A guide member (14) has an upper surface assisting conveyance of workpieces (44) mounted on a table (12) and is arranged downstream of the table (12) in a workpiece conveyance direction. A belt drive mechanism (16) has pulleys (26a to 26d, 28a to 28b), and endless belts (32a to 32d) wound around these pulleys, and is arranged above the table (12) and the guide member (14) so as to stride over the table (12) and the guide member (14). A first opening portion is formed on a bottom portion of the belt drive mechanism (16) to generate an upward suction force. A second opening portion is formed on the upper surface of the guide member (14) to generate a downward suction force. A magnitude of the suction force generated in the first opening portion exceeds a magnitude of the suction force generated in the second opening portion.

A paper sheet storing/feeding device (e.g., escrow unit 40) includes a rotary member (e.g., drum 42) to an outer peripheral surface of which one end of a belt-shaped winding member (e.g., tapes 90, 92, 94) that winds a plurality of paper sheets one by one is connected, and a guiding unit (80, 85) that guides a paper sheet to prevent the paper sheet from sandwiching the winding member from both sides when the paper sheet is fed from the rotary member by unwinding the winding member from the rotary member.

A folding arrangement including a flap lifting assembly located at a drop conveyor discharge end and including a pivoting arm with a flap engaging surface that is movable between a first, flap-lifting position and a second, pass-through position is provided. A folding assembly includes a receiving conveyor with a receiving conveyor feed end positioned below the drop conveyor discharge end, and a folding finger above the receiving conveyor feed end. The product-substrate combination is driven by the drop conveyor into contact with the flap engaging surface in the first position to lift the flap as the product-substrate combination is discharged from the drop conveyor discharge end towards the receiving conveyor feed end, and the folding finger contacts the flap of the product-substrate combination to complete folding of the flap to a second angled position onto the product as the product-substrate combination pivots the flap engaging surface to the second position.

The invention relates to a device for receiving, transporting, and dispensing film bags, comprising a film bag magazine with multiple parallel magazine shafts and two circulating conveyor belt devices which can be driven independently of each other and which comprise film bag receiving areas arranged thereon, said conveyor belt devices circulating about two common axes. The two axes are designed to be drivable independently of each other, and each axis drives one of the two conveyor belt devices. The invention further relates to a method for receiving, transporting, and dispensing film bags by means of the device for receiving, transporting, and dispensing film bags.

In a bank-note processing machine, bank notes are guided through between two components of a checking device by means of a transport band. The transport band is led away at least partly from the checking device by means of deflection rollers to enable a better check of the bank notes and a trouble-free transport of the bank notes.

In a bank-note processing machine, bank notes are guided through between two components of a checking device by means of a transport band. The transport band is led away at least partly from the checking device by means of deflection rollers to enable a better check of the bank notes and a trouble-free transport of the bank notes.

Disclosed is an automated insert feeding system and related methods, capable of removing bulk-packaged items from a tray or other package, and separating the bulk-packaged items individually for distribution into individual packages in high speed reliable fashion. The disclosed systems can also be loaded with multiple packages of the pre-packaged items for automatic feeding into the system which allows human operators to load several packages and allow the system to work unattended, thereby reducing man-hours spend on the process.

A sheet transport system comprising an endless carrier belt that has a predetermined stiffness and is arranged to carry the sheets towards an end of a conveyer path where the sheet is separated from the carrier belt by passing this belt around a separating member that has a predetermined curvature, wherein the carrier belt runs in parallel with an endless conveyer that has a larger stiffness than the carrier belt and, at the end of the conveyer path, has a smaller curvature than the separating member.

The method serves for producing flexible packaging products, more particularly packaging bags, the packaging products being formed by welding together two film layers. In order to avoid imprecisions in the sequence of process steps, film sections (4) formed of film layers are separated from a film web (7a; 7b) and transferred to a transport device (1) where they are positively fixed at least at one edge by means of a fixing device (3). Then the film sections (4) are transported by means of the transport device (1) in a transport direction (5) to at least one welding station (12) while maintaining the positive fit, the film layers are welded together in the latter, and the film sections (4) are subsequently further transported while maintaining the positive fit.

A media sheet router moves sheets from a digital printer through the router and selectively to a plurality of finishers at full process speed. A router inlet path is aligned with the printer outlet path. Two router outlet paths are disposed at ninety degrees to the left and right of the router inlet path. The router outlet paths are each aligned with a finisher inlet path or another router. First and second turning elements are each mounted at forty-five degrees to the router inlet path and at ninety degrees to each other. Each turning element directs the sheets in a helical path to the router outlet paths. Transfer belts hold the sheets against each turning element. A bypass transfer moves the sheet to a bypass outlet path aligned with a bypass finisher inlet path. Diverters selectively direct the sheets onto the turning elements or the bypass transfer.