The invention relates to an installation for printing and die-cutting laminar bodies, which comprises a digital printing station (1) for printing at least one face of the laminar bodies, and a die-cutting station (2) for die-cutting the laminar bodies coming from the digital printing station (1), comprising first conveying means (3) for moving the laminar bodies (P) positioned between the digital printing station (1) and a redirection station (5), and second conveying means (4) for moving the laminar bodies between the outlet of the redirection station (5) and the die-cutting station (2), The digital printing station defines an axial direction of travel and the die-cutting station (2) defines an axial direction of travel that is perpendicular to the axial direction of travel of the laminar bodies in the digital printing station (1), such that an L-shaped path of the laminar bodies (P), viewed in the plan view, is defined.

In one example in accordance with the present disclosure, a sheet transport device is described. The sheet transport device includes a pickup roller to insert a sheet into a sheet path. A pair of separation rollers of the sheet transportation device form a nip that advances the sheet along the sheet path. A first separation shaft on which a first separation roller is disposed rotates in a first direction as the sheet is advanced and a second separation shaft on which a second separation roller is disposed also rotates in the first direction as the sheet is advanced. The second separation roller is driven in a second direction via a torque limiter. A motor rotates the shafts. A one-way clutch is disposed on the second separation shaft to disengage the second separation shaft from the motor when the motor is operating in a reverse mode.

Method of manipulating a sheet of fiber reinforced material built up with parallel longitudinally oriented fibers embedded in a thermoplastic matrix material, wherein at least one face of the sheet is engaged by a friction element that extends substantially transversely to the orientation of the fibers, and that exerts friction onto the face in a direction substantially along the orientation of the fibers. And a device for moving sheets of fiber reinforced material having parallel longitudinally oriented fibers embedded in a thermoplastic matrix material, in particular sheets presenting anisotropic stiffness is disclosed. The device comprises a conveying path for conveying sheets of fiber reinforced material in a direction substantially along the orientation of the fibers, and a drive element arranged substantially transversely to the conveying path to in use engage a face of a sheet of fiber reinforced material to be conveyed along the path, and arranged to exert friction onto the face in a direction substantially along the orientation of the fibers. The device may further include a guide element arranged substantially transversely to the conveying path to in use engage the opposite face of the sheet of fiber reinforced material to be conveyed along the path, the drive element and the guide element being arranged to envelope the conveying path.

Method of manipulating a sheet of fiber reinforced material built up with parallel longitudinally oriented fibers embedded in a thermoplastic matrix material, wherein at least one face of the sheet is engaged by a friction element that extends substantially transversely to the orientation of the fibers, and that exerts friction onto the face in a direction substantially along the orientation of the fibers. And a device for moving sheets of fiber reinforced material having parallel longitudinally oriented fibers embedded in a thermoplastic matrix material, in particular sheets presenting anisotropic stiffness is disclosed. The device comprises a conveying path for conveying sheets of fiber reinforced material in a direction substantially along the orientation of the fibers, and a drive element arranged substantially transversely to the conveying path to in use engage a face of a sheet of fiber reinforced material to be conveyed along the path, and arranged to exert friction onto the face in a direction substantially along the orientation of the fibers. The device may further include a guide element arranged substantially transversely to the conveying path to in use engage the opposite face of the sheet of fiber reinforced material to be conveyed along the path, the drive element and the guide element being arranged to envelope the conveying path.

A method for supplying plate elements to a machine for processing the plate elements, from an initial pile of elements, the method includes: pushing a first batch of plate elements, from the top of the pile, downstream until the first batch comes at a storage capable of storing the first pushed batch, and simultaneously, displacing the storage downstream over a distance corresponding to the length of the first batch to separate the first batch from the pile; and thereafter transferring the elements of the first batch one after the other to the machine.

A method for supplying plate elements to a machine for processing the plate elements, from an initial pile of elements, the method includes: pushing a first batch of plate elements, from the top of the pile, downstream until the first batch comes at a storage capable of storing the first pushed batch, and simultaneously, displacing the storage downstream over a distance corresponding to the length of the first batch to separate the first batch from the pile; and thereafter transferring the elements of the first batch one after the other to the machine.

Disclosed are a cash box and a banknote processing device using the same. The cash box includes: a guiding plate, configured to guide a banknote to enter a banknote storage chamber; a pickup roller, configured to output the banknote; and a sensor, configured to detect a position of the guiding plate and a position of the pickup roller. When the guiding plate is in a banknote feeding position or the pickup roller is in a banknote pickup position, the sensor outputs a first signal. When the guiding plate deviates from the banknote feeding position and the pickup roller deviates from the banknote pickup position, the sensor outputs a second signal, wherein the first signal is different from the second signal.

Disclosed are a cash box and a banknote processing device using the same. The cash box includes: a guiding plate, configured to guide a banknote to enter a banknote storage chamber; a pickup roller, configured to output the banknote; and a sensor, configured to detect a position of the guiding plate and a position of the pickup roller. When the guiding plate is in a banknote feeding position or the pickup roller is in a banknote pickup position, the sensor outputs a first signal. When the guiding plate deviates from the banknote feeding position and the pickup roller deviates from the banknote pickup position, the sensor outputs a second signal, wherein the first signal is different from the second signal.

A pusher plate stacking bin apparatus is provided for a valuable media depository. The apparatus comprising a pusher plate driven by a rack and pinion apparatus to stack a media item that is in a final position within the apparatus onto a media stacking platform. The media item is urged into the final position such that a trailing edge of the media item overhangs and rests on a fixed media guide and such that a leading edge of the media item overhangs and rests on a hinged media guide with a bottom surface of the media item elevated above the media stacking platform. The rack and pinion apparatus drives the plate past the media guides causing the hinged media guide to drop and the media item to fold along the leading edge as the media item is stacked onto the platform.

A pusher plate stacking bin apparatus is provided for a valuable media depository. The apparatus comprising a pusher plate driven by a rack and pinion apparatus to stack a media item that is in a final position within the apparatus onto a media stacking platform. The media item is urged into the final position such that a trailing edge of the media item overhangs and rests on a fixed media guide and such that a leading edge of the media item overhangs and rests on a hinged media guide with a bottom surface of the media item elevated above the media stacking platform. The rack and pinion apparatus drives the plate past the media guides causing the hinged media guide to drop and the media item to fold along the leading edge as the media item is stacked onto the platform.