A method of manufacturing an engine valve intermediate product with a boss portion formed in integral fashion at an outer circumferential surface at an intermediate location on a stem forming portion. The manufacturing method may comprise a stem retaining operation in which an intermediate location of the stem forming portion is retained by a plurality of intermediate jigs removably installable radially with respect to a center of the stem forming portion, and a base end portion is retained by a base end jig. The manufacturing method may further comprise a stem enlarging operation in which compressive forces are applied from both ends of the intermediate product and the boss portion is formed as the intermediate product is made to rotate and alternating loads that cause tensile forces and compressive forces to act in repeated and alternating fashion at the outer circumferential surface of the stem forming portion are applied.

A hub main body (13z) is supported by a support portion (18). At least one block (22) is engaged with a stationary flange (6) of an outer ring (2). As a support plate (21) rotates, the outer ring (2) rotates. A caulking portion (16) is formed by pressing a pressing die (20) on a cylindrical portion (31).

A bearing device for a vehicle wheel includes an outer member which is a plastic work piece in which an open hole in an outer-side end part is pushed out from inner sides, and an outer periphery of the outer member has a bulged part that is enlarged radially outward.

The application relates to a device for applying an applied force to a connection element such that the connection element is plastically deformed by the application of force. The device comprises a movably mounted head part with a machining head which is designed to contact the connection element; a drive which is designed to drive a translation of the head part in the longitudinal axis thereof; a second drive which is designed to drive a rotation of the machining head about a longitudinal axis; and a housing for receiving the first drive, the second drive, and the head part. The first drive and the second drive are electrically driven and are arranged coaxially. The application further relates to a method for operating a device according to the application and to the use of a device according to the application as an electric riveting machine.

An inner-ring restraint device of a hub bearing capable of restraining an inner ring efficiently without applying a load to the hub bearing. An inner-ring restraint device includes a restraint ring allowing a plurality of pieces to be arranged to form a ring shape and restricting an inner ring of a hub bearing by reducing a diameter, a support plate having a ring shape coaxial with the hub bearing, being provided so as to move in an axial direction and supporting the restraint ring at a position closer to the hub bearing for the vehicle than the restraint ring in the axial direction and a ring-shaped operation plate connected to the support plate so as to relatively move in the axial direction and applying a pressure in a direction of reducing the diameter to the restraint ring by coming relatively close to the support plate.

A moving element (21) holding a workpiece (a hub unit bearing (1)) is horizontally loaded into an internal space (23) of an exterior (17) from an external space of the outer package (17), while being guided by a guide member (20) through an opening portion (a front surface side opening portion (25)) provided in the exterior (17) constituting a rotary forging apparatus (16). After completion of the loading process, the workpiece is subjected to rotary forging, using a forming die (18).

Provided are an oil receiver (20) having an annular recess portion (52) which faces an entire circumference of an outer circumferential edge of a concave spherical portion (36), and a guide member (21) which guides lubricating oil, which has flowed out from a spherical engagement portion between a convex spherical portion (24) and a concave spherical portion (36), toward an annular recess portion (52).

A measuring pressing die (43) is supported by a spherical concave seat (12). A measuring shaft member (45) is disposed coaxially with a reference axis () and is linearly guided in a direction of the reference axis () between the measuring pressing die (43) and a support table (16). After that, the load application apparatus measures an actual load in the direction of the reference axis () applied to the measuring shaft member (45) using a load cell (48) in a state in which the measuring pressing die (43) is pressed against the measuring shaft member (45) while the measuring pressing die (43) is rotated about the reference axis ().

Provided are an oil pan (20) which has an annular recess portion (52) facing an outer circumferential edge of a spherical concave portion (36) throughout a whole circumference; and a cover (21) which is constituted in a tubular shape, of which one axial end portion is rotatably supported by a part adjacent to a radially inner side of the annular recess portion (52), and of which an axially opposite end portion is rotatably supported by a part of a shaft-equipped spherical seat (18) on the one axial end side.

A hub main body (13z) is supported by a support portion (18). At least one block (22) is engaged with a stationary flange (6) of an outer ring (2). As a support plate (21) rotates, the outer ring (2) rotates. A caulking portion (16) is formed by pressing a pressing die (20) on a cylindrical portion (31).