An object of the invention is to provide a banknote storing/feeding unit which is capable of effectively utilizing winding spaces of a drum and a reel, to increase the number of banknotes to be stored. The banknote storing/feeding unit includes the drum which winds and rewinds a banknote together with a tape, and the reel which winds and rewinds the tape on and from the drum. A guide body swinging according to winding and rewinding of the tape and the banknote on and from the drum is provided between the drum and the reel. The guide body has a guide passage that guides the tape and the banknote to be wound and rewound on the drum. The guide body swings centering on a supporting point located within a region parallel to a virtual line connecting a rotational center of the drum and a rotational center of the reel.

A paper sheet stacking mechanism 50 includes a stacking wheel 52, a roller 54 that is disposed outward from the stacking wheel 52 so as to be coaxially aligned with the stacking wheel 52 and that is rotatable about a shaft 53 at a greater angular velocity than that of the stacking wheel 52, and a transport unit that is configured to transport a paper sheet to the gap between two adjacent vanes 52b of the stacking wheel 52. The transport unit is located such that a discharge position is disposed outward from the outer periphery of the base 52a of the stacking wheel 52 and inward of the circular region defined by the tips of the vanes 52b of the stacking wheel 52 during the rotation of the stacking wheel 52, when viewed in the axial direction of the shaft 53 of the stacking wheel 52.

Systems and methods are provided for configuring media transport flow paths for directing input image receiving media, including of different types, in sheet or roll form from multiple axes to provide wider latitude in selecting particular input image receiving media and combinations of input image receiving media to support execution of a print job. The disclosed schemes are directed at using one or more stationary turn bars disposed generally at 45 in an input media transport path approaching a marking module in an image forming system to allow for sheets or sheeted materials to be positioned at 90 to the in-line input image receiving media transport path directed toward the marking module thus allowing for flexibility in selection among various sources of stacked, pallet and rolled media.

The present invention is related to a method for folding an article into three parts comprising first folding a leading end portion of the article to form a first folded article, and second folding a trailing end portion of the first folded article, wherein the first folded article is transported with a moving direction change no higher than about 45 degree.

A paper sheet stacking mechanism 50 includes a stacking wheel 52, a roller 54 that is disposed outward from the stacking wheel 52 so as to be coaxially aligned with the stacking wheel 52 and that is rotatable about a shaft 53 at a greater angular velocity than that of the stacking wheel 52, and a transport unit that is configured to transport a paper sheet to the gap between two adjacent vanes 52b of the stacking wheel 52. The transport unit is located such that a discharge position is disposed outward from the outer periphery of the base 52a of the stacking wheel 52 and inward of the circular region defined by the tips of the vanes 52b of the stacking wheel 52 during the rotation of the stacking wheel 52, when viewed in the axial direction of the shaft 53 of the stacking wheel 52.

In a method for producing a collection (20) of pre-products by inserting a first pre-product (1) into a second pre-product (3), it is provided according to the invention that a first pre-product (1) and a second pre-product (3) are provided, wherein the second pre-product (3) has a wrapping fold (4) with a fold inner side (5). The second pre-product (3) is conveyed into an insertion position, in which the second pre-product (3) is opened and faces with the fold inner side (5) toward the first pre-product (1). The first pre-product (1) is conveyed into the opened second pre-product (3) and against the fold inner side (5) so as to form the collection (20), the second pre-product (3) assumes the conveying direction of the first pre-product (1), and the collection (20) is provided for further processing.

A paper sheet stacking mechanism 50 includes a stacking wheel 52, a roller 54 that is disposed outward from the stacking wheel 52 so as to be coaxially aligned with the stacking wheel 52 and that is rotatable about a shaft 53 at a greater angular velocity than that of the stacking wheel 52, and a transport unit that is configured to transport a paper sheet to the gap between two adjacent vanes 52b of the stacking wheel 52. The transport unit is located such that a discharge position is disposed outward from the outer periphery of the base 52a of the stacking wheel 52 and inward of the circular region defined by the tips of the vanes 52b of the stacking wheel 52 during the rotation of the stacking wheel 52, when viewed in the axial direction of the shaft 53 of the stacking wheel 52.

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.

In a method for producing a collection (20) of pre-products by inserting a first pre-product (1) into a second pre-product (3), it is provided according to the invention that a first pre-product (1) and a second pre-product (3) are provided, wherein the second pre-product (3) has a wrapping fold (4) with a fold inner side (5). The second pre-product (3) is conveyed into an insertion position, in which the second pre-product (3) is opened and faces with the fold inner side (5) toward the first pre-product (1). The first pre-product (1) is conveyed into the opened second pre-product (3) and against the fold inner side (5) so as to form the collection (20), the second pre-product (3) assumes the conveying direction of the first pre-product (1), and the collection (20) is provided for further processing.

A chopping cut mechanism comprising a first driving device and a chopping cut device, the chopping cut device comprises an upper blade and the first driving device drives the upper blade to carry out reciprocating motion. The upper blade having a compaction component and the compaction component comprises a compaction part which is not lower than the upper blade edge line. A first conveying mechanism, wherein the first conveying mechanism comprises: a second driving device and a first conveying device, the second driving device drives the first conveying device for directional transport, the first conveying device is located below the upper blade.