High pressure presses, components for high pressure presses and related methods are provided herein. In one embodiment of the invention, a press base may include a piston cavity formed in the press base and a piston cavity sleeve positioned in the piston cavity. The piston cavity sleeve may include a wall having an outer surface and an inner surface opposite the outer surface. The piston cavity sleeve may further include a floor having an upper surface and a lower surface opposite the upper surface. An outer radius may be formed at a juncture of the outer surface of the wall and lower surface of the floor and an inner radius may be formed at a juncture of the inner surface of the wall and upper surface of the floor. The inner radius may exhibit a radius of curvature that is greater than a radius of curvature of the outer radius.

A link press assembly for use with a press to service a parallel link track chain is provided that includes alignment tools, disassembly tools, and reassembly tools. The alignment tools include a contact block, a plurality of block guide rods slidingly receivable within block guide rod passages of the contact block, a bridge plate for securement to a parallel link track chain, a plurality of elongated rod guides having plate guide rod passages, and a support block. The disassembly tools include a disassembly mount plate, an inner link support plate, a plurality of disassembly rods, an outer link support plate, and a disassembly tool bar having a plurality of pin bumpers. The reassembly tools include a back tool plate, a plurality of backing cups, a reassembly front tool bar having a plurality of front cups secured thereto, and a link hanger having a plurality of hanger guide rod passages.

A can crusher (102), having: a backing plate (120); a left crush-arm (126) pivotally secured to the backing plate and having a left handle (130) and a left crush surface (128) that faces the backing plate when the can crusher is in a closed configuration (190); a right crush-arm (140) pivotally secured to the backing plate and having a right handle (144) and a right crush surface (142) that faces the backing plate when in the closed configuration; and a support plate (150). In a vertical orientation (152) the backing plate is oriented vertically; the support plate is disposed below horizontal sweeps (154, 156) of the crush surfaces; and the support plate supports a can in between the crush surfaces when the can crusher is in an open configuration (104).

A can crusher (102), having: a backing plate (120); a left crush-arm (126) pivotally secured to the backing plate and having a left handle (130) and a left crush surface (128) that faces the backing plate when the can crusher is in a closed configuration (190); a right crush-arm (140) pivotally secured to the backing plate and having a right handle (144) and a right crush surface (142) that faces the backing plate when in the closed configuration; and a support plate (150). In a vertical orientation (152) the backing plate is oriented vertically; the support plate is disposed below horizontal sweeps (154, 156) of the crush surfaces; and the support plate supports a can in between the crush surfaces when the can crusher is in an open configuration (104).

A press head for a press machine used to press-fit a connector to a printed circuit board includes a press motor operable in a pressing operation, a driver assembly operably coupled to the press motor and movable during the pressing operation, and a press anvil operably coupled to the driver assembly and movable by the driver assembly during the pressing operation. The press anvil has a load cell housing holding a load cell and a contact plate coupled to the load cell housing and engaging the load cell. The contact plate has a contact surface configured to engage the connector or a seating tool for the connector and configured to press the connector toward the printed circuit board during the pressing operation. The load cell measures a pressing load of the contact plate during the pressing operation.

A can crusher (1900), including: a support plate (1912) and a backing plate (1902); a left crush-arm (1908) pivotally secured to the support plate and including: a left flap (1924) and a left handle (1920) that extends transverse relative to the left flap; a right crush-arm (1910) pivotally secured to the support plate and including a right flap (1934) and a right handle (1930) that extends transverse relative to the right flap; and a retaining pin (1914) directly secured to the support plate. When the support plate is horizontally oriented the retaining pin extends vertically upward from the support plate and is disposed outside a horizontal sweep of the left flap and outside a horizontal sweep of the right flap. The retaining pin is configured to trap a can between the retaining pin and the backing plate when the can crusher is in an open configuration.

A can crusher (1900), including: a support plate (1912) and a backing plate (1902); a left crush-arm (1908) pivotally secured to the support plate and including: a left flap (1924) and a left handle (1920) that extends transverse relative to the left flap; a right crush-arm (1910) pivotally secured to the support plate and including a right flap (1934) and a right handle (1930) that extends transverse relative to the right flap; and a retaining pin (1914) directly secured to the support plate. When the support plate is horizontally oriented the retaining pin extends vertically upward from the support plate and is disposed outside a horizontal sweep of the left flap and outside a horizontal sweep of the right flap. The retaining pin is configured to trap a can between the retaining pin and the backing plate when the can crusher is in an open configuration.

Embodiments of the present disclosure are directed to new and improved self-contained compactor systems incorporating a straight-push cylinder design, in which the compactor system is actuated in a horizontal direction. The improved design accommodates increased storage volume, long wear parts, simplified reservoir cleaning, and easier external access to the components, cylinders, and hoses of the self-contained compactor system.

Embodiments of the present disclosure are directed to new and improved self-contained compactor systems incorporating a straight-push cylinder design, in which the compactor system is actuated in a horizontal direction. The improved design accommodates increased storage volume, long wear parts, simplified reservoir cleaning, and easier external access to the components, cylinders, and hoses of the self-contained compactor system.

The present disclosure relates to a mounting press for hot mounting a sample, comprising: a mounting cylinder for receiving the sample, having a main cylinder axis and a cylinder opening, the main cylinder axis extending inside the mounting cylinder and out through the cylinder opening, a sliding closure with a sliding carriage, an upper piston and a closing lever that is operatively connected to the upper piston, wherein the sliding carriage is configured so as to be displaceable in a direction transverse to the main cylinder axis, for example by means of the closing lever, and wherein in a position of use of the sliding carriage the upper piston can be driven to or into the cylinder opening of the mounting cylinder, wherein the closing lever has at least one open position and one closed position and can be transferred from the open position into the closed position, and wherein the closing lever cooperates with the upper piston such that the upper piston closes the cylinder opening when guiding the closing lever from the open position into the closed position when the sliding carriage is in the position of use.