A turning toolholder includes a shank, a club head, and a clamp and a clamp screw for clamping a cutting insert. The club head includes a clamp coolant supply hole in fluid communication, a flank coolant supply hole and an auxiliary rake coolant supply hole, all in fluid communication with the main coolant supply hole. Coolant is supplied through a rake coolant exit opening formed in the forward nose portion of the clamp to direct coolant to the top rake surface of the cutting insert, and coolant is supplied through a flank coolant exit opening located below the insert-receiving pocket to provide coolant to the side flank surfaces of the cutting insert. In addition, an auxiliary rake coolant supply housing formed on a top surface of the club head supplies additional coolant to the top rake surface of the cutting insert during high heat applications.

A tool for machining work pieces is disclosed. In order to provide a tool which exhibits only very small vibrations during operation, the tool body of the tool has a cavity in which a multiplicity of hollow structural elements having an outer closed shell, within which at least one solid particle or a hollow body is arranged in a freely movable manner, are accommodated.

A toolholder includes a cutting tool mounted to a head attached to a collar at a first end of the toolholder. A shank is located at a second, opposite end of the toolholder. A central cavity extends inwardly from the first end toward the shank. A viscous fluid inertia mass damper is disposed within the central cavity. The viscous fluid inertia mass damper includes an absorber body having a first end, a second end opposite the first end, a fluid reservoir formed in the damper body for containing a viscous fluid, and a plurality of apertures formed in the damper body for allowing the viscous fluid to flow from the fluid reservoir and through the apertures to suppress vibration of the toolholder. A method for suppressing vibrations in a toolholder is also disclosed.

A cutting insert (1) includes a top surface (6), a side surface, a rake face (10) on the top surface (6), a front flank face (11) and a lateral flank face (12), a cutting edge (9) including a front cutting edge (13), and a lateral cutting edge (14), a breaker groove (15) adjacent to the front cutting edge (13) and the lateral cutting edge (14), and a rake face end (20). The breaker groove (15) includes a descending surface (16) and an ascending surface (17). The ascending surface (17) includes a front wall surface (21) and a lateral wall surface (22) on the side of the front cutting edge (13) and the side of the lateral cutting edge (14). An opening angle (1) of the front wall surface (21) is greater than an opening angle (2) of the lateral wall surface (22) in the top surface (6) view.

The invention relates to an insert holder for a tool for turning a machine tool, comprising an insert holder body (2), the head (22) of which is intended to receive a cutting insert (3), characterized in that at least two measurement recesses (4, 5) are provided in the insert holder body (2) on the side of the head (22), said measurement recesses (4, 5) being arranged symmetrically relative to the neutral fiber (6) of the insert holder body (2) and centered on the neutral fiber (6). The measurement recesses (4, 5) have, respectively, a planar bottom (41, 51) that is parallel to the direction (Y) of the component of the tangential cutting force of the insert holder to be measured, and parallel to the longitudinal direction (X, Z) of the insert holder body (2). The insert holder also comprises at least one first strain gauge (71, 72, 73, 74) configured such as to measure the change in shape of the planar bottom (41, 51) of at least one of the measurement recesses (4, 5).

A method for fabricating a rotatable cutting tool is disclosed. The method may comprise fabricating a body of a holder for the cutting tool, wherein the body of the holder extends along an axis and includes a head portion and a shank portion. The head portion may extend from a first end to a second end, and the first end may be configured to receive a cutting tip. The method may further comprise applying a plurality of rotation-assisting strips along an outer surface of the head portion that extend between the first end and the second end. The rotation-assisting strips may project from the outer surface of the head portion. The method may further comprise heat treating the holder having the plurality of rotation-assisting strips.

A method of selectively hardfacing a holder of a cutting tool is provided. The method includes creating a groove on an outer surface of the holder. The method also includes applying a wear resistant material within the groove of the holder to form a wear resistant layer. The method includes heat treating the holder having the wear resistant layer.

A method of selectively hardfacing a holder of a cutting tool is provided. The method includes creating a groove on an outer surface of the holder. The method also includes applying a wear resistant material within the groove of the holder to form a wear resistant layer. The method includes heat treating the holder having the wear resistant layer.

A machine tool assembly including a body component, a head component and a fastener. The body and head components respectively include a body hole and a head hole. The fastener is configured to secure the head component to the body component via insertion through the head hole and attachment to the body hole. The head hole includes a head fastener retention arrangement for preventing unintentional ejection of the fastener therefrom.

A machine tool assembly including a body component, a head component and a fastener. The body and head components respectively include a body hole and a head hole. The fastener is configured to secure the head component to the body component via insertion through the head hole and attachment to the body hole. The head hole includes a head fastener retention arrangement for preventing unintentional ejection of the fastener therefrom.