After holding a metal pipe 10 using a clamping die 5, a primary formed portion 11a corresponding to the preforming surface portion 5c is formed on the metal pipe 10 by pressing an end portion of the metal pipe 10 with a pressing die 6 in a direction of a cylinder center line C1. A final formed portion 11b is formed on the metal pipe 10 by moving an outer forming die 7 to press an outer circumferential surface of the metal pipe 10 with the outer forming die 7 after aligning a rib portion 7c with the primary formed portion 11a, while moving an inner forming die 8 to press an inner circumferential surface of the metal pipe 10 with the inner forming die 8 after aligning a recessed groove portion 8c with the primary formed portion 11a.

After holding a metal pipe 10 using a clamping die 5, a primary formed portion 11a corresponding to the preforming surface portion 5c is formed on the metal pipe 10 by pressing an end portion of the metal pipe 10 with a pressing die 6 in a direction of a cylinder center line C1. A final formed portion 11b is formed on the metal pipe 10 by moving an outer forming die 7 to press an outer circumferential surface of the metal pipe 10 with the outer forming die 7 after aligning a rib portion 7c with the primary formed portion 11a, while moving an inner forming die 8 to press an inner circumferential surface of the metal pipe 10 with the inner forming die 8 after aligning a recessed groove portion 8c with the primary formed portion 11a.

The present disclosure relates to a corrugated pipe forming apparatus including: a support block rotated by power of a motor; a bearing including an outer ring connected to an inner peripheral surface of the support block and an inner ring; a dies inserted into the inner ring in which at least a portion thereof is disposed inside of the support block, a screw protrusion forming a valley on a surface of the smooth pipe is formed; and a fastening ring. In the support block, a shielding wall covering a first gap formed between the first sidewall of the outer ring and the inner ring is formed to protrude inwardly from the first lateral side, and thus leakage of lubricating oil injected into the bearing is prevented.

The present disclosure relates to a corrugated pipe forming apparatus including: a support block rotated by power of a motor; a bearing including an outer ring connected to an inner peripheral surface of the support block and an inner ring; a dies inserted into the inner ring in which at least a portion thereof is disposed inside of the support block, a screw protrusion forming a valley on a surface of the smooth pipe is formed; and a fastening ring. In the support block, a shielding wall covering a first gap formed between the first sidewall of the outer ring and the inner ring is formed to protrude inwardly from the first lateral side, and thus leakage of lubricating oil injected into the bearing is prevented.

A power tool includes an outer housing having a drive unit support portion and a handle portion, an inner housing positioned at least partially within the handle, and a drive unit positioned in the drive unit support portion. The drive unit includes an output shaft extending at least partially through the handle portion. The power tool also includes a ball screw mechanism having a nut supported at least partially within the inner housing and a screw coupled to the nut for relative axial displacement therewith in response to relative rotation between the screw and the nut. Torque from the output shaft is applied to one of the nut and the screw to cause the relative rotation. The handle portion exerts a reaction torque on the inner housing in response to the relative rotation between the nut and screw to prevent the inner housing from rotating relative to the outer housing.

The present disclosure relates to a corrugated pipe forming apparatus including: a support block rotated by power of a motor; a bearing including an outer ring connected to an inner peripheral surface of the support block and an inner ring; a dies inserted into the inner ring in which at least a portion thereof is disposed inside of the support block, a screw protrusion forming a valley on a surface of the smooth pipe is formed; and a fastening ring. In the support block, a shielding wall covering a first gap formed between the first sidewall of the outer ring and the inner ring is formed to protrude inwardly from the first lateral side, and thus leakage of lubricating oil injected into the bearing is prevented.

The present disclosure relates to a corrugated pipe forming apparatus including: a support block rotated by power of a motor; a bearing including an outer ring connected to an inner peripheral surface of the support block and an inner ring; a dies inserted into the inner ring in which at least a portion thereof is disposed inside of the support block, a screw protrusion forming a valley on a surface of the smooth pipe is formed; and a fastening ring. In the support block, a shielding wall covering a first gap formed between the first sidewall of the outer ring and the inner ring is formed to protrude inwardly from the first lateral side, and thus leakage of lubricating oil injected into the bearing is prevented.

A power tool includes an outer housing having a drive unit support portion and a handle portion, an inner housing positioned at least partially within the outer housing, and a drive unit positioned in the drive unit support portion, the drive unit including an output member. The power tool also includes a power screw mechanism with a nut fixed relative to the outer housing and a screw coupled for co-rotation with the output member and axially movable relative to the output member. The screw is in threaded engagement with the nut such that the screw moves axially in response to rotation of the screw relative to the nut. The power tool also includes a working assembly coupled to the inner housing for movement in response to axial movement of the screw.

A power tool includes an outer housing having a drive unit support portion and a handle portion, an inner housing positioned at least partially within the outer housing, and a drive unit positioned in the drive unit support portion, the drive unit including an output member. The power tool also includes a power screw mechanism with a nut fixed relative to the outer housing and a screw coupled for co-rotation with the output member and axially movable relative to the output member. The screw is in threaded engagement with the nut such that the screw moves axially in response to rotation of the screw relative to the nut. The power tool also includes a working assembly coupled to the inner housing for movement in response to axial movement of the screw.

A method for producing rotationally symmetric structural components of metal, in particular steel, is provided. A blank is arranged in a torsion-proof manner on a first receptacle, the receptacle is rotated about a rotation axis so that the blank is caused to rotate about this rotation axis, at least one linear shaping element with a contour having at least partially an unrolled external contour of the rotationally symmetric structural component or a preform of the structural component is moved tangentially to the surface of the synchronously rotating blank, and the linear shaping element is at the same time pressed against the blank so that during the tangential movement the contour of the linear shaping element is formed at least partially into the blank. A kingpin or link pin of a connection link with a connection shaft and a link outer part is produced.