The invention relates to a method for producing an electrode stack made of anodes and cathodes for a lithium-ion battery, in particular of an electrically powered motor vehicle, wherein the anodes or the cathodes are provided with a separator, wherein the anodes and the cathodes are conveyed into receiving areas of a rotationally driven or rotatably driven stacking wheel; wherein the anodes and cathodes received in the receiving areas are conveyed to a stacking compartment by rotation of the stacking wheel; wherein the anodes and the cathodes are held in the region of the stacking compartment by a removal arm and are transferred from the respective receiving areainto the stacking compartment as a result of the rotation of the stacking wheel, wherein said anodes and cathodes are stacked in an alternating manner in the stacking compartment; and wherein the alternately stacked anodes and cathodes are pressed against one another in the stacking compartment. The invention additionally relates to a device for producing such an electrode stack.

The invention relates to a method for producing an electrode stack (4) from monocells (5) for a lithium-ion battery, in particular of an electrically powered motor vehicle, wherein the monocells (5) are each formed from an anode (6) and a cathode (8), wherein the monocells (5) are conveyed into receptacles (14) of a rotationally driven or rotationally drivable stacking wheel (12), wherein the monocells (5) accommodated in the receptacles (14) are conveyed by means of a rotation of the stacking wheel (12) to a stacking compartment (24), wherein the monocells (5) are held by means of a stripper arm (22) in the region of the stacking compartment (24), and are transferred due to the rotation of the stacking wheel (12) from the respective receptacles (14) into the stacking compartment (24), wherein the monocells (5) are stacked in the stacking compartment (24), and wherein the stacked monocells (5) are pressed against each other in the stacking compartment (24). The invention also relates to an apparatus (2) for producing such an electrode stack (4).

A sheet stacker includes a pair of sheet holders, a sheet leading-edge aligner, a sheet stacking member, and control circuitry. A downstream side of the pair of sheet holders in a conveyance direction of a conveyed sheet is lowered along the conveyance direction. Each one of the pair of sheet holders is movable in an orthogonal direction to the conveyance direction. The pair of sheet holders hold both side-end portions of the sheet in the orthogonal direction. The sheet stacking member is disposed below the pair of sheet holders. A downstream side of the sheet stacking member in the conveyance direction is lowered along the conveyance direction. The sheet stacking member stacks the sheet dropped from the pair of sheet holders after a leading edge of the sheet is aligned by the leading-edge aligner. The control circuitry controls operations of the leading-edge aligner and the pair of sheet holders.

A media storage bin has a guide member mounted via a hinge adjacent to a wall of an enclosure and a second free end. The guide member directs inserted media items downward and pivots around an axis of the hinge. A base plate is mounted below the guide member in the enclosure and is arranged to hold a stack of inserted media items on a top surface thereof. A motor is coupled to move the base plate up and down within the enclosure. A controller is coupled to control movement of the motor and is configured to provide signals to the motor to move the base plate to a predetermined home position adjacent to the guide member upon startup and move the base plate upward to compress any deformed inserted media items on the base plate until an input feedback signal reaches a predetermined level.

A sheet stacker includes a pair of sheet holders, a sheet leading-edge aligner, a sheet stacking member, and control circuitry. A downstream side of the pair of sheet holders in a conveyance direction of a conveyed sheet is lowered along the conveyance direction. Each one of the pair of sheet holders is movable in an orthogonal direction to the conveyance direction. The pair of sheet holders hold both side-end portions of the sheet in the orthogonal direction. The sheet stacking member is disposed below the pair of sheet holders. A downstream side of the sheet stacking member in the conveyance direction is lowered along the conveyance direction. The sheet stacking member stacks the sheet dropped from the pair of sheet holders after a leading edge of the sheet is aligned by the leading-edge aligner. The control circuitry controls operations of the leading-edge aligner and the pair of sheet holders.

A method and apparatus are disclosed for processing structured tissue material to form a compressed bundle of folded tissues. A web of at least one ply of structured tissue is subjected to a destructuring operation before folding with itself or with another similar web to form a stack. The stack can then be compressed to form the compressed bundle at a pressure that is less than would have been the case, had the structured tissue not first been destructured.

A binding device includes a stacking device configured to receive sheets, a sheet alignment member configured to align the sheets on the stacking device, a binder configured to bind the sheets on the stacking device, a binder moving device configured to move the binder, and a retreat device configured to retreat the sheet alignment member from a range of movement of the binder. The retreat device retreats the sheet alignment member in response to a pressing force acting on the sheet alignment member in a direction of movement of the binder.

A pleated filter preparation system is provided for accurately counting pleats along a continuous sheet of pleated filter material and cutting the sheet into filter strips to be formed into filters. The pleated filter preparation system includes a pleat driver having multiple drive gears that engage with the pleats of the pleated filter material to move the pleated filter material through the system. A pleat counter counts peaks and valleys of each pleat comprising the pleated filter material so as to identify a target pleat to be cut. The pleat counter clamps and stretches the target pleat to distinguish the target pleat among the other pleats. A punch cut station cuts the target pleat to form a filter strip having a desired number of pleats. A pleat compressor compresses the filter strips to a predetermined size and then ejects the filter strips into a suitable container or bin.

In a sheet postprocessing apparatus, an accommodation paddle increases a rate of increase in transport force generated for sheets by the accommodation paddle, in conjunction with a rate of increase in transport resistance generated for the sheets by a sheet pressing member with an increase in number of the sheets stacked on a sheet stacker.

A finisher assembly of a multifunction peripheral includes a vertically oriented stapler and a paper transport motor. When the paper transport motor rotates in the forward direction, printed pages from the print engine of the multifunction peripheral are received via a paper chute and a feed assist roller urges the printed pages into a vertical paper accumulation cache basin. Rotation of the paper transport motor also opens a biasing plate allowing the pages to freely enter the cache basin. Once all of the pages of the print job are in the cache basin, the paper transport motor rotates in the reverse direction causing the biasing plate to bias the printed pages, in the cache basin, against a registration surface of the vertically oriented stapler unit. The pages of the print job are stapled together the stapled print job is moved to the paper tray for collection by a user.