A pickup mechanism includes a paper feeding channel, a pickup roller assembly disposed in the paper feeding channel and projecting beyond a top of the paper feeding channel, a paper tray disposed to an upstream of the pickup roller assembly, and a guiding swing arm assembly. The guiding swing arm assembly includes two guiding swing arms mounted adjacent to and spaced from two opposite sides of the pickup roller assembly. Each guiding swing arm includes a pivoting shaft, a stopping block, and an extending arm connected between the pivoting shaft and the stopping block. The two stopping blocks of the two guiding swing arms are disposed between the pickup roller assembly and the paper tray for blocking paper. An axial direction of the pivoting shaft of each guiding swing arm is deviated from a center axis direction of the pickup roller assembly.

A medium feeder includes: a path blocking member configured to rotate to switch between a blocking state that blocks a feed path for a medium fed out from a tray at a position of the guide member, and an open state that opens the feed path; and a switching unit that performs switching of the path blocking member, wherein the switching unit includes a rack configured to be displaced in a feeding direction in which a medium is fed from the tray to thereby perform switching of the path blocking member, and a pinion gear that drives the rack.

A medium discharge device includes: a discharge unit that discharges a medium; a first medium receiving tray that receives the medium discharged by the discharge unit; and a second medium receiving tray that is provided above the first medium receiving tray in a vertical direction and receives the medium discharged by the discharge unit. The second medium receiving tray is capable of changing a position between an advance position for receiving a medium, which is discharged, by causing at least an upstream zone of the tray including an upstream side end portion in a medium discharge direction to advance to a passing route of the medium from the discharge unit toward the first medium receiving tray and a retraction position to which the upstream zone retracts from the passing route.

A sheet conveyance device correcting skew of a sheet being conveyed includes: a rotational shaft extending perpendicularly to a sheet conveyance direction; conveyance rollers disposed at predefined intervals and into which the rotational shaft is inserted; gate members being coaxial with the conveyance rollers and disposed between the conveyance rollers along the rotational shaft, the gate members each having an arc-shaped part partially surrounding the rotational shaft and a stopper protruding radially outwards from the arc-shaped part; and a mounting plate elongated along the rotational shaft and being supported rotatably around the rotational shaft and holding the gate members in a same orientation. After the sheet abuts against at least one of the stoppers, the stoppers are pushed out of the conveyance path by the sheet. When the stoppers are positioned on the conveyance path, openings of the arc-shaped parts face toward a downstream side in the conveyance direction.

A sheet transport device includes a sheet storage unit that stores a sheet and that is disposed in a housing having a bottom plate such that a gap is provided between the sheet storage unit and the bottom plate, the gap extending horizontally; a sheet transport unit that feeds the sheet from the sheet storage unit and transports the fed sheet along a transport passage including a reversing transport path along which the sheet is transported downward and then upward to reverse the sheet front to back, the reversing transport path extending vertically and being connected to the gap; and a first gate unit that prevents passage of the sheet that has entered the reversing transport path when the sheet free falls and allows passage of the sheet when the sheet receives a sheet transport driving force from the sheet transport unit.

The invention relates to a stacking device (10) for placing sheet-shaped elements (P) in stacks in a forming machine (1), said stacking device (10) comprising: a movable stacking surface (11), and an actuating device (12) for moving stacking surface (11): between a retracted position and a vertical forward position in a reciprocating back-and-forth motion for stacking sheets, and between the retracted position and a stowed position to open an access to the stack of sheet-shaped elements (P), characterized in that the actuator (12) comprises cam means configured to move the stacking surface (11) upwardly in the retracted position, in a raised position to be located above the top of the sheet stack.

The invention also relates to a machine forming sheet-shaped elements comprising at least one such stacking device.

A sheet loader includes a housing and a fence. The housing has a bottom face. The fence is movable in a fence moving direction and configured to regulate a position of an end face of the sheet to be loaded in the housing. The fence includes a sliding face and a bend. The sliding face is configured to slide on the bottom face of the housing as the fence moves. The bend is disposed at an end of the sliding face in the fence moving direction and bent in a direction away from the bottom face of the housing.

The pick-up device disposed between the input tray and the feeding path and includes a Paper feeding unit for feeding the paper from the input tray; a separation roller disposed opposite to the Paper feeding unit and contacting each other; a blocking arm disposed between the input tray and the Paper feeding unit, and configured to be switchable disposed between a blocking position for blocking the paper and a feeding position for passing the paper through the feeding path; and a guiding arm, the guiding arm is disposed in the feeding path through a pivot shaft, and includes a guiding portion, the pivot shaft is located upstream of the separation roller, and the guiding portion is swingable disposed in a seam space formed by the Paper feeding unit and the separation roller; and wherein a distance from the axle of the separation roller to the guiding portion is greater than the wheel diameter of the separation roller, and the vertical distance between the paper to be fed and the guiding portion is greater than the vertical distance between the paper to be fed and the separation roller.

The present invention relates to a multi-banknote cassette with a movable stopper, and more particularly, to a multi-banknote cassette with a movable stopper, which is capable of storing various kinds of banknotes at the same time. The multi-banknote cassette may include: a stopper driver which is formed at the top of a cassette body and has a pinion gear rotated by a driving motor; and a movable stopper which has a rack gear formed at one side surface thereof and engaged with the pinion gear and is lifted/lowered vertically through a stack guide to guide an introduced banknote in the cassette body, while the pinion gear of the stopper driver is rotated. Through such a structure, various kinds of banknotes can be easily handled in one banknote cassette.

A pickup mechanism includes a paper feeding channel, a pickup roller assembly disposed in the paper feeding channel and projecting beyond a top of the paper feeding channel, a paper tray disposed to an upstream of the pickup roller assembly, and a guiding swing arm assembly. The guiding swing arm assembly includes two guiding swing arms mounted adjacent to and spaced from two opposite sides of the pickup roller assembly. Each guiding swing arm includes a pivoting shaft, a stopping block, and an extending arm connected between the pivoting shaft and the stopping block. The two stopping blocks of the two guiding swing arms are disposed between the pickup roller assembly and the paper tray for blocking paper. An axial direction of the pivoting shaft of each guiding swing arm is deviated from a center axis direction of the pickup roller assembly.