A housing including an internal gear having a first central axis as a center; a first rotating body relatively rotatably joined to the housing ; a second rotating body including an external gear having a second central axis parallel to the first central axis as a center and meshing with an internal gear and relatively rotatably joined to the first rotating body; a ram shaft joining part connected to the second rotating body and configured to be linearly moved in a reciprocating manner in a prescribed direction; and an air supply path passing through the insides of the first rotating body, the second rotating body, and the ram shaft joining part are provided.

A can body maker includes a ram shaft extending in a front-rear direction, a punch disposed at a front end portion of the ram shaft, a reciprocating linear motion mechanism connected to a rear end portion of the ram shaft to reciprocate and linearly move the ram shaft in the front-rear direction, a die having a through hole into which the punch is inserted, a cup holding mechanism which presses a cup-shaped body against an end face in which the through hole of the die opens, and a cup holder drive mechanism that oscillates the cup holding mechanism in the front-rear direction, wherein the cup holder drive mechanism has a cam structure and is disposed directly below the cup holding mechanism.

A can body maker includes a ram shaft extending in a front-rear direction, a punch disposed at a front end portion of the ram shaft, a reciprocating linear motion mechanism connected to a rear end portion of the ram shaft to reciprocate and linearly move the ram shaft in the front-rear direction, a die having a through hole into which the punch is inserted, a cup holding mechanism which presses a cup-shaped body against an end face in which the through hole of the die opens, and a cup holder drive mechanism that oscillates the cup holding mechanism in the front-rear direction, wherein the cup holder drive mechanism has a cam structure and is disposed directly below the cup holding mechanism.

A reciprocating linear motion mechanism for a can body maker includes: a housing including an internal gear; a first rotation body; a first bearing connecting the housing and the first rotation body; a convex part protruding toward one side of an axis direction in the axis direction; a second rotation body including an external gear meshing with the internal gear; a recess recessed toward onside in the axis direction from a surface facing the other side of the second rotation body in the axis direction and into which the convex part is inserted; a second bearing connecting the convex part and the recess; and a ram shaft connection part connected to the second rotation body and moved linearly in a reciprocating manner, wherein the internal gear, the external gear, the recess, the second bearing, and the convex part overlap each other.

A reciprocating linear motion mechanism for a can body maker includes: a housing including an internal gear; a first rotation body; a first bearing connecting the housing and the first rotation body; a convex part protruding toward one side of an axis direction in the axis direction; a second rotation body including an external gear meshing with the internal gear; a recess recessed toward onside in the axis direction from a surface facing the other side of the second rotation body in the axis direction and into which the convex part is inserted; a second bearing connecting the convex part and the recess; and a ram shaft connection part connected to the second rotation body and moved linearly in a reciprocating manner, wherein the internal gear, the external gear, the recess, the second bearing, and the convex part overlap each other.

The present disclosure provides a manufacturing process of an arc-shaped bottom titanium cup, including: S1: pressing an inner support ring; S2: primary crystallization; S3: matching; S4: welding opening parts; S5: pressing a titanium cup vacuum bottom; S6: welding the titanium cup vacuum bottom; S7: secondary crystallization; S8: vacuumizing; S9: detecting a thermal insulation function; S10: welding a titanium cup bottom plate; S11: surface polishing; and S12: oxidation processing. The present disclosure provides an inner support ring structure, the inner support ring always holds the titanium cup vacuum bottom round and maintains the titanium cup vacuum bottom in a high degree of roundness, thereby ensuring that a surface of a titanium cup shell and a titanium cup vacuum bottom is flat and smooth. The arc-shaped bottom titanium cup is clamped by adopting an upper mold and a lower mold, so that the arc-shaped bottom titanium cup is accurately limited.

The present disclosure provides a manufacturing process of an arc-shaped bottom titanium cup, including: S1: pressing an inner support ring; S2: primary crystallization; S3: matching; S4: welding opening parts; S5: pressing a titanium cup vacuum bottom; S6: welding the titanium cup vacuum bottom; S7: secondary crystallization; S8: vacuumizing; S9: detecting a thermal insulation function; S10: welding a titanium cup bottom plate; S11: surface polishing; and S12: oxidation processing. The present disclosure provides an inner support ring structure, the inner support ring always holds the titanium cup vacuum bottom round and maintains the titanium cup vacuum bottom in a high degree of roundness, thereby ensuring that a surface of a titanium cup shell and a titanium cup vacuum bottom is flat and smooth. The arc-shaped bottom titanium cup is clamped by adopting an upper mold and a lower mold, so that the arc-shaped bottom titanium cup is accurately limited.

A symmetric, modular base for a can processing system. The base includes a leg portion comprising a plurality of openings adapted for receiving at least one of a transfer star wheel and a turret mechanism configured to perform a working operation on an article. The base further includes a first foot portion extending from a first side of the leg portion. The base further includes a second foot portion extending from the second side of the leg portion. The base further includes a plurality of openings in the first foot portion and the second foot portion, the plurality of openings of the first and second foot portion providing access to an interior portion of the base. The base is generally symmetric about a center line drawn vertically through a midpoint of the leg portion of the base between the first foot portion and the second foot portion to allow for mounting of components on either a first side or a second side of the base.

Provided is a machining jig on which a carbon film (3) is formed on a machining surface of a rigid substrate (1), in which the carbon film (3) indicates a Raman spectroscopy spectrum with an intensity ratio, represented by the formula: I.sub.D/I.sub.G (where I.sub.D is the maximum peak intensity at 1333±10 cm.sup.−1 in the Raman spectroscopy spectrum of the carbon film surface, and I.sub.G is the maximum peak intensity at 1500±100 cm.sup.−1 in the Raman spectroscopy spectrum of the carbon film surface), exceeding 0.6. Also provided is a method of manufacturing seamless can bodies, the method including a step of using a mold machining member, on which a diamond film is formed on a machining surface, to press work a metal material onto the machining surface of the mold machining member in a state where a coolant is interposed.

Provided is a machining jig on which a carbon film (3) is formed on a machining surface of a rigid substrate (1), in which the carbon film (3) indicates a Raman spectroscopy spectrum with an intensity ratio, represented by the formula: I.sub.D/I.sub.G (where I.sub.D is the maximum peak intensity at 1333±10 cm.sup.−1 in the Raman spectroscopy spectrum of the carbon film surface, and I.sub.G is the maximum peak intensity at 1500±100 cm.sup.−1 in the Raman spectroscopy spectrum of the carbon film surface), exceeding 0.6. Also provided is a method of manufacturing seamless can bodies, the method including a step of using a mold machining member, on which a diamond film is formed on a machining surface, to press work a metal material onto the machining surface of the mold machining member in a state where a coolant is interposed.