A device for making a double-sided toothed belt has an inner mold having teeth and an outer mold. The outer mold includes segments arranged parallel to the longitudinal axis of the inner mold and mutually adjacent. The device has a force transmission element arranged on the radial outer side of the segments. A pressure vessel has a cylindrical wall surrounding the force transmission element. The force transmission element is formed as a bellows fastened with two ends in pressure-tight fashion to the pressure vessel. The force transmission element is arranged in a ring-shaped space formed between the wall of the pressure vessel and the radial outer side of the segments. The pressure vessel has a pressure medium bore which opens into the ring-shaped space radially outside the force transmission element. The segments and the inner mold each have one axial passage bore through which fluid can be conducted.

Solid metal protrusions are formed by a method including: clamping and fixing the metal workpiece with a support die and a pressure die; pressing each cross section of an outer peripheral end parts of the metal workpiece fixed with the support die and the pressure die at a temperature lower than a softening point of a metal used as the metal workpiece from a direction perpendicular or oblique to an upright direction of the protrusions to be formed on one surface of the metal workpiece by press molding using a pressing die or a pressing jig; undergoing plastic flows of metal into through-holes formed as recessed parts that serve as female molds for forming the protrusions in at least one of the support die and the pressure die; and forming solid protrusions on the surface of the metal workpiece.

Each of a plurality of divided dies (11, 12) has a divided surface (111, 121) and a defining surface (112, 122) which defines a cavity 100. The divided surface has an inclined divided surface (1112, 1212) inclined with respect to the translational direction, and at least one pair of perpendicular divided surfaces (1112, 1113, 1211, 1213) which is disposed on the opposite side based on the defining surface and is perpendicular to the translational direction. Each of the plurality of divided dies (11) and (12), while abutting against each other at, at least the at least one pair of perpendicular divided surfaces of the divided surface, abuts against each other in a state of being spaced apart from each other with a gap d within a range of 1 to 30 m at the inclined divided surface (1112, 1212), thereby forming the cavity 100.

In an example, a cubic press is described having press bases with spacers disposed between adjacent press bases. Sets of two or more tie bars are also disposed between adjacent press bases. The tie bars are placed in a state of compression while the spacers are placed in a state of compression. During operation, the press bases may become displaced relative to one another such that additional tension is experienced by the tie bars while the amount of compression experienced by the spacer is reduced. The tie bars exhibit a relatively small cross-sectional area as compared to the cross-sectional area of the spacer.

Powder press having preferably stamps which are movable for a transverse press in a feed housing. The stamps partially delimit a hollow chamber of a matrix in the feed housing and are able to be coupled to a press device by one connector piece each. An adjustable positioning device, which is formed from a wedge arrangement having a stop surface and placed crosswise to the moving direction of the stamp, is allocated to the respective stamp for determining the pressing position thereof. The wedge arrangement includes at least one wedge which is adjustable crosswise to the moving direction of the stamp and has the stop surface which contacts a stop surface at the stamp. Such a wedge arrangement can achieve very accurate pressing positions of the stamp, and extremely stable positioning of the stamp to be pressed with high pressure.

A compacting device and a method for producing a cutting insert green body by compacting a powder is provided. A die contributes to defining a die cavity that defines the shape of the green body to be formed. The die includes an upper die part defining an upper part of said die cavity together with an upper punch, a lower die part defining a lower part of the die cavity together with a lower punch, and intermediary die members, which are moveable in a plane perpendicular to a pressing axis and which define an intermediary part of the die cavity. The intermediary part of the die cavity defines an undercut portion, which extends circumferentially around the green body to be formed and which includes three or more peripheral indexing grooves in the green body.

Embodiments disclosed herein relate to cell assemblies for fabricating superhard materials (e.g., used in a high-pressure cubic press) and methods of using the same. The disclosed cell assemblies include a plurality of internal anvils, at least some of which are positioned internally relative to a cell pressure medium of the cell assembly. Such a configuration for the cell assemblies may enable one or more of intensifying cell pressure, reducing processing time, or reducing costs for fabricating such superhard materials.

A device (1) for generating high pressures in solid and liquid media is described. The device (1) includes a lower shell-shaped body half (2) and an upper shell-shaped body half (3). The device (1) further includes a lower elastic membrane (6) and an upper elastic membrane (7), which are each inserted into the lower body half (2) and into the upper body half (3), respectively. The respective body half (2, 3) and the respective membrane (6, 7) inserted into it each surround a pressure chamber (62, 73). The device (1) furthermore includes an opening and a channel (14) in the lower body half (2), in order to attach an oil line from an oil pump to the device and to pump the oil into the pressure chamber between the lower body half (2) and the elastic membrane (6) inserted into it. The pressure chambers (62, 73) in the lower body half (2) and in the upper body half (3) communicate by means of a line. The device (1) is distinguished in that the line connects the pressure chambers (62, 73) in the lower body half (2) and the upper body half (3) permanently with one another in both the open and the closed state of the device. The device is furthermore distinguished in that it includes a pipeline, which is embodied in the form of a helical spring line (17) and extends outside the lower shell-shaped body half (2) and the upper shell-shaped body half (3).

A press machine has a body, a lower pressing assembly, and an upper pressing assembly. The body has a first driving device, a second driving device, at least one first supporting rod, and at least one second supporting rod. The at least one first supporting rod is rotatably connected to the first driving device. The at least one second supporting rod is rotatably connected to the second driving device. The lower pressing assembly is movably mounted with the at least one first supporting rod of the body. The upper pressing assembly is movably mounted with the at least one second first supporting rod of the body, and is able to move toward the lower pressing assembly.

The invention relates to a device for producing conical bellows (2) for air springs, having at least one clamping/spreading device (9), wherein two terminal positions, specifically an introduction position and a vulcanization position, are attainable by the clamping/spreading device (9), wherein the external diameter of the introduction position is smaller than the external diameter of the vulcanization position. The clamping/spreading device (9) has clamping segments (6) which in the introduction position are converged in such a manner that the external diameter of the clamping/spreading device (9) enables an air spring bellows preform (2) to be pulled over, and the clamping segments (6) in the vulcanization position are diverged in such a manner that the external diameter of the clamping/spreading device (9) is enlarged in such a manner that the air spring bellows preform (2) is capable of being pressed tightly against the corresponding external shape (5) from the inside, wherein open gaps (10) on account of the enlargement of the external diameter of the clamping/spreading device (9) remain between the clamping segments (6).