A parallel veneer standby step, a cross veneer moving step, a cross veneer positioning step, a cross veneer standby step, a parallel veneer returning step, a parallel veneer positioning step, a superimposing step, and a superimposed veneer gluing step are included. Accordingly, a superimposed veneer is obtained in which the parallel veneer and the cross veneer are bonded with a high degree of adhesion and corresponding edges of the parallel veneer and the cross veneer substantially align with each other.

To prevent deformation to relatively stiffer sheets during flipping, while ensuring reliable holding of relatively weaker sheets, a method for stacking sheets received from a printer by a sheet flipping device includes at least one slot for receiving a leading portion of a sheet. The method includes determining a respective insertion depth parameter for a first and a second sheet, wherein the second sheet has a greater stiffness than the first sheet; inserting a length of the first sheet into the at least one slot in correspondence with its respective insertion depth parameter, followed by flipping said first sheet; inserting a length (D2) of the second sheet into the at least one slot in correspondence with its respective insertion depth parameter, followed by flipping said second sheet, wherein the inserted length of the first sheet is greater than that of the second sheet.

Disclosed is a device for loading a bound product, the device holding a product without the product sagging, which has been completed by punching various objects to be bound and then binding same by means of a coil spring, reversing the moving direction to a loading location and thereby enabling neat and stable stacking in a zigzag state without having the coil springs come in contact with one another. A device for loading a bound product, according to the present invention, comprises: a supporting frame unit for providing a distance for the movement of a bound product from a binding location to a loading location; a transfer unit having upper and lower gears, which are axially mounted on one side of the frame unit, a driven gear, which is axially mounted on the other end, a moving belt, for connecting the lower gear and the driven gear, a power belt, which is connected to the upper gear, and a first driving motor, for transmitting power to the power belt; an LM guide having a rail, which is mounted on the frame unit in the length direction, and a block; a reversing unit having a supporting plate, which is fixed on the block of the LM guide and the moving belt, a pinion, of which the upper end is rotatably and axially mounted on the supporting plate, a first cylinder, for operating a rack gear that interlocks with the pinion, and a rotating plate which is fixed on the lower end of the pinion; and a holding unit having a support and a second cylinder which is mounted on the rotating plate of the reversing unit and has a pressure member coupled to the front end thereof so as to hold a bound product.

Postal sorting equipment for sorting flat mailpieces comprises a postal sorting machine, a storage-tray conveyor for conveying open-topped storage trays filled with mailpieces stacked flat, a shuttle-tray conveyor for conveying substantially L-shaped open-fronted shuttle trays, and in which the mailpieces are placed on-edge in stacks, and a tray interchanger suitable for automatically transferring the mailpieces stored flat in an open-topped storage tray to an open-fronted shuttle tray, the feed inlet comprising an unstacker with a fork-shaped magazine with tines, each of which is constituted by a motor-driven belt, the shuttle tray and the fork-shaped magazine being designed so that, by advancing towards the unstacker, the shuttle tray is engaged by the motor-driven belts of the unstacker magazine that come to be inserted under the mailpiece stack disposed on-edge in the shuttle tray, the unstacker magazine including a conveyor section that is mounted to move in elevation under the magazine tines.

Disclosed is a device for loading a bound product, the device holding a product without the product sagging, which has been completed by punching various objects to be bound and then binding same by means of a coil spring, reversing the moving direction to a loading location and thereby enabling neat and stable stacking in a zigzag state without having the coil springs come in contact with one another. A device for loading a bound product, according to the present invention, comprises: a supporting frame unit for providing a distance for the movement of a bound product from a binding location to a loading location; a transfer unit having upper and lower gears, which are axially mounted on one side of the frame unit, a driven gear, which is axially mounted on the other end, a moving belt, for connecting the lower gear and the driven gear, a power belt, which is connected to the upper gear, and a first driving motor, for transmitting power to the power belt; an LM guide having a rail, which is mounted on the frame unit in the length direction, and a block; a reversing unit having a supporting plate, which is fixed on the block of the LM guide and the moving belt, a pinion, of which the upper end is rotatably and axially mounted on the supporting plate, a first cylinder, for operating a rack gear that interlocks with the pinion, and a rotating plate which is fixed on the lower end of the pinion; and a holding unit having a support and a second cylinder which is mounted on the rotating plate of the reversing unit and has a pressure member coupled to the front end thereof so as to hold a bound product.

A sheet flipping device includes a receiving member for receiving a sheet, a flipping volume being the volume which in operation is defined by the flipping movement of the sheet, and a flipping element for flipping the sheet around an axis of rotation within the flipping volume onto the receiving member. The sheet flipping device further includes an air vortex ring generator having an air vortex ring exit nozzle defining a translational direction of a generated air vortex ring when the generated vortex ring is in operation generated from the air vortex ring exit nozzle. The air vortex ring generator is mounted such that in operation the sheet is urged onto the receiving member by the air vortex ring during the flipping motion of the sheet through the flipping volume. A sheet stacking device and a printing apparatus include the sheet flipping device.

A stacker module includes a lift table, a stacker configured to place sheets that are successively supplied thereto onto the top of a stack forming on the lift table, a controller configured to lower the lift table as the stack grows, a height-adjustable eject table, and an eject mechanism configured to transfer a completed stack from the lift table onto the eject table. The eject mechanism is height-adjustable for transferring stacks onto the eject table in different height positions of the lift table.

When using a flipping wheel to flip sheets of weak or long media, there is a risk that these sheets collapse upon themselves. To reduce this risk, a method of stacking sheets includes flipping a sheet while holding its leading edge and bringing the leading edge down towards a stack support; bringing a trailing portion of the sheet into contact with a guide member positioned over the stack support; forming an overpressure in an inner volume of the bent sheet during flipping, while its trailing portion is in contact with the guide member; and maintaining the overpressure and contact while a trailing edge of the sheet travels along the guide member.

In an example, a media handling device (100) comprises a media catcher (110) defining a first media collecting width (112) along a lateral direction. The device also comprises a first board section (120) defining a second media collecting width (122) along the lateral direction, the second media collecting width exceeding and at least partially overlapping the first media collecting width, and a second board section (130), whereby the first board section is at least partially located between the second board section and the media catcher, the first and second board sections forming an apex (125) along the second media collecting width to support media. The device further comprises an abutment (140) at a distal end of the first board section away from the apex, the abutment being located between the first board section and the media catcher.