In accordance with an embodiment, a sheet processing apparatus comprises a first tray, a second tray, a third tray, a lower supporting plate, a drive section and a control device. The second tray is located at the lower part of the first tray. The third tray is located at a downstream side with respect to the second tray in a sheet conveyance direction. The lower supporting plate can support the sheet from the lower part. The drive section drives the lower supporting plate. The control device controls the drive section to arrange the lower supporting plate at the downstream side with respect to a conveyance starting point of the sheet in the sheet conveyance direction in a case of skipping the first tray and the second tray to convey the sheet to the third tray.

A post-processing apparatus for post-processing paper discharged from an image forming apparatus comprises: a paper discharging roller for conveying both first and second paper sequentially discharged from an image forming apparatus to an intermediate loading part; a main paddle part for conveying the first and second paper loaded on the intermediate loading part to a compiling region; a reverse roller for conveying, together with the main paddle part, the first and second paper to the compiling region; and a binding part for processing the first and second paper conveyed to the compiling region, the paper discharging roller allows the first paper to stand by on a standby path, and conveys the first and second paper to the intermediate loading part in a state in which the leading end of the first paper protrudes further than the leading end of the second paper.

A sheet processing apparatus includes a tray, a stapler, a first discharge section, and a controller. A sheet on which an image is formed is stacked on the tray. The stapler is arranged at an upstream side in a first direction which is a sheet discharge direction with respect to the tray, and executes a binding processing on the sheet. The first discharge section moves from a reference position at the upstream side of the tray to the first direction while supporting the sheet, and executes a discharge processing of the sheet. The controller enables the first discharge section to move from the reference position to a downstream side in the first direction and stop at a processing position and drives the stapler to execute the binding processing on the sheet supported by the first discharge section.

A binding device includes a first pressing member that presses a recording-medium stack from one surface side of the recording-medium stack, a second pressing member disposed at a position opposed to the first pressing member to press the recording-medium stack from the other surface side of the recording-medium stack, and a reduction part provided in at least one pressing member of the first pressing member and the second pressing member to reduce creases in recording media of the recording-medium stack in a binding operation when a number of the recording media in the recording-medium stack is smaller than a maximum number of recording media to be bound by the first pressing member and the second pressing member.

A sheet transporting mechanism transports a sheet from a storage tray to a stacking tray, and includes: a first transporter that moves between initial and first positions to transport the sheet from the initial position toward the stacking tray; a second transporter that transports the transported sheet by the first transporter to the stacking tray; a single motor that drives the first and second transporters; a guide rail that guides movement of the second transporter; a first transmission gear that transmits a driving force of the single motor to move the first transporter between the initial and first positions; a second transmission gear that transmits the driving force of the single motor to move the guide rail in an upward and downward direction; and a third transmission gear that transmits the driving force of the single motor to allow the second transporter to be guided by the guide rail.

The present invention relates to a stacker module for a folder-gluer machine, the stacker module being located downstream of a transfer module in a direction of transportation of the folder-gluer machine and configured to receive folding boxes from a conveyor in the transfer module. The stacker module comprises a loading surface configured to receive a plurality of folding boxes in order to form a stack and to descend vertically as the number of folding boxes on the loading surface increases, and a linearly movable ejector configured to eject the stack from the loading surface. A front abutment guide configured to move between an abutment and a clearing position to retain and release the stack.

A method for generating decks of sheet elements (18) comprises the steps of positioning a set of numerous sheet elements (18) onto a transport surface of a transport device (30) to partly overlap in transport direction (T). The set of overlapping sheet elements (18) is moved against a stop member (44). The stop member (44) is moved in the transport direction (T) with a lower velocity than a velocity of the transport surface. By maintaining displacement of sheet elements (18) which are not yet contacting stop member (44) all sheet elements are shifted towards stop member (44) to define a deck. The method is carried out by a corresponding device.

A post-processing unit in an image forming apparatus includes a stapler, an exit tray, a height detector, and a shifting controller. The stapler staples a sheet sheaf. The exit tray is configured to be elevated and lowered and to receive the sheet sheaf stapled by the stapler. The height detector detects a height of the sheet sheaf on the exit tray. The shifting controller shifts the sheet sheaf to be ejected in a situation in which the stapler staples one location at a trailing end of the sheet sheaf in a conveyance direction of the sheet sheaf. The shifting controller shifts the sheet sheaf in a front-rear direction, which is a direction perpendicular to a vertical direction and to the conveyance direction of the sheet sheaf, so that the stapled location in the sheet sheaf on the exit tray matches a detection point of the height detector.

A sheet processing apparatus includes a conveying portion, a stack portion on which sheets conveyed by the conveying portion are stacked, a first regulating portion regulating a position of a sheet bundle stacked on the stack portion in a crossing direction, a second regulating portion regulating a position of a sheet bundle on the stack portion in a conveying direction, a first binding device moved in the crossing direction and binding a corner portion of a sheet bundle by a staple, a second binding device binding a corner portion of a sheet bundle without a staple, and a controller positioning the first binding device and binding a corner portion of a sheet bundle by the first binding device. The controller also moves the second binding device and binds a corner portion of a sheet bundle without a staple by the second binding device.

The present invention is to provide a processing unit which can move smoothly to accurate position in a proper posture. The processing unit is provided with a support mechanism that supports a processing unit 26 so as to allow the processing unit 26 to be moved to a sheet processing position (processing tray) 24. The support mechanism includes the processing unit 26 and first and second support portions 50 and 55 that support the processing unit 26. The first and second support portions 50 and 55 apply, to different positions (j and k) of the processing unit 26 which are spaced from each other, a support force Fa acting from below to above (in a direction opposite to a gravity acting direction) and a support force Fb acting from above to below (in a direction same as the gravity acting direction), respectively.