first side of the damper body is configured to abut a first side of the workpiece. The damper body includes a frame forming an outer periphery of the damper body, a plurality of damper nodes with a cavity in each damper node positioned in the frame, and a plurality of ribs extending between the frame and the damper nodes. A damping material is positioned in the cavity of each damper node.

A milling tool for milling a material is provided. The milling tool comprises a tool shank having an axis of rotation, and further comprises a tool head at one end thereof. The tool head comprises at least two tiers, each tier comprising a plurality of flutes extending circumferentially around the tool head. The tool head comprises superhard material and the tiers are axially displaced from each other and separated by a non-cutting portion of the tool head.

A milling and boring tool with a tool shaft which comprises a center axis, at least one geometrically defined rough cutter and at least one geometrically defined finishing cutter, and the at least one rough cutter and the at least one finishing cutter respectively comprise a chip groove. The milling and boring tool is characterized in that the chip groove of the at least one finish machining cutter has an opposite twist than the chip groove of the at least one rough cutter.

A method for milling a planar surface, during which a milling cutter, an axis of rotation of which is perpendicular to a surface to be machined, is moved in a direction parallel to the plane of the surface, to machine the surface in a single machining operation, over a predetermined layer of material, using a single milling head, and the milling cutter, in a same axial position relative to the surface to be machined, simultaneously carries out rough working, at least one intermediate finishing operation, and a finishing operation over a same layer of material.

A plurality of helical grooves are formed in a workpiece having a cylindrical shape. Each of grooves is divided into a first portion including an end portion on a first end side of the workpiece and a second portion including an end portion on a second end side of the workpiece. A method of manufacturing a screw rotor of a screw compressor includes attaching a first end of the workpiece to a holder of a machine tool, finishing the first portion of each of the plurality of helical grooves by cutting, detaching the workpiece from the holder, attaching a second end of the workpiece detached from the holder to the holder, and finishing the second portion of each of the plurality of helical grooves by cutting.

The invention relates to a milling tool having a plurality of first blades and at least one second blade, which are arranged on the milling tool in a staggered manner in the circumferential direction of the milling tool, wherein the plurality of first blades are arranged in the axial direction of the milling too at a nominal position, wherein the plurality of first blades comprises a compensation group having at least one compensation blade and at least one non-compensation blade, wherein the at least one non-compensation blade is assigned a nominal cutting circle, wherein the at least one compensation blade is assigned a compensation cutting circle, wherein the nominal cutting circle and the compensation cutting circle are different, wherein the at least one second blade is offset forward in the axial direction of the milling tool by a forward offset with respect to the nominal position in the direction of a machining front end, wherein the at least one second blade is assigned a surface machining cutting circle, wherein the surface machining cutting circle is smaller than the nominal cutting circle and than the compensation cutting circle, wherein the at least one second blade leads the plurality of first blades in the circumferential direction.