An objective of the present disclosure is to prevent paper sheets from being folded or damaged when the paper sheets are stacked. A paper sheet stacking mechanism (banknote stacking mechanism 50) includes stacking wheels 52, rotary rollers 54, a transport mechanism 70 configured to insert a paper sheet between vanes 52b of the stacking wheels, and a guide (center guide 55) having a guide surface 551 configured to guide the paper sheet. The guide surface has a curved shape having a diameter about a rotary shaft, and the diameter gradually increases from an upstream side toward a downstream side in a rotation direction of the stacking wheels.

The invention relates to a handling device for presenting a flat piece to at least a first and a second treatment device in particular for presenting a plastic card substrate to a printer device and a flipping device. The handling device comprises an elongated backbone element; wherein the backbone element is rotatable along a longitudinal axis and has at least a first and a second angular position; a holding element configured to hold the flat piece relative to the backbone element; and a control unit, configured to control the angular position of the backbone element; wherein, when the backbone element is at the first angular position, the flat piece is at a first treatment position for the first treatment device, and when the backbone element is at the second angular position, the flat piece is at a second treatment position for the second treatment device.

This disclosure relates to a method and apparatus for taking flexible sheets off a delivery belt, such as from a scanner or copier, and restacking them in the order and orientation (face) they were originally scanned in. This requires flipping over such sheets by use of a spindle wheel with a plurality of fingers defining slots therebetween for receiving the sheets and reversing their face (flipping). By knowing the speed of the delivery belt and using a continuously spinning spindle wheel it is possible to avoid the effects of momentum on the fingers which distorts their position during stopping and starting action. Instead, the spindle wheel is in constant rotation but the speed of rotation is adjusted from a first speed, then a second tapering speed, to a third speed which is adapted to ensure that the slot between fingers is accurately presented to the leading edge as it enters the slot and does not get rejected by an accidental encounter with a finger.

A unit for applying first and second tabs, obtained from first and second webs, to a chassis web includes an applicator drum rotatable about an axis and including a main body. A plurality of carriers is movable between a lowered position close to the axis and a raised position away from the axis, each including a suction portion. A first carrier first suction and non-suction portions aligned along the axis. A second carrier includes second suction and non-suction portions aligned along the axis. The first suction portions alternate with the second non-suction portions and the first non-suction portions alternate with the second suction portions. A first system holds the first web on the applicator drum upstream of a cutting device. A second system holds the second web on the drum upstream of the cutting device.

A unit for applying first and second tabs, obtained from first and second webs, to a chassis web includes an applicator drum rotatable about an axis and including a main body. A plurality of carriers is movable between a lowered position close to the axis and a raised position away from the axis, each including a suction portion. A first carrier first suction and non-suction portions aligned along the axis. A second carrier includes second suction and non-suction portions aligned along the axis. The first suction portions alternate with the second non-suction portions and the first non-suction portions alternate with the second suction portions. A first system holds the first web on the applicator drum upstream of a cutting device. A second system holds the second web on the drum upstream of the cutting device.

An objective of the present disclosure is to prevent paper sheets from being folded or damaged when the paper sheets are stacked. A paper sheet stacking mechanism (banknote stacking mechanism 50) includes stacking wheels 52, rotary rollers 54, a transport mechanism 70 configured to insert a paper sheet between vanes 52b of the stacking wheels, and a guide (center guide 55) having a guide surface 551 configured to guide the paper sheet. The guide surface has a curved shape having a diameter about a rotary shaft, and the diameter gradually increases from an upstream side toward a downstream side in a rotation direction of the stacking wheels.