Techniques for implementing and/or deploying a swage machine, which includes a die plate that enables a die to be used to conformally deform a pipe fitting around pipe segment tubing to be loaded in the swage machine, a grab plate having grab plate sections that are pivotably connected, and grab adapter sections. Each grab adapter sections includes a base sub-section connected to a corresponding grab plate section, in which an inner surface of the base sub-section includes an alignment notch, and a modular sub-section to be secured to the base sub-section, in which an outer surface of the modular sub-section includes an alignment tab to be disposed within the alignment notch in the base sub-section and an inner surface of the modular sub-section includes a grab tab section that matingly interlocks with a fitting grab notch on the pipe fitting to facilitate securing the swage machine to the pipe fitting.

A pressed article includes a main body, a recess portion, a pin, and a groove portion. The main body has a plate shape. The recess portion is provided in a first surface of the main body facing one side in a plate thickness direction of the main body. The pin is provided at a position corresponding to the recess portion on a side of a second surface opposite to the first surface of the main body, is formed to have an outer shape smaller than that of the recess portion when viewed in the plate thickness direction of the main body, and protrudes in the plate thickness direction of the main body. The groove portion is recessed from the second surface of the main body toward the first surface and is provided to surround at least a part of the periphery of the pin.

A pressed article includes a main body, a recess portion, a pin, and a groove portion. The main body has a plate shape. The recess portion is provided in a first surface of the main body facing one side in a plate thickness direction of the main body. The pin is provided at a position corresponding to the recess portion on a side of a second surface opposite to the first surface of the main body, is formed to have an outer shape smaller than that of the recess portion when viewed in the plate thickness direction of the main body, and protrudes in the plate thickness direction of the main body. The groove portion is recessed from the second surface of the main body toward the first surface and is provided to surround at least a part of the periphery of the pin.

The purpose of the present invention is to provide a coated metal mold having superior durability and adhesion resistance over a usage range from cold to warm/hot; and a method for manufacturing the coated metal mold. The coated metal mold is characterized by having a hard coating on a surface, wherein the hard coating includes an A layer formed from a nitride and having a film thickness not smaller than 5 μm, and a B layer formed of a diamond-like carbon coating, the B layer is disposed closer to the outer surface side than the A layer, the surface of the B layer has an arithmetic mean roughness Ra≤0.2 μm, a maximum height Rz≤2.0 μm, and a skewness Rsk<0.

The purpose of the present invention is to provide a coated metal mold having superior durability and adhesion resistance over a usage range from cold to warm/hot; and a method for manufacturing the coated metal mold. The coated metal mold is characterized by having a hard coating on a surface, wherein the hard coating includes an A layer formed from a nitride and having a film thickness not smaller than 5 μm, and a B layer formed of a diamond-like carbon coating, the B layer is disposed closer to the outer surface side than the A layer, the surface of the B layer has an arithmetic mean roughness Ra≤0.2 μm, a maximum height Rz≤2.0 μm, and a skewness Rsk<0.

A precision forging method includes arranging a metal material in a die cavity so that a distal end surface of a wall portion of the metal material is opposed toward a stopper and a bottom portion of the metal material is opposed toward a punch. Further, the precision forging method includes moving the punch, which includes a cutting blade on an edge of a working end surface, in the die cavity to cut part of the wall portion thickness-wise with the cutting blade and cause shear deformation in the cut portion.

A precision forging method includes arranging a metal material in a die cavity so that a distal end surface of a wall portion of the metal material is opposed toward a stopper and a bottom portion of the metal material is opposed toward a punch. Further, the precision forging method includes moving the punch, which includes a cutting blade on an edge of a working end surface, in the die cavity to cut part of the wall portion thickness-wise with the cutting blade and cause shear deformation in the cut portion.

A mould for hot forging includes a first half-mould and a second half-mould. The first and second half-moulds each include a mould holder having a recess and a die provided with an impression. The die is combined with the mould holder at the recess. At least one of the first half-mould and the second half-mould is provided with at least one feeding channel for a lubricating-cooling liquid, extending from an outer wall of the mould holder to the recess of the mould holder, and with a plurality of distribution channels for the lubricating-cooling liquid. At least one quota of the plurality of distribution channels includes distribution channels extending from a wall of the die facing the recess, to the impression. The at least one feeding channel and the distribution channels face at least one gap formed between the mould holder and the respective die at the recess.

A mold of the present disclosure is used when forging a billet having a rod shape, and the mold includes: a lower mold having a groove portion for housing the billet; an upper mold having a pressing portion engaged with the groove portion and that presses the billet; and a guide portion disposed in the groove portion or the pressing portion and that guides a flow of a material of the billet in a longitudinal direction of the billet. In a state in which the groove portion and the pressing portion are engaged, in a direction in which the groove portion extends, a protruding amount of a top portion of the guide portion to an inner side of the groove portion is larger than a protruding amount of end portions on both sides sandwiching the top portion of the guide portion to the inner side of the groove portion.

A mold of the present disclosure is used when forging a billet having a rod shape, and the mold includes: a lower mold having a groove portion for housing the billet; an upper mold having a pressing portion engaged with the groove portion and that presses the billet; and a guide portion disposed in the groove portion or the pressing portion and that guides a flow of a material of the billet in a longitudinal direction of the billet. In a state in which the groove portion and the pressing portion are engaged, in a direction in which the groove portion extends, a protruding amount of a top portion of the guide portion to an inner side of the groove portion is larger than a protruding amount of end portions on both sides sandwiching the top portion of the guide portion to the inner side of the groove portion.