A path-controlled press, with at least one drive shaft having a driver that is eccentric relative to a shaft axis, and a sliding block, wherein the sliding block is driven by the driver to perform a forcibly actuated movement During the execution of a pressure stroke, the sliding block is guided on at least one sliding surface on the pressure side in relation to a pressure-side surface of a slide guide. The sliding block has a sliding surface on the pulling side opposite the sliding surface on the pressure side, which is guided on a surface of the slide guide on the pulling side. The sliding surface on the pressure side of the sliding block has a concave or convex curvature. The sliding surface on the pulling side of the sliding block has another respective concave or convex curvature.

A pressing structure includes a support frame and a pressing element. The pressing element is mounted to a bottom surface of the base plate. The pressing element includes a pedestal and a cushion element. The pedestal has a base board. A bottom surface of the base board protrudes downward to form a pressing block. A bottom surface of the pressing block is recessed upward and gradually arched outward from top to bottom to form a first pressing face. The rocker component has a base portion. The first pressing face is in contact with the base portion. The cushion element is mounted on the pedestal, so that the rocker component is mounted on the electronic component by the pressing structure, the rocker component and the electronic component are without affording the excessive pressure force to cause a damage and a deformation of the electronic component.

Improved balers may include a traveling chute that may reduce wear and tear and maintenance, and/or improve efficiency by reducing downtime. The traveling chute may include moving guides that include channels that engage tongues of stationary guide rails disposed on a baler. For example, the channels may be substantially rectangular channels that run the length of the moving guide. Similarly, the stationary guides may include substantially rectangular tongues and the moving guides may slide across the tongues and upper surfaces of the stationary guides as the traveling chute moves between various positions. The moving guides may include polyoxymethylene inserts in which the channels may be provided. The moving guides and stationary guides may be provided as a kit for attachment to various baling apparatuses. Additional features and components also are described.

A pressing structure includes a support frame and a pressing element. The pressing element is mounted to a bottom surface of the base plate. The pressing element includes a pedestal and a cushion element. The pedestal has a base board. A bottom surface of the base board protrudes downward to form a pressing block. A bottom surface of the pressing block is recessed upward and gradually arched outward from top to bottom to form a first pressing face. The rocker component has a base portion. The first pressing face is in contact with the base portion. The cushion element is mounted on the pedestal, so that the rocker component is mounted on the electronic component by the pressing structure, the rocker component and the electronic component are without affording the excessive pressure force to cause a damage and a deformation of the electronic component.

A bailing apparatus may include a multi-component bolster assemblies that may ease installation and removal, reduce wear and tear and maintenance, and/or improve baling efficiency by reducing material waste, imperfections, and/or contamination. The bolster assemblies may include a plurality of coupling portions that engage a hydraulic rod and may enable the bolster assembly to self-center within a press chamber during normal baling operations. The bolster assemblies also may include an island portion that may be attached to the coupling portions and to a bolster cap, and the latter may be attached using retainer bolts having substantially planar heads that may define lips that run about frustums. The bolts may substantially planar head may reduce irregularities in the bale and the lips may prevent material seepage into the bolster assemblies.

Improved balers may include a traveling chute that may reduce wear and tear and maintenance, and/or improve efficiency by reducing downtime. The traveling chute may include moving guides that include channels that engage tongues of stationary guide rails disposed on a baler. For example, the channels may be substantially rectangular channels that run the length of the moving guide. Similarly, the stationary guides may include substantially rectangular tongues and the moving guides may slide across the tongues and upper surfaces of the stationary guides as the traveling chute moves between various positions. The moving guides may include polyoxymethylene inserts in which the channels may be provided. The moving guides and stationary guides may be provided as a kit for attachment to various baling apparatuses. Additional features and components also are described.

The invention relates to a punch press for punching out punch products, such as automotive components, especially instrument panels, door interior panels or similar, with a frame, with a punching tool with a lower tool and an upper tool, with a machine table for holding the lower tool, and with a traversing device for moving the upper tool in relation to the lower tool, wherein the punch press, especially the punching tool, the machine table and the traversing device are set up for replacing the punching tool for a punch product change to retool the punch press to new punch products to be punched.

A shear press (100) for scrap comprising a machine body (105) defining a compaction channel (125) adapted to contain the scrap and guide it in a sliding manner along a predetermined advance direction (A), compaction means (155) and cutting means (180); wherein the compaction means (155) comprise: two mutually opposed jaws (170) articulated to the machine body (105) according to axes of rotation (B) parallel to each other and orthogonal to the advance direction (A) of the scrap, and actuating members (175) adapted to rotate said jaws (170) around the respective axes of rotation (B), in opposite directions, between an open configuration and a closed configuration, thereby reducing the space between the two jaws (170); wherein each jaw (170) comprises an operating surface (400) adapted to laterally de-limit the compaction channel (125) when the jaw (170) is in open configuration; wherein the cross section of said operating surface (400), carried out with respect to a section plane orthogonal to the axis of rotation (B), comprises an end (405) proximal to the axis of rotation (B), an end (410) distal from the axis of rotation (B) and at least one first rectilinear stretch (415) that is parallel to the advance direction (A) of the scrap when the jaw (170) is in the closed configuration, and wherein the extreme point (420) of said first rectilinear stretch (415) with respect to the axis of rotation (B) of the jaw (170) does not coincide with the distal end (410) of the cross section of the operating surface (400) but is aligned to the latter along a direction of alignment (C) which forms, with said first rectilinear stretch (415), an angle () having its vertex facing the inner part of the compaction channel (125).

The present disclosure provides a pressing device which includes: at least two floating heads which are arranged side by side; a positioning member connecting with each floating head and defining a position of each floating head; a cover plate positioned above each floating head; and elastic members, each elastic member being provided between the cover plate and the corresponding floating head so as to make the cover plate slide up and down relative to each floating head. The pressing device can be adapted to a step type cell or a step type battery having a certain tolerance in thickness and can ensure that every step surface of the step type cell or the step type battery is uniformly pressed, thereby improving the quality of the battery.

A joining punch for a joining device for producing a joining connection, in particular an adhesive connection, between a first joining part, for example a cover glass, and a second joining part, for example a housing, has at least one force-receiving part to which a contact force can be applied and having at least two pressing parts for applying pressure to the first joining part. The at least two pressing parts are arranged and/or formed independently of one another on the joining punch in such a manner that they are tiltable relative to the force-receiving part. The joining punch is embodied in a joining device. The two joining parts can be pressed together according to a nominal distribution of the forces or pressures, in particular uniformly using the joining device. Unevennesses and deformations of the joining parts, in particular of the first joining part, can be compensated.