JP2023020761A - Sheet processor - Google Patents

Abstract

To adequately discharge a sheet while suppressing enlargement of a device.SOLUTION: A raking part 240 transfers a sheet placed on a processing tray 220 toward a rear end regulation member 290. The raking part 240 moves between a first position above a pre-processing nip part 211a between a pre-processing roller 211 and a conveyor belt 212 and a second position that contacts a top face of the sheet placed on the processing tray 220 and can transfer the sheet toward the rear end regulation member 290. The raking part 240 sandwiches the sheet placed on the processing tray 220 between itself and a discharge belt 260 at the second position.SELECTED DRAWING: Figure 28

Description

The present invention relates to a sheet processing apparatus that performs predetermined processing such as stapling on sheets.

In the sheet processing apparatus, sheets conveyed from a conveying path are placed on a processing tray, the sheets on the processing tray are subjected to processing such as stapling, and the sheets are discharged from the processing tray to a stacking tray. As such a sheet processing apparatus, there is conventionally known a sheet processing apparatus having a conveying means for conveying a sheet placed on a processing tray and abutting the trailing edge of the sheet against a trailing edge regulating plate (Patent Document 1). ).

In addition to this conveying means, there is also disclosed in Japanese Unexamined Patent Application Publication No. 2002-200013 that a sheet placed on a processing tray is brought into contact with the upper surface of the sheet and conveyed toward the trailing end regulating plate in cooperation with the above-described conveying means. This document describes a configuration including forward and reverse rotating rollers having a function of discharging sheets placed on a processing tray toward a stacking tray. The forward and reverse rotating rollers disclosed in Japanese Patent Laid-Open No. 2002-200001 are positioned at a position spaced apart from the processing tray when the sheet is conveyed from the conveying path to the processing tray, and after the sheet is placed on the processing tray, the forward and reverse rotation rollers are positioned at a distance from the processing tray. is lowered to a position where it abuts on the upper surface of the substrate, and the bidirectional transport is performed as described above.

JP 2011-16649 A

However, when a sheet bundle consisting of a plurality of sheets is discharged from a processing tray or when a sheet having a low friction coefficient on the surface is discharged by the forward/reverse rotating rollers as described in Patent Document 1, the forward/reverse rotation rollers are used. It is required to secure the conveying force by bringing the rollers into strong contact with the surface of the sheet. However, in the case of such a configuration, it is necessary to ensure the strength of the supporting member for supporting the forward and reverse rotating rollers, etc., and the size of the device increases. Further, when the roller is brought into strong contact with the front surface of the sheet, there is a risk that the image on one of the stacked sheets is transferred to the rear surface of the other sheet, which is called show-through.

A sheet processing apparatus according to the present invention comprises a conveying rotator pair that nips a sheet at a nip portion and conveys it in a predetermined direction, a processing tray on which the sheet conveyed by the conveying rotator pair can be placed, and the processing tray. regulating means for regulating the upstream end of the placed sheet in the predetermined direction; transfer means for transferring the sheet placed on the processing tray toward the regulating means; a processing means for performing a predetermined process on the sheet whose upstream end in the predetermined direction is regulated by means; a discharge belt capable of discharging the sheet placed on the processing tray downstream in the predetermined direction; A first position located above the nip portion of the conveying rotor pair, and a second position where the upper surface of the sheet placed on the processing tray can be brought into contact with the sheet and the sheet can be transported toward the regulating means. and a moving means for moving between the second position, and the transport means clamps the sheet placed on the processing tray between the discharge belt and the second position.

Further, the sheet processing apparatus of the present invention includes a conveying rotator pair that nips a sheet at a nip portion and conveys it in a predetermined direction; a processing tray on which the sheet conveyed by the conveying rotator pair can be placed; trailing edge dropping means for dropping the upstream end of the sheet conveyed by the pair of rotating bodies toward the processing tray; regulation means for regulating the upstream end of the sheet placed on the processing tray in the predetermined direction; a processing unit that performs a predetermined process on the sheet placed on the processing tray and whose upstream end in the predetermined direction is regulated by the regulating unit; and a sheet that is placed on the processing tray and can be discharged downstream in the predetermined direction. a first position above the nip portion of the conveying rotating body pair, and a second position abutting on the upper surface of the sheet placed on the processing tray. and a moving means for moving between the sheets, wherein the trailing edge dropping means clamps the sheet placed on the processing tray between itself and the discharge belt at the second position.

According to the present invention, sheets can be discharged appropriately while suppressing an increase in the size of the apparatus.

1 is a cross-sectional view of a schematic configuration of an image forming system according to an embodiment; FIG. 1 is a schematic configuration perspective view of a sheet processing apparatus according to an embodiment; FIG. 1A and 1B are schematic diagrams of a sheet processing apparatus according to an embodiment as viewed from above; FIG. 4A and 4B are schematic diagrams showing (a) a first example, (b) a second example, and (c) a third example of a sheet nip position between a scraping belt and a discharge belt according to the embodiment; FIG. 8 is a schematic diagram showing another example of the support structure of the raking belt according to the embodiment, showing (a) a state where there are few sheets on the processing tray and (b) a state where there are many sheets on the processing tray. The perspective view which shows a part of drive structure which concerns on embodiment. FIG. 4A is a side view of a first drive configuration of a pre-treatment roller according to an embodiment, showing (a) a state where nip pressure is applied and (b) a state where nip pressure is released; The perspective view which shows a part of drive structure which concerns on embodiment. FIG. 4 is a perspective view showing the drive structure of the scraping belt and the trailing edge dropping member according to the embodiment; 4A and 4B are perspective views showing the operation of the discharge roller according to the embodiment, in which (a) the discharge roller is at the retracted position, and (b) the discharge roller is at the contact position; FIG. 11 is a perspective view showing the operation of the scraping belt and the trailing edge dropping member according to the embodiment, in which (a) the scraping belt and the trailing edge dropping member are in the first position, and (b) the scraping belt and the trailing edge dropping member are shown; 5A and 5B each show a state in which the member is in the second position; FIG. FIG. 10 is a perspective view showing the operation of the scraping belt and the trailing edge dropping member according to the embodiment, in which (a) the scraping belt and the trailing edge dropping member are in the second position, and (b) the scraping belt and the trailing edge dropping member are shown; 5A and 5B each show a state in which the member has returned from the second position to the first position; FIG. FIG. 7 is a diagram for explaining another example of the support structure of the discharge rollers of the embodiment; 4 is a table showing the correspondence relationship between each motor and each configuration of the sheet processing apparatus according to the embodiment; 2 is a block diagram showing the control configuration of the sheet processing apparatus according to the embodiment; FIG. 4 is a flowchart showing an example of the control flow of the sheet processing apparatus according to the embodiment; 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. . 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, and FIG. . 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, and FIG. Pattern diagram. 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. Saw schematic. 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, and FIG. . (a) Schematic view from above, (b) side view of the sheet processing apparatus showing a state in which the leading edge of the sheet reaches the pre-processing roller in a shift mode (alignment priority) for large sheets according to the embodiment. Schematic diagram viewed from FIGS. 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, showing a state after the trailing edge of a sheet has passed a pre-processing roller in a shift mode (alignment priority) for a large sheet according to the embodiment; FIGS. ) Schematic view viewed from the side. (a) Schematic view of the sheet processing apparatus as viewed from above, showing a state in which the sheet is nipped between the scraping belt and the discharge roller and the discharge belt in the shift mode (alignment priority) for large sheets according to the embodiment, ( b) Schematic view seen from the side. (a) Schematic view from above, (b) side view of the sheet processing apparatus according to the embodiment, showing a state in which the sheet abuts against the trailing edge regulating member in a shift mode (alignment priority) for large sheets. Schematic diagram viewed from 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, and FIG. figure. (a) Schematic view from above, (b) Schematic view from side of the sheet processing apparatus showing a state in which sheet shifting is completed in a shift mode (alignment priority) for large sheets according to the embodiment. figure. 1A and 1B are schematic diagrams of the sheet processing apparatus according to the embodiment, showing a state in which sheets are discharged to a stacking tray in a shift mode (alignment priority) for large sheets, as viewed from above; FIG. Schematic diagram. 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. 1A and 1B are schematic diagrams of the sheet processing apparatus as seen from above, and FIG. 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above and FIG. 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, and FIG. figure. (a) Schematic view of the sheet processing apparatus as seen from above, (b) Schematic view of the sheet processing apparatus, showing a state in which the second sheet is abutted against the trailing edge regulating member in the stapling mode according to the embodiment; figure. 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, and FIG. Pattern diagram. 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above and FIG. FIG. 11A is a schematic top view of the sheet processing apparatus, showing a state in which a stapled sheet bundle is nipped between a raking belt and an ejection roller, and an ejection belt in a stapling mode according to the embodiment; (b) Schematic diagram seen from the side. 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, and FIG. figure. 1A and 1B are schematic diagrams of a sheet processing apparatus as viewed from above, and FIG. figure. 4A and 4B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, and FIG. Saw schematic. 4A and 4B are schematic diagrams of the sheet processing apparatus as seen from above, and FIG. 1A and 1B are schematic diagrams of the sheet processing apparatus as viewed from above, showing a state in which the trailing edge of a sheet stacked on a stacking tray is pressed by a sheet pressing belt in a sheet discharging operation according to the embodiment; FIG. The schematic diagram seen from the side.

An embodiment will be described with reference to FIGS. 1 to 46. FIG. First, the schematic configuration of the image forming system of this embodiment will be described with reference to FIG.

[Image forming system]
FIG. 1 is a cross-sectional view showing a schematic configuration of an image forming system according to this embodiment. The image forming system 1000 has an image forming apparatus 100 , a punch unit 150 and a sheet processing apparatus 200 . The image forming apparatus 100 is a copying machine, a printer, a facsimile machine, a multifunction machine having a plurality of these functions, or the like, and forms an image on a sheet such as paper or a plastic sheet. In this embodiment, an electrophotographic printer is used, and a sheet on which a toner image is formed is discharged from the first discharge section 101 or the second discharge section 102 . Note that the image forming apparatus 100 may be an inkjet image forming apparatus.

In the image forming apparatus of the present embodiment, although detailed illustration is omitted, the image forming unit 103 forms a toner image on a sheet. Briefly, an electrostatic latent image is formed on the photosensitive drum by charging the surface of the photosensitive drum and exposing the surface. Then, this electrostatic latent image is developed with a developer by a developing device to form a toner image. The toner image formed on the photosensitive drum is transferred to a sheet, and is fixed to the sheet by being heated and pressurized by a fixing device. The sheet on which the toner image is fixed passes through the conveying path 104 and is sent to the first discharge section 101 or the second discharge section 102 .

Further, the image forming apparatus 100 of the present embodiment includes an image forming apparatus main body 110 having an image forming section 103, a conveying path 104, a first discharging section 101 and a second discharging section 102, and a An image reading unit 120 is provided. The image reading unit 120 reads an image on a document and sends the read image signal to the image forming apparatus main body 110 . The image forming apparatus main body 110 includes a first housing portion 111 in which the image forming portion 103 is arranged, and a second housing portion in which a part of the transport path 104, the first discharge portion 101 and the second discharge portion 102 are arranged. 112 , and the second housing portion 112 is provided above the first housing portion 111 . The image reading section 120 is provided above the second housing section 112 .

With this configuration, the present embodiment has a torso space 130 surrounded by the first housing section 111 , the second housing section 112 and the image reading section 120 . Then, the sheet is discharged from the first discharge portion 101 or the second discharge portion 102 into the body interior space 130 . In addition, the punch unit 150, the sheet processing device 200, and the like can be detachably attached to the space 130 inside the body. In this embodiment, the image forming system 1000 is configured by mounting the punch unit 150 and the sheet processing apparatus 200, but either one or another sheet processing apparatus may be mounted. .

The punch unit 150 is connected to the first discharge section 101 and can receive the sheet discharged from the first discharge section 101 and punch the sheet. The sheet processing apparatus 200 is connected to the sheet discharge section of the punch unit 150 and receives sheets discharged from the punch unit 150 . Although the details will be described later, the sheet can be subjected to a predetermined process such as stapling. The sheet can be delivered to the sheet processing apparatus 200 without being punched by the punch unit 150, and the sheet can be discharged from the sheet processing apparatus 200 without being subjected to predetermined processing. The sheet discharged from the second discharge section 102 is discharged onto the sheet mounting surface 160 above the punch unit 150 and the sheet processing apparatus 200 .

Rails 131 are arranged in the body space 130 along the left-right direction in FIG. It is also possible to omit the punch unit 150 and directly connect the sheet processing apparatus 200 to the first discharge section 101 . In addition, by making the punch unit 150 and the sheet processing apparatus 200 detachable in this way, it is possible to clear sheet jams.

For example, when the sheet is jammed at the first discharge portion 101, the punch unit 150 and the sheet processing apparatus 200 are pulled out in the direction of the arrow α1 to expose the first discharge portion 101. FIG. Further, when a sheet jam occurs in the punch unit 150, only the sheet processing apparatus 200 is pulled out in the direction of the arrow α1 to expose the punch unit 150. FIG. When the punch unit 150 and the sheet processing apparatus 200 are attached to the image forming apparatus 100, they are pushed in the direction of the arrow α2. As described above, in this embodiment, since the sheet processing apparatus 200 is arranged in the internal space 130 of the image forming apparatus 100, the sheet processing apparatus 200 is required to be downsized.

[Sheet processing device]
The configuration of the sheet processing apparatus 200 of this embodiment will be described with reference to FIGS. 2 to 15. FIG. First, the overall configuration of the sheet processing apparatus 200 will be described with reference to FIGS. 2 and 3A and 3B.

[Overall Configuration of Sheet Processing Apparatus]
The sheet processing apparatus 200 includes a conveying path 210, a processing tray 220, a discharge roller (nip member) 230, a scraping section 240, a trailing edge dropping member 250, a discharge belt (bundling belt) 260, an alignment section 270, a return member 280, It has a trailing end regulating member 290, a stacking tray 300, a standing surface 310, a sheet pressing belt 320, and the like. A sheet received from the image forming apparatus 100 or the punch unit 150 is conveyed to the conveying path 210 .

Sheets conveyed from the conveying path 210 are discharged directly to the stacking tray 300 or placed on the processing tray 220 depending on the sheet processing mode. Direct discharge to the stacking tray 300 means discharging the sheet to the stacking tray 300 without reversely conveying the sheet to a position where stapling can be performed on the processing tray 220 . In other words, the sheet processing apparatus 200 has a mode in which sheets stapled by the stapling unit 400 are discharged onto the stacking tray 300 and a mode in which sheets are discharged onto the stacking tray 300 without being stapled by the stapling unit 400 . have. In this embodiment, the sheets can be aligned by the alignment section 270 without being placed on the processing tray 220 . Also, the processing tray 220 can also align the sheets, and the sheets placed on the processing tray 220 can be stapled by the stapling unit 400 . Also, the sheet or sheet bundle placed on the processing tray 220 can be discharged to the stacking tray 300 by the discharge belt 260 or the like. The configuration of each unit will be described in detail below.

[Conveyance path]
A conveying path 210 is a path for conveying a sheet in a predetermined direction, and includes a pre-processing roller 211 as a first rotating body, a conveying belt 212 as a second rotating body, and an upstream roller 212 as a third rotating body. A roller 213 and a knurled belt 214 are arranged. These are spaced apart in the sheet width direction (direction of arrow γ in FIG. 3A (vertical direction)) that intersects the conveying direction of the sheet (predetermined direction, direction of arrow β in FIG. 3A (horizontal direction)). are arranged in pairs so that

The conveying belt 212 is an endless belt arranged along the entire predetermined direction of the conveying path 210 so as to support the lower surface of the sheet received by the sheet processing apparatus 200 . The conveying belt 212 is stretched over a pair of rollers 212a and 212b, and is rotated by driving one of the rollers 212a. An upstream roller 213 is arranged at the upstream end of the conveying belt 212 in a predetermined direction. transport.

A pre-processing roller 211 is arranged at the downstream end of the conveying belt 212 in a predetermined direction, and the pre-processing roller 211 and the conveying belt 212 form a pre-processing nip portion 211a in which a sheet can be nipped and conveyed. Then, the sheet is nipped by the pre-processing nip portion 211 a and conveyed in a predetermined direction, and the sheet is discharged from the conveying path 210 . In this embodiment, the pre-treatment roller 211 and the conveying belt 212 constitute a pair of conveying rotators and conveying means. As will be described later, the pre-processing roller 211 can change the contact pressure (nip pressure) with respect to the conveying belt 212 .

The pre-processing roller 211 is rotationally driven in the same manner as the conveying belt 212, but since the conveying belt 212 is rotationally driven, the pre-processing roller 211 may be configured to follow the conveying belt 212 to rotate without being rotationally driven. Further, in the present embodiment, the conveying path 210 is composed of a plurality of rollers and a conveying belt, but the conveying path may be configured such that a plurality of spheres are arranged above the conveying belt so as to be rotatable in any direction. . In this configuration, as will be described in detail later, it is possible to shift the sheet even when there is a sheet in the conveying path without adjusting the nip pressure such as reducing the nip pressure of the pre-processing roller 211 . Become.

The knurled belt 214 is coaxial with the downstream roller 212a on which the conveying belt 212 is stretched, and is rotatable together with the roller 212a. Such a knurled belt 214 is provided so as to protrude further downstream than the downstream end of the conveying belt 212 in a predetermined direction. This makes it difficult for the end (the upstream end in the predetermined direction) to remain in the pre-processing nip portion 211a.

[Processing tray]
The processing tray 220 is arranged downstream of the conveying path 210 in the sheet conveying direction and below the conveying path 210 in the vertical direction. Further, the processing tray 220 is inclined with respect to the horizontal plane so that the upstream side in a predetermined direction is lower than the downstream side. The processing tray 220 is capable of placing sheets conveyed from the conveying path 210 and stacking a plurality of sheets. movement (sheet shift) is performed. Further, at the upstream end of the processing tray 220 in a predetermined direction, a rear end regulating member 290 is arranged as a regulating means and processing side regulating means for regulating the upstream end (rear end) of the sheet placed on the processing tray 220 in a predetermined direction. It is

Further, a stapling unit 400 as processing means is arranged upstream of the processing tray 220 in a predetermined direction. The stapling unit 400 performs stapling as a predetermined process on the sheet bundle that has undergone widthwise alignment and rear end regulation on the processing tray 220 . The stapling unit 400 can change the stapling position with respect to the sheet bundle, and moves according to the stapling position. Note that the predetermined process may be punching or other process other than stapling. The sheet or sheet bundle placed on the processing tray 220 is discharged onto the stacking tray 300 by the discharge roller 230, the scraping portion 240, and the discharge belt 260, as will be described later.

[Ejection belt]
The discharge belt 260 and the discharge roller 230 form a pair of discharge rotors that sandwich and convey the sheet, and discharge means. The discharge belt 260 is stretched by at least two tension rollers 261 and 262 . That is, in the present embodiment, the discharge belt 260 is stretched by two tension rollers 261 and 262, but the number of tension rollers that stretch the discharge belt 260 may be three or more. Further, in this embodiment, three ejection belts 260 are arranged at positions spaced apart in the width direction of the sheet. Of these three discharge belts 260, the center discharge belt 260 is positioned so that it can pinch the sheet with a scraping portion 240, which will be described later. are arranged at positions where they can be held.

The discharge belt 260 is arranged along a predetermined direction, rotates when the tension roller 261 is rotationally driven, and conveys the sheet or sheet bundle on the processing tray 220 toward the stacking tray 300 . That is, the tension roller 261 is a drive roller that drives the discharge belt 260 . As long as the sheet or sheet bundle on the processing tray 220 can be conveyed toward the stacking tray 300, the discharge belt may be replaced with another rotating member such as a discharge roller.

[Scraping part]
The transporting means, the processing-side transporting means, and the raking portion 240 serving as the dropping member transport the sheet placed on the processing tray 220 toward the trailing end regulating member 290 . The scraping portion 240 contacts the upper surface of the sheet placed on the processing tray 220 at a first position located vertically above the pre-processing nip portion 211 a where the sheet is nipped between the pre-processing roller 211 and the conveying belt 212 . It is movable between a second position in which the sheet can be transported toward the trailing end regulating member 290 in contact therewith.

The raking portion 240 pinches the sheet placed on the processing tray 220 between itself and the discharge belt 260 at the second position. The position where the sheet is nipped by the raking portion 240 and the discharge belt 260 is upstream in a predetermined direction from the position where the sheet is nipped between the discharge roller 230 and the discharge belt 260, which will be described later. That is, the raking portion 240 is located at the second position between the pre-processing roller 211 and a position (discharge nip portion) at which the sheet is nipped by the discharge roller 230 and the discharge belt 260, which will be described later.

Such a raking portion 240 is driven to rotate in both forward and reverse directions, and can convey the sheet on the processing tray 220 toward the trailing edge regulating member 290, that is, upstream in a predetermined direction, as described above. Together with the discharge belt 260, the sheet placed on the processing tray 220 can be conveyed downstream in a predetermined direction. That is, the scraping unit 240 includes a scraping belt 240a as described later, and the scraping belt 240a can be rotated in both forward and reverse directions. At the second position, the sheet is brought into contact with the sheet on the processing tray 220 , and the sheet is conveyed toward the trailing edge regulating member 290 by rotating the scraping belt 240 a in the forward direction. On the other hand, the sheet or sheet bundle on the processing tray 220 is conveyed toward the stacking tray 300 by rotating the scraping belt 240a in the opposite direction.

A sheet or a sheet bundle placed on the processing tray 220 is nipped by a discharge roller 230 and a discharge belt 260, which will be described later, and discharged to the stacking tray 300. There is a possibility that the bundle cannot be ejected reliably. Conventionally, the trailing edge regulating member 290 is moved to the sheet stack ejection side to assist the ejection of the sheet bundle. 290 does not move in the direction of discharging the sheet bundle. Therefore, in the present embodiment, the sheet bundle placed on the processing tray 220 is conveyed toward the stacking tray 300 by the raking unit 240 in order to assist in discharging the sheet bundle.

In particular, in the present embodiment, the raking portion 240 is positioned between the pre-processing roller 211 and the discharge nip portion in the predetermined direction at the second position, so that the sheet on the processing tray 220 is more driven. easy to do That is, the downstream side of the sheet on the processing tray 220 hangs down from the processing tray 220 toward the stacking tray 300 . Therefore, when the sheet is nipped at the discharge nip portion, the downstream side in the predetermined direction hangs down from the discharge nip portion, and the upstream side floats. Therefore, in the present embodiment, the portion of the sheet on the processing tray 220 that floats on the upstream side of the discharge nip portion is pressed against the scraping portion 240, thereby efficiently transmitting the drive of the scraping portion 240 to the sheet. Assistance for sheet ejection can be performed efficiently.

Further, the raking portion 240 sandwiches the sheet or the sheet bundle placed on the processing tray 220 between itself and the discharge belt 260 at the second position. That is, the upper surface of the sheet is pressed by the raking portion 240 at a position facing the discharge belt 260 with the sheet or sheet bundle sandwiched therebetween. Therefore, the force for conveying the sheet or sheet bundle by the discharge belt 260 can be increased. Furthermore, if the raking portion 240 is brought into contact with the sheet at a position as close to the discharge nip as possible, the assisting by the raking portion 240 can be performed for a longer time.

The scraping section 240 has a scraping belt 240a as a transfer belt and at least two rollers 240b and 240c on which the scraping belt 240a is stretched. That is, in the present embodiment, the scraping belt 240a is stretched by two rollers 240b and 240c, but the number of rollers that stretch the scraping belt 240a may be three or more. The scraping portion 240 can contact the sheet placed on the processing tray 220 with the stretched surface of the scraping belt 240a stretched by the two rollers 240b and 240c at the second position. That is, the raking portion 240 can contact the sheet on the processing tray 220 with a large contact area, thereby facilitating transmission of the drive in the conveying direction to the sheet. In other words, by increasing and stabilizing the surface in contact with the sheet, the conveying efficiency is improved, so the contact pressure can be reduced. As a result, it is possible to reduce the occurrence of damage during sheet conveyance.

Here, in the present embodiment, the contact position relationship between the scraping belt 240a and the discharge belt 260 is as shown in FIG. 4(a). That is, at the second position, the scraping belt 240a sandwiches the portion where the discharge belt 260 is stretched between the two tension rollers 261 and 262 and the sheet. However, the contact position relationship between the scraping belt 240a and the discharge belt 260 may be as shown in FIGS. 4(b) and 4(c).

That is, as shown in FIG. 4(b), the scraping belt 240a moves between the two tension rollers 261 and 262, the upstream tension roller 262 in the predetermined direction, and the discharge belt 260 at the second position. The sheet may be sandwiched between the two. Further, as shown in FIG. 4(c), the scraping belt 240a is stretched between the two rollers 240b and 240c at the second position. , 262 on the upstream side in the predetermined direction, and the sheet may be nipped through the discharge belt 260 .

Note that the raking unit 240 may be a rotating body other than the belt, such as a roller. For example, in the case of rollers, the rollers may sandwich the portion where the discharge belt 260 is stretched between two tension rollers 261 and 262 and the sheet. The sheet may be sandwiched between the tension roller 262 on the upstream side in the predetermined direction and the discharge belt 260 . However, in order to secure a contact area with the sheets on the processing tray 220, it is preferable that the scraping portion 240 is formed of a belt as in the present embodiment.

Such a raking portion 240 rotates a rotating shaft 242 as a first rotating shaft between a first position and a second position by a raking rotating mechanism 241 as moving means and first rotating means. rotated to the center. In other words, the raking portion 240 can move up and down between the first position and the second position. The rake-in rotating mechanism 241 includes a rake-in arm 243 as a first support member that supports the rake-in portion 240, and a rotary shaft 242 that rotatably supports the rake-in arm 243. The raking portion 240 supported at the tip of 243 is rotatable around the rotating shaft 242 .

Here, the scraping portion 240 preferably moves along the vertical direction, and it is conceivable that the mechanism for moving the scraping portion 240 between the first position and the second position is a linear motion mechanism. However, when a direct-acting mechanism is employed, there is a risk that the apparatus will become large in the vertical direction, for example, by arranging a motor or a direct-acting shaft in the vertical direction. As described above, since the sheet processing apparatus 200 of the present embodiment is arranged in the internal space 130 of the image forming apparatus 100, it is not preferable for the vertical dimension to be large. Therefore, in the present embodiment, the rake-in rotation mechanism 241 that rotates the rake-in portion 240 about the rotation shaft 242 is employed. Note that a linear motion mechanism may be employed as a mechanism for raising and lowering the raking unit 240 as long as the sheet processing apparatus can ensure a vertical dimension. Further, by increasing the distance between the rotating shaft 242 and the scraping portion 240 as much as possible and increasing the radius of rotation, the scraping portion 240 can be moved in the vertical direction as much as possible.

The rotating shaft 242 is arranged downstream in a predetermined direction from the discharge nip portion where the discharge roller 230 nips the sheet with the discharge belt 260 at the contact position. As a result, the turning trajectory (turning radius) of the raking portion 240 can be increased, and a motion close to a linear motion becomes possible. At the first position, the raking portion 240 is positioned vertically above the pre-processing nip portion 211a where the sheet is nipped between the pre-processing roller 211 and the conveying belt 212, and the rotary shaft 242 is located at the first position. It is positioned vertically above the raking portion 240 in .

As will be described later, the rotation shaft 232 of the discharge roller 230 is arranged upstream of the discharge nip portion in a predetermined direction, and the rotation direction is shown in the figure in relation to the sheet conveyed from the pre-processing nip portion 211a. The counterclockwise direction of 3(b) is preferable. On the other hand, the rotation shaft 242 of the raking portion 240 is required to have a large rotation radius as described above, and the second position is preferably upstream of the discharge nip portion in a predetermined direction. From this point of view, in the present embodiment, the rotation shaft 242 is arranged downstream of the discharge nip portion in a predetermined direction, and the rotation direction of the scraping portion 240 is opposite to the rotation direction of the discharge roller 230, that is, , in the direction of arrow R1 (clockwise) in FIG. 3(b). And he is trying for each other's rotation locus|trajectory to overlap, seeing from the width direction.

That is, the raking locus of the raking arm 243 that supports the raking portion 240 is closer to the turning shaft 232 of the discharge roller 230 than the turning shaft 242 (the second turning shaft side). On the other hand, the rotation trajectory of a discharge arm 233 that supports the discharge roller 230 (to be described later) is closer to the rotation shaft 242 (first rotation shaft side) of the raking portion 240 than the rotation shaft 232 is. The rotation locus of the scraping arm 243 partially overlaps the rotation locus of the discharge arm 233 when viewed from the width direction of the sheet that intersects the sheet conveying direction. For this reason, in the present embodiment, the discharge roller 230 and the scraping portion 240 are arranged at positions shifted in the width direction. Specifically, two discharge rollers 230 are arranged on both sides in the width direction, and one raking portion 240 is arranged between the two discharge rollers 230 . With this configuration, the radius of rotation of the raking portion 240 can be increased, and the raking portion 240 can come into contact with the sheets on the processing tray 220 upstream of the discharge nip portion in a predetermined direction.

In this embodiment, as described above, the rotation shaft 242 is arranged above the discharge port 201 of the sheet processing apparatus 200 shown in FIG. 1 in order to increase the rotation radius of the raking portion 240 . A discharge port 201 of the sheet processing apparatus 200 is provided with a canopy portion 202 to prevent fingers from entering the stapling unit 400 . In particular, in this embodiment, since the length of the processing tray 220 is shortened for cost reduction, the stapling unit 400 can be easily reached by a finger or the like. and the like do not reach the stapling unit 400 . If such eaves 202 were not provided, it would be necessary to provide a safety switch or the like to automatically stop the operation of stapling unit 400 upon detection of entry of a finger or the like, which would increase costs.

For this reason, the eaves portion 202 is provided above the discharge port 201 . It is possible to provide it in the vicinity. As a result, the rotating shaft 242 can be separated from the scraping portion 240 that moves above the processing tray 220, and the radius of rotation of the scraping portion 240 is increased so that the moving direction of the scraping portion 240 is as straight as possible. The direction is along the

The reason why the scraping portion 240 is moved in the direction along the straight line as much as possible is that the change in the angle of the stretched surface of the scraping belt 240a is minimized while the scraping portion 240 is in the first position and the second position. It is for That is, at the second position, the stretched surface of the scraping belt 240a is aligned with the sheet placement surface of the processing tray 220 or the upper surface of the sheet on the processing tray 220 in order to secure a contact area between the scraping belt 240a and the sheet. They are configured to be substantially parallel. Here, “substantially parallel” means, for example, that the angle of the tension surface with respect to the upper surface of the seat is within ±5°. If the turning radius of the scraping portion 240 is small, when the scraping portion 240 is moved to the first position, the stretched surface of the scraping belt 240a rises, and the scraping portion 240 is in the first position. The vertical dimension of the In this case, the size of the device is increased in order to secure a space of this dimension. Therefore, in the present embodiment, the turning radius of the raking portion 240 is increased.

Note that as the number of sheets placed on the processing tray 220 increases, the position at which the scraping belt 240a comes into contact with the sheets rises. Therefore, in the case of a mechanism that does not change the angle of the stretched surface of the scraping belt 240a, the contact area between the scraping belt 240a and the sheet changes depending on the amount of sheets loaded. Therefore, a mechanism capable of changing the angle of the raking belt 240a may be added. For example, as shown in FIGS. 5A and 5B, rollers 240b and 240c on which the scraping belt 240a is stretched are connected by an arm 240d, and the roller 240c on the upstream side in a predetermined direction is provided with a rotation shaft 240e. Thus, the scraping belt 240a can be rotated with respect to the scraping arm 243 about the rotary shaft 240e. By providing a compression spring or a torsion spring so that the roller 240b on the downstream side in a predetermined direction is urged toward the sheet, the angle of the stretched surface of the scraping belt 240a changes to follow the surface of the sheet. make it As a result, regardless of the amount of sheets stacked on the processing tray 220, the stretched surface of the scraping belt 240a can be brought into contact with the upper surface of the sheet over a wide contact area.

Further, in the case of the present embodiment, the raking portion 240 also functions as a dropping member that drops the trailing end (the upstream end in the predetermined direction) of the sheet conveyed from the pre-processing rollers 211 toward the processing tray 220 . That is, the raking rotation mechanism 241 positions the raking section 240 at the first position while the pre-processing roller 211 and the conveying belt 212 are conveying the sheet. On the other hand, after the upstream end (rear end) of the sheet in the predetermined direction passes through the pre-processing roller 211 and the pre-processing nip portion 211a of the conveying belt 212, the raking-rotation mechanism 241 moves the raking-in portion 240 from the first position to the first position. 2 position to drop the sheet toward the processing tray 220 . This prevents the trailing edge of the sheet from remaining in the pre-processing nip portion 211a. Note that the movement start timing of the raking portion 240 from the first position to the second position may be before the upstream end in the sheet conveying direction passes the nip portion 211a, or after the upstream end in the sheet conveying direction passes the nip portion 211a. It is sufficient if the movement to the second position is completed and the sheet can be dropped onto the processing tray 220 . The same applies to the movement timing of the trailing edge dropping member 240, which will be described later.

In particular, in the present embodiment, the scraping portion 240 is positioned at the first position when the sheet is being conveyed by the pre-processing roller 211 and the conveying belt 212 . That is, the raking section 240 is on standby above the pre-processing nip section 211a. Therefore, it is easy to bring the scraping portion 240 into contact with the upper surface of the trailing edge portion of the sheet that has passed through the pre-processing nip portion 211a and further push the sheet downward, thereby dropping the trailing edge of the sheet onto the processing tray 220 more reliably. be able to. The scraping portion 240 that functions even if the trailing edge of the sheet is dropped has the scraping belt 240a stretched by the two rollers 240b and 240c as described above. Further, in this embodiment, when dropping the trailing edge of the sheet, the stretched surface of the raking belt 240a is brought into contact with the upper surface of the sheet. Therefore, for example, the contact area with the sheet can be secured more than when the raking portion is a roller, and the trailing edge of the sheet can be removed more reliably.

[Rear end dropping member]
The scraping portion 240 described above is positioned at the center in the width direction of the sheet, and there is a possibility that the trailing edge of the sheet cannot be sufficiently removed only by this scraping portion 240 . For this reason, the present embodiment further includes a trailing edge dropping member 250 as an upstream edge dropping member. A pair of trailing edge dropping members 250 are provided on both sides of the raking portion 240 . That is, the pair of trailing edge dropping members 250 are arranged on both sides of the scraping portion 240 in the width direction of the sheet intersecting the sheet conveying direction, and move vertically in conjunction with the scraping portion 240 to remove the sheet. After passing through the pre-processing nip portion 211a, the upstream end (rear end) of the sheet comes into contact with the upper surface of the sheet on the upstream side in the predetermined direction (upstream side in the sheet conveying direction), and moves the upstream end (rear end) of the sheet to the processing tray. 220 to drop.

Each of the pair of trailing end dropping members 250 is a plate-like member, and is rotatably supported by the rotating shaft 242 in the same manner as the raking portion 240 . Then, it rotates in the vertical direction together with the scraping portion 240 by the scraping rotation mechanism 241 . When the raking portion 240 is at the first position, the leading ends of the pair of trailing edge dropping members 250 are located above the pre-processing nip portion 211a, similarly to the raking portion 240 . Further, when the raking portion 240 is at the second position, the surfaces of the pair of trailing edge dropping members 250 that contact the sheet (lower surfaces of the leading end portions) are positioned above the surface of the raking portion 240 that abuts the sheet. do. When the sheets placed on the processing tray 220 are curled, the lower surface of the leading end portion of the trailing edge dropping member 250 is positioned on the upper surface of the curled portion when the sheet bundle is discharged. When the rear end of the is lifted, it abuts on the upper surface of the lifted portion. Note that when the trailing edge dropping member 250 is arranged at the second position so as to face the discharge belt 260 with the sheet or sheet bundle sandwiched therebetween, the sheet is placed on the processing tray 220 in the same manner as the scraping unit 240 . It may contact the upper surface of the placed sheet or sheet bundle. In this way, when the trailing edge dropping member 250 is positioned to sandwich the sheet between itself and the discharge belt 260, at the second position, the trailing edge dropping member 250 separates the sheet or sheets on both sides in the width direction of the raking portion 240. Since the upper surface of the bundle is pressed, the sheet or sheet bundle can be more reliably pressed toward the discharge belt 260, and the sheet or sheet bundle can be conveyed more reliably. Note that the leading end portions of the pair of trailing edge dropping members 250 are bent portions 251 that are bent so as to be substantially parallel to the upper surface of the sheet on the processing tray 220 at the second position. The rotation trajectory of the pair of trailing end dropping members 250 is the same as that of the raking portion 240 and the raking arm 243 .

[Return member]
The return member 280 further conveys the sheet conveyed toward the trailing edge regulating member 290 by the raking portion 240 toward the trailing edge regulating member 290 as described above, and the trailing edge of the sheet is conveyed to the trailing edge regulating member 290. It contacts to restrict the position of the trailing edge of the sheet. Such a return member 280 is composed of a knurled belt 281. By rotating the knurled belt 281, the sheet conveyed upstream in a predetermined direction by the raking unit 240 is further ragged, and the trailing edge of the sheet is turned to the trailing edge. It is brought into contact with the regulating member 290 . The return member 280 can move between a contact position where it can contact the sheet and a retracted position retracted upward from the contact position. When conveying the sheet on the processing tray 220 toward the stacking tray 300 , it moves to the retracted position.

[Eject roller]
The discharge roller 230, together with the discharge belt 260, constitutes a pair of discharge rotors and discharge means. The discharge roller 230 as an upper discharge rotating body can move between a contact position where it contacts the upper surface of the sheet placed on the processing tray 220 and a retreat position where it retreats upward from the contact position. 260 to sandwich the sheet. That is, the discharge roller 230 functions as a nip member that nips the sheet with the discharge belt 260 at the contact position. The two discharge rollers 230 are spaced apart in the width direction of the sheet, and as described above, each discharge roller 230 can pinch the sheet with the corresponding discharge belt 260 at the contact position. .

In addition, in the case of this embodiment, two discharge rollers 230 are arranged spaced apart in the width direction. That is, of the pair of trailing edge dropping members 250, the discharge roller 230 is positioned between the trailing edge dropping member 250 on one side and the scraping portion 240 and between the trailing edge dropping member 250 and the scraping portion 240 on the other side. One is placed in each of the spaces. These two discharge rollers 230 sandwich the sheet or sheet bundle with the discharge belts 260 on both sides in the width direction at the contact position. As the discharge belt 260 rotates, the sheet or sheet bundle sandwiched between the discharge roller 230 and the discharge belt 260 is conveyed. If the sheet or sheet bundle is nipped and conveyed by the discharge roller 230 and the discharge belt 260 at positions spaced apart in the width direction in this manner, skew is less likely to occur during conveyance of the sheet or sheet bundle. Further, at this time, the sheet or sheet bundle is sandwiched between the discharge belt 260 at the center in the width direction and the scraping portion 240 to assist the discharge of the sheet or the sheet bundle. , the conveying force can be transmitted to the sheet at three points, and the sheet or sheet bundle can be ejected more reliably while suppressing the skew.

The discharge roller 230 is a driven roller that rotates following the rotation of the discharge belt 260, but may be driven. That is, in the present embodiment, the discharge roller 230 is a driven rotating body, and the discharge belt 260 is a driven rotation. Further, the discharge roller 230 functions as a nip member capable of nipping the sheet with the discharge belt 260 at the contact position, but the nip member may be another rotating member such as a belt instead of the roller. Alternatively, it may be a contact member that contacts the sheet without rotating like a lever member.

The discharge roller 230 is arranged at the contact position so as to face the downstream tension roller 261 of the tension rollers 261 and 252 that stretch the discharge belt 260 with the discharge belt 260 interposed therebetween. Thus, at the contact position, the sheet can be nipped between the ejection roller 230 and the tension roller 261 via the ejection belt 260, so that the sheet can be reliably nipped and conveyed.

The ejection roller 230 is rotatable between a contact position and a retracted position about a rotation shaft 232 as a second rotation shaft by an ejection roller rotation mechanism 231 as a second rotation means. . In other words, the discharge roller 230 can move up and down between the contact position and the retracted position. The ejection roller rotation mechanism 231 includes an ejection arm 233 as a second support member that supports the ejection roller 230 and a rotation shaft 232 that rotatably supports the ejection arm 233 . Further, the discharge roller 230 supported at the tip of the discharge arm 233 can be rotated around the rotation shaft 232 . A detailed configuration of the discharge roller rotating mechanism 231 will be described later.

The rotating shaft 232 is arranged upstream in a predetermined direction from the discharge nip portion where the discharge roller 230 nips the sheet between the discharge belt 260 and the discharge roller 230 at the contact position. At the retracted position, the discharge roller 230 is positioned vertically above the pre-processing nip portion 211a where the sheet is nipped between the pre-processing roller 211 and the conveying belt 212. It is positioned above 230 in the vertical direction.

Since the discharge roller 230 defines the positional relationship between the rotating shaft 232 and the pre-processing nip portion 211a as described above, the sheet that has passed through the pre-processing nip portion 211a reaches the stacking tray 300 in the retracted position. allow to go to On the other hand, the ejection roller 230 rotates about the rotation shaft 232 in the direction of arrow R2 (counterclockwise direction) in FIG. At this time, the discharge arm 233 enters the path along which the sheet passes through the pre-treatment nip portion 211a, and also serves to guide the sheet downward. Specifically, when the discharge arm 233 guides the sheet that has passed through the pre-processing nip portion 211a, the discharge roller 230 stops at the guide position between the contact position and the retracted position in the vertical direction. . Then, the sheet can be nipped between the discharge roller 230 and the discharge belt 260 by moving the discharge roller 230 further downward from the guide position to the contact position.

[Matching section]
An alignment section 270 as alignment means has a pair of alignment plates 271 . The pair of aligning plates 271 are arranged further downstream than the downstream end of the conveying path 210 in the sheet conveying direction (the downstream end in a predetermined direction), and move in the width direction of the sheet intersecting the sheet conveying direction to adjust the width of the sheet. The sheets are aligned in the width direction by contacting the directional edges. In this embodiment, they are arranged on both sides in the width direction of the sheet placed on the processing tray 220 and are movable in the width direction. Also, the configuration of the pair of alignment plates 271 is the same.

Also, the pair of alignment plates 271 has a first contact portion 272 and a second contact portion 273 . The first contact portion 272 is further downstream than the downstream end of the conveying path 210 in the sheet conveying direction, and can contact the width direction edge of the sheet hanging from the conveying path 210 toward the processing tray 220 . That is, the first contact portion 272 is in a state where the leading edge (downstream edge in the predetermined direction) of the sheet conveyed on the conveying path 210 passes through the pre-processing nip portion 211a, and the trailing edge does not pass through the pre-processing nip portion 211a. , and is provided at a position where it can come into contact with the width direction edge of the sheet while hanging down from the conveying path 210 to the pre-processing nip portion 211a. In this embodiment, the first contact portion 272 is arranged further downstream than the downstream end portion of the conveying path 210 in the sheet conveying direction. not only on the downstream side of the downstream end in the sheet conveying direction, but also on the upstream side of the pre-processing nip portion 211a in the sheet conveying direction, and the edge in the sheet width direction straddles the pre-processing nip portion 211a. You may make it contact|abut.

The second contact portion 273 is arranged from below the first contact portion 272 to the downstream side of the first contact portion 272 in the sheet conveying direction. The end can contact the edge in the width direction of the sheet while protruding toward the stacking tray 300 (stacking tray side) from the downstream end of the processing tray 220 in the sheet conveying direction. That is, the second contact portion 273 is provided at a position where it can contact the width direction edge of the sheet placed on the processing tray 220 . The processing tray 220 is generally shorter than the sheets to be placed, and even if the sheet is placed on the processing tray 220 and the trailing edge of the sheet is regulated as described above, the leading edge of the sheet hangs down toward the stacking tray 300 side. state. The second contact portion 273 is formed at a position capable of contacting the width direction edge of the sheet in such a state.

Further, the second contact portion 273 , which will be described later in detail, can also contact the width direction edge of the sheet hanging from the conveying path 210 toward the processing tray 220 along with the first contact portion 272 . As described above, the discharge roller 230 rotates from the retracted position to the guide position. As will be described later in detail, the discharge roller 230 and the discharge arm 233 start rotating toward the guide position in synchronization with the timing of the sheet being discharged from the conveying path 210, and move the leading edge of the sheet in the middle of being discharged from the conveying path 210. It also serves as guide means for guiding the sheet downward by coming into contact with the upper surface. As the sheet is guided downward by the discharge roller 230 and the discharge arm 233 in this way, the width direction edge of the sheet comes into contact with the first contact portion 272 and the second contact portion 273 .

Here, the first contact portion 272 is positioned vertically above the second contact portion 273 . Also, the pair of alignment plates 271 has cutouts 274 that are cut so as not to interfere with the trailing edge dropping member 250 described above. That is, the pair of alignment plates 271 includes a second contact portion 273 elongated in a predetermined direction and a first contact portion formed to extend upward from the upstream portion of the second contact portion 273 in the predetermined direction. 272 and a notch 274 formed above a downstream portion of the second contact portion 273 in a predetermined direction. As described above, the trailing edge dropping member 250 rotates about the rotating shaft 242 downstream in the predetermined direction from the discharge nip portion. Interference with the trailing edge dropping member 250 is prevented.

On the other hand, as described above, the first contact portion 272 is provided above the upstream portion of the second contact portion 273 in the predetermined direction so as to be able to contact the width direction edge of the sheet hanging down from the conveying path 210 . ing. Further, the second contact portion 273 is also formed below the notch portion 274 so that the width direction edge of the sheet hanging down from the conveying path 210 can contact the second contact portion 273 . ing.

As will be described later in detail, when the width direction edge of the sheet hanging down from the conveying path 210 is brought into contact with the sheet, the nip pressure of the pre-processing roller 211 is set to approximately 0, and even when the sheet is on the conveying path 210, the pair of Alignment plate 271 enables alignment of sheets or movement (shift) of sheets in the width direction. The second contact portion 273 contacts the width direction edge of the sheet hanging from the conveying path 210 as described above together with the first contact portion 272 to align the sheet or move the sheet in the width direction. It is possible. Furthermore, the second contact portion 273 is movable in the width direction along the sheet placement surface of the processing tray 220 so as to be able to contact the width direction edge of the sheet placed on the processing tray 220 . In addition, it is formed longer than the first contact portion 272 in a predetermined direction so that the contact area with the width direction edge of the sheet on the processing tray 220 is increased.

[Load tray]
Sheets discharged by the discharge roller 230 and the discharge belt 260 are stacked on the stacking tray 300 as described above. The stacking tray 300 is provided on the downstream side of the processing tray 220 in a predetermined direction and can be vertically lowered. Further, the stacking tray 300 is inclined with respect to the horizontal plane so that the upstream side in a predetermined direction is lower than the downstream side. Such a stacking tray 300 is, for example, supported so as to be vertically movable along rails arranged in the vertical direction, and is moved up and down by driving an elevating motor MT9 (FIG. 14) as elevating means.

At the upstream end of the stacking tray 300 in a predetermined direction, an upright surface 310 is provided as stacking side regulating means for regulating the upstream end (rear end) of the sheets or sheet bundles stacked on the stacking tray 300 in a predetermined direction. Further, at least a part of the processing tray 220 is provided at the downstream end in the predetermined direction so as to protrude downstream in the predetermined direction from the standing surface 310 and downward from the sheet loading surface of the processing tray 220 . A sheet pressing belt 320 is provided as an endless belt. The sheet holding belt 320 is a knurled belt similar to the return member 280 described above.

The stacking tray 300 can be moved up and down between a first stacking position and a second stacking position below the first stacking position by an elevating motor MT9. The first stacking position is a position where the sheets on the stacking tray can come into contact with the sheet pressing belt 320 . Further, the second stacking position is a position where the operation of the stacking tray 300 that has been lowered when discharging the sheets to the stacking tray 300 switches to ascending.

Although details will be described later, the stacking tray 300 moves up and down when a sheet or a sheet bundle is discharged, and the upper surface of the sheet or the sheet bundle on the stacking tray 300 on the trailing end side comes into contact with the sheet pressing belt 320 . As a result, even if the trailing edge of the sheet or sheet bundle on the processing tray 220 is pressed by the sheet pressing belt 320 and the sheet or sheet bundle is discharged after that, the sheet or sheet bundle already stacked on the stacking tray 300 is still held. displacement can be suppressed.

In addition to the function of pressing the trailing edge of the sheet or sheet bundle on the stacking tray 300 , the sheet pressing belt 320 rotates to direct the sheet or sheet bundle on the stacking tray 300 toward the standing surface 310 . The trailing edge of the sheet or the sheet bundle is aligned by conveying and abutting the trailing edge of the sheet or the sheet bundle against the standing surface 310 . Such a sheet pressing belt 320 is arranged coaxially with a tension roller 261 that drives a discharge belt 260 as a drive rotating body. That is, a roller for driving the sheet pressing belt 320 is also provided on the drive shaft 261a of the tension roller 261, and the discharge belt 260 and the sheet pressing belt 320 rotate synchronously.

[Driving Configuration of Sheet Processing Apparatus]
Next, a driving configuration 500 of each part of the sheet processing apparatus 200 will be described with reference to FIGS. 6 to 14. FIG. FIG. 6 shows a configuration for varying the nip pressure of the pre-processing roller 211, driving the conveying belt 212, etc., and raising and lowering the discharge roller 230 in the drive configuration 500. FIG. The transport motor MT<b>1 transmits drive to the drive shaft 502 of the roller 212 a that drives the transport belt 212 via the transmission belt 501 . Since a roller for driving the knurled belt 214 is also provided on the drive shaft 502, the knurled belt 214 is also rotationally driven by the conveying motor MT1.

Further, the drive of the transport motor MT1 is transmitted to the pre-processing roller 211 and the return member 280 via a transmission mechanism (not shown). Therefore, the pre-processing roller 211, the conveying belt 212, the knurled belt 214, and the return member 280 are synchronously driven to rotate by the conveying motor MT1.

The lifting motor MT3 is connected to the rotation shaft 232 of the discharge roller 230, and the discharge roller 230 moves up and down between the contact position and the retracted position as described above by driving the lifting motor MT3. Further, in the case of this embodiment, the nip pressure of the pre-treatment roller 211 can be changed by driving the lifting motor MT3. In other words, the lift motor MT3 also functions as a nip pressure adjusting means capable of adjusting the nip pressure for nipping the sheet between the pre-processing roller 211 as the first rotating body and the conveying belt 212 as the second rotating body.

This configuration is shown in FIGS. 7(a) and 7(b). The pre-processing roller 211 is held by a roller holding portion 511, and the roller holding portion 511 is movable in the vertical direction, that is, in the direction of moving toward and away from the portion of the conveying belt 212 that is stretched over the rollers 212a. is. The roller holding portion 511 is biased in a direction to press the pre-processing roller 211 against the conveying belt 212 by a torsion spring 512 as biasing means. Also, the torsion spring 512 is supported by the rotation shaft 232 of the discharge roller 230 and rotates together with the rotation shaft 232 .

Specifically, one end of the torsion spring 512 is in contact with the roller holding portion 511 , and a portion of the other end of the torsion spring 512 sandwiching the rotation shaft 232 is provided on the ejection arm 233 that supports the ejection roller 230 . It abuts on the projecting portion 233a that is formed. As a result, the torsion spring 512 is elastically stretched between the roller holding portion 511 and the projecting portion 233a. When the ejection arm 233 rotates together with the rotating shaft 232, the position of the part of the other end of the torsion spring 512 that is in contact with the projecting portion 233a changes, and the torsion spring 512 rotates around the rotating shaft 232. 232. As a result, the force that biases the roller holding portion 511 by the torsion spring 512 changes, and the nip pressure of the pre-processing roller 211 can be changed.

FIG. 7A shows a state in which the discharge roller 230 is positioned at the retracted position. In this state, the roller holding portion 511 is biased by the torsion spring 512, and the pre-processing roller 211 contacts the conveying belt 212 with a predetermined nip pressure (first pressure). On the other hand, FIG. 7B shows a state in which the discharge roller 230 is lowered toward the contact position. When the rotation shaft 232 rotates in the direction of lowering the discharge roller 230 toward the contact position by driving the lifting motor MT3, the torsion spring 512 also rotates accordingly. Then, the bias of the torsion spring 512 against the roller holding portion 511 is released, and the nip pressure of the pre-treatment roller 211 against the conveyor belt 212 becomes almost 0 (second pressure smaller than the first pressure). In other words, the pre-processing roller 211 comes into contact with the conveying belt 212 due to its own weight.

As described above, in this embodiment, the nip pressure of the pre-processing roller 211 against the conveying belt 212 can be changed by driving the lifting motor MT3 to move the discharge roller 230 up and down. Therefore, as will be described later, when the aligning unit 270 performs the aligning operation with a part of the sheet remaining on the conveying path 210, the nip pressure of the pre-processing roller 211 is reduced to approximately 0 by lowering the discharge roller 230. can be If the nip pressure of the pre-processing roller 211 is approximately 0, even if the sheet is nipped between the pre-processing roller 211 and the conveying belt 212, the sheet can be moved in the width direction.

As shown in FIG. 6, a flag 513 is provided at the end of the rotating shaft 232, and the flag 513 can be detected by the nip member HP position detection sensor SN2. The nip member HP position detection sensor SN2 is a photointerrupter having a light emitting portion and a light receiving portion. , to detect the position at the home position.

As shown in FIG. 8, the lifting motor MT3 is connected to the rotary shafts 242 of the raking portion 240 and the trailing edge dropping member 250 via the transmission belt 514 and the electromagnetic clutch CL1. That is, a transmission belt 514 is stretched between a pulley 515 provided on the rotating shaft 232 of the discharge roller 230 and a pulley 516 drivingly connected to the electromagnetic clutch CL1 by a gear or the like. Electromagnetic clutch CL1 is connected to rotating shaft 242 . As shown in FIGS. 9 and 10(a), the connection between the electromagnetic clutch CL1 and the rotating shaft 242 is established by a lifting lever 517 provided on the electromagnetic clutch CL1 and a protrusion protruding from the rotating shaft 242. 518.

That is, the lifting lever 517 is fixed to the output shaft of the electromagnetic clutch CL1, and swings about the rotation center of the rotating shaft 242 as the output shaft rotates. A projecting portion 518 is provided below the lifting lever 517 at a position where it can be engaged with the lifting lever 517 . Therefore, when the lift lever 517 swings, it engages with the protrusion 518, and the rotating shaft 242 provided with the protrusion 518 rotates. In this embodiment, as will be described later, the scraping arm 243 and the trailing edge dropping member 250 are urged upward by the tension spring 252, so that the projection 518 is also attached so as to abut against the lift lever 517 positioned above. are being forced. Therefore, when the electromagnetic clutch CL1 is ON and the lift motor MT3 is driven in the forward direction, the engagement of the lift lever 517 and the protrusion 518 moves the scraping portion 240 and the trailing edge dropping member 250 downward. do. On the other hand, when the lift motor MT3 is driven in the reverse direction, the lift lever 517 swings upward, and the extension spring 252 causes the protrusion 518 to follow the lift lever 517 and move upward. That is, by driving the lifting motor MT3 in the opposite direction, the raking portion 240 and the trailing edge dropping member 250 can be moved upward.

In summary, when the electromagnetic clutch CL1 is ON, the drive from the pulley 516 is connected to the rotating shaft 242 side. And the trailing edge dropping member 250 moves up and down. On the other hand, when the electromagnetic clutch CL1 is OFF, the drive transmission between the pulley 516 and the rotating shaft 242 is cut off. , only the discharge roller 230 moves up and down.

A tension spring 252 is provided in the trailing end dropping member 250 . The tension spring 252 has one end connected to the tip side of the trailing edge dropping member 250 and the other end connected to a frame on the upper surface of the apparatus (not shown). energized. Therefore, the trailing edge dropping member 250 is biased upward.

Here, as shown in FIG. 9, the rotating shaft 242 is arranged around a driving shaft 244 for driving a raking belt 240a, which will be described later, so as to be relatively rotatable with respect to the driving shaft 244. As shown in FIG. The drive shaft 244 is not connected to the electromagnetic clutch CL1, and the rotary shaft 242 is rotatable separately from the drive shaft 244. The rotary shaft 242 has a first portion 242a to which the base end of the trailing end dropping member 250 is fixed, and a second portion 242b to which the base end of the raking arm 243 of the raking portion 240 is fixed. The first portion 242a and the second portion 242b are connected to each other and are rotatable together. Therefore, the scraping arm 243 moves upward together with the trailing edge dropping member 250 when the trailing edge dropping member 250 moves upward due to the biasing force of the tension spring 252 .

For example, if the electromagnetic clutch CL1 is turned off after the raking portion 240 and the trailing edge dropping member 250 are moved to the second position, the trailing edge dropping member 250 and the raking portion 240 are quickly moved to the first position by the tension spring 252. rise towards That is, the raking portion 240 and the trailing edge dropping member 250 can be moved upward simply by turning off the electromagnetic clutch CL1 without driving the lifting motor MT3. For example, in order to receive the next sheet, it is faster to turn off the electromagnetic clutch CL1 and move upward by the biasing force of the tension spring 252 than by driving the lift motor MT3. Therefore, in the case of this embodiment, the next sheet can be quickly received on the processing tray 220, and productivity can be improved.

10(a) to 12(b), the lifting operation of the discharge roller 230, the scraping portion 240, and the trailing edge dropping member 250 will be described. First, FIGS. 10A and 11A show a state in which the discharge roller 230 is at the retracted position, and the scraping portion 240 and the trailing edge dropping member 250 are at the first position. When the lift motor MT3 is driven with the electromagnetic clutch CL1 turned off from the state of FIG. 10(a), as shown in FIG. 10(b), only the discharge roller 230 descends from the retracted position toward the contact position.

On the other hand, when the electromagnetic clutch CL1 is turned ON and the lift motor MT3 is driven from the state of FIG. 11(a), as shown in FIG. The portion 240 and trailing edge dropping member 250 are also lowered toward the second position. Next, when the electromagnetic clutch CL1 is turned off from the state shown in FIG. 12(a), in which the discharge roller 230 is at the contact position and the scraping portion 240 and the trailing edge dropping member 250 are at the second position, the state shown in FIG. 12(b) is shown. As shown, while the discharge roller 230 remains at the contact position, the tension spring 252 moves the scraping portion 240 and the trailing edge dropping member 250 upward. Thus, in this embodiment, by controlling the ON and OFF timings of the electromagnetic clutch CL1, it is possible to shift the elevation timings of the ejection roller 230, the raking portion 240, and the trailing edge dropping member 250. FIG.

As shown in FIG. 13, a rotation shaft 233B is provided in the middle of the ejection arm 233A of the ejection roller 230 so that the tip side of the rotation shaft 233B can be rotated, and the tip side is moved downward by a spring. You may make it energize|bias toward. In this case, even if the scraping portion 240 and the trailing edge dropping member 250 descend after the discharge roller 230 , the scraping portion 240 and the trailing edge dropping member 250 can contact the sheet on the processing tray 220 .

That is, when the electromagnetic clutch CL1 is turned ON while the discharge roller 230 is at the contact position, and the lift motor MT3 is driven, the discharge roller 230 moves downward from the contact position. With the configuration shown in FIG. 13, when the ejection roller 230 attempts to move further downward, the distal end of the ejection arm 233A rotates around the rotation shaft 233B, thereby allowing the ejection roller 230 to move. can do. Therefore, even if the scraping portion 240 and the trailing edge dropping member 250 descend after the discharge roller 230, the scraping portion 240 and the trailing edge dropping member 250 can descend to a position where they can contact the sheet on the processing tray 220. Become.

As shown in FIG. 8, the conveying motor MT2 can transmit driving force to a drive shaft 244 for driving the scraping belt 240a via a transmission belt 520. As shown in FIG. A pulley 521 is provided at a position between the drive shaft 244 and the rake arm 243. A drive belt is provided between the pulley 521 and a roller 240c (FIG. 9) on which the rake belt 240a is stretched. 522 is hung. When the transport motor MT2 is driven, the drive shaft 244 rotates via the transmission belt 520, and the roller 240c rotates via the pulley 521 and the drive belt 522 provided on the drive shaft 244. FIG. Then, the scraping belt 240a stretched by the rollers 240c is rotationally driven. As described above, since the drive shaft 244 is rotatable relative to the rotation shaft 242, the drive shaft 244 idles with respect to the rotation shaft 242 when the transport motor MT2 is driven.

The drive shaft 244 and the tension roller 261 that rotates the discharge belt 260 are connected by a drive transmission section 523 . The drive transmission portion 523 rotates integrally with a pulley 523a provided on the drive shaft 244, a first intermediate pulley 523b, a first transmission belt 523c stretched between the pulley 523a and the first intermediate pulley 523b, and a first intermediate pulley 523b. A second intermediate pulley 523d, an electromagnetic clutch CL2, a pulley 523e drivingly connected to the electromagnetic clutch CL2 by a gear or the like, a second transmission belt 523f stretched between the second intermediate pulley 523d and the pulley 523e, and drivingly connected to the electromagnetic clutch CL2. and a driven shaft 523g. A tension roller 261 is provided on the drive shaft 523g.

Therefore, when the transport motor MT2 is driven, the first transmission belt 523c and the second transmission belt 523f rotate. When the electromagnetic clutch CL2 is ON, the drive of the transport motor MT2 is transmitted to the drive shaft 523g, the tension roller 261 rotates, and the discharge belt 260 is driven to rotate. On the other hand, when the electromagnetic clutch CL2 is OFF, the drive is not transmitted to the drive shaft 523g even if the conveying motor MT2 is driven, and the discharge belt 260 does not rotate.

Further, in this embodiment, the drive shaft 523g is also connected to the roller 321 that drives the sheet pressing belt 320 . That is, the roller 321 is provided on the drive shaft 523g, and rotates together with the tension roller 261 as the drive shaft 523g rotates. Therefore, when the electromagnetic clutch CL2 is ON and the conveying motor MT2 is driven, the roller 321 is rotated, and the sheet pressing belt 320 is also driven to rotate. On the other hand, when the electromagnetic clutch CL2 is OFF, the sheet pressing belt 320 does not rotate even if the conveying motor MT2 is driven.

FIG. 14 shows the relationship between each motor and each configuration. The columns shown in FIG. 14 are, from left to right, number, name of motor, presence/absence of a clutch between drive parts driven by the motor, drive parts, operation, state and direction of operation of clutch during forward rotation, clutch position during reverse rotation. Indicates the state, direction of movement, and remarks. In FIG. 14, the conveying motors MT1 and MT2 and the lifting motor MT3 are as described above. As is clear from FIG. 14, the transport motor MT1 drives a roller (transport roller) 212a that drives the transport belt 212, the pre-processing roller 211, and the return member 280. As shown in FIG. That is, in this embodiment, the same driving source is used for the conveying belt 212, the pre-processing roller 211, and the return member 280. FIG.

The transport motor MT2 also drives a drive shaft 244 for driving the scraping belt 240a, a tension roller 261 for driving the discharge belt 260, and a drive shaft 523g for driving the sheet pressing belt 320. FIG. That is, in this embodiment, the driving source for the raking belt 240a, the discharge belt 260, and the sheet pressing belt 320 is the same. Further, the lift motor MT3 lifts and lowers the discharge roller (nip member) 230, changes the nip pressure of the pre-processing roller 211, and lifts and lowers the scraping portion 240 and the trailing edge dropping member 250. FIG. That is, in this embodiment, the same driving source is used to raise and lower the discharge roller 230, raise and lower the scraping portion 240 and trailing edge drop member 250, and change the nip pressure of the pre-processing roller 211. FIG.

In this embodiment, in addition to this, an elevating motor MT4 for raising and lowering the return member 280, an aligning plate moving motor MT5 for moving the front aligning plate 271 in the width direction, and a rear aligning plate 271 are moved in the width direction. Alignment plate moving motor MT6 for moving the sheet stack to the aligning plate moving motor MT6, STP moving motor MT7 for moving the stapling unit 400 to change the stapling position, STP clinch motor MT8 for driving the stapling unit 400 and stapling the sheet bundle, and the stacking tray 300 is provided with an elevating motor MT9 for elevating the .

[Control Configuration of Sheet Processing Apparatus]
A control configuration of the sheet processing apparatus 200 will be described with reference to FIGS. 15 and 16. FIG. FIG. 15 is a block diagram showing the drive configuration of each motor, clutch, etc., and each sensor of the sheet processing apparatus 200. As shown in FIG. Signals from these sensors are input to a control section 203 as control means, and each driving configuration is controlled by the control section 203 . A control unit 203 is communicably connected to a control unit of the image forming apparatus 100 and controls the entire sheet processing apparatus 200 .

Such a control unit 203 has a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory). The CPU controls each part while reading a program corresponding to the control procedure stored in the ROM. The RAM stores work data and input data, and the CPU performs control by referring to the data stored in the RAM based on the above-described programs and the like.

Each motor, clutch, etc. shown in FIG. 15 are as described above. On the other hand, each sensor will be described with reference to FIG. 3(b). First, the inlet sensor SN1 is provided on the conveying path 210 and detects the leading edge of the sheet conveyed on the conveying path 210 . The nip member HP position detection sensor SN2 is provided around the rotation shaft 232 as described above, and detects that the discharge roller (nip member) 230 is at the retracted position (home position). The raking portion HP position detection sensor SN3 is provided around the rotary shaft 242 and detects that the raking portion 240 and the trailing edge dropping member 250 are at the first position (home position). The knurled belt HP position detection sensor SN4 detects the position (home position) at which the return member 280 has retreated from the processing tray 220 .

The front aligning plate HP position detection sensor SN5 and the rear aligning plate HP position detection sensor SN6 are located at positions where the front aligning plate 271 and the rear aligning plate 271 are separated from the sheet placed on the processing tray 220 in the width direction. (home position). A stapler HP position detection sensor SN7 detects that the staple unit 400 is at the home position. A stacking tray HP position detection sensor SN8 detects the home position of the stacking tray 300 . A stacking tray lower limit position detection sensor SN9 detects the lower limit position of the stacking tray 300 . A processing tray sheet presence/absence detection sensor SN10 detects the presence/absence of a sheet on the processing tray 220 . Based on the signals from these sensors, the control unit 203 performs various controls, which will be described later.

Next, with reference to FIG. 16, the flow of control in each mode of this embodiment will be described. In this embodiment, there is a straight discharge mode in which a sheet sent to the sheet processing apparatus 200 is discharged to the stacking tray 300 as it is without being subjected to a predetermined process, and a sheet transport mode in which the sheet sent to the sheet processing apparatus 200 is moved in the width direction ( There is a shift mode in which the sheets are discharged to the stacking tray 300 after a shift operation, and a staple mode in which the sheets sent to the sheet processing apparatus 200 are stapled as a predetermined process and discharged to the stacking tray 300 . Each of these modes is selected by the user.

In addition, the shift mode includes a case where a large size sheet whose length in the conveying direction (predetermined direction) is longer than a predetermined length is shifted, and a case where the length of the sheet in the predetermined direction is less than a predetermined length than the large size sheet. There is a case where a shift operation is performed to a small size. The predetermined length is, for example, a so-called A4 vertical size that feeds an A4 size sheet in the vertical direction (the direction in which the longitudinal direction is the conveying direction). Further, in the shift mode, it is possible to select and execute a productivity priority mode in which productivity is prioritized and an alignment priority mode in which alignment of sheets is prioritized.

The productivity priority mode as the first mode is a mode in which the alignment unit 270 aligns the sheet in the width direction while the sheet hangs down from the conveying path 210 toward the processing tray. The alignment priority mode as the second mode is a mode in which the aligning unit 270 aligns the sheets in the width direction with respect to the sheets that are not stapled by the stapling unit 400 while being placed on the processing tray 220 . be. A detailed description of this point will be given later.

When control is started, the control unit 203 determines which of the straight discharge mode, the shift mode, and the staple mode is selected as the discharge mode (S1). When the straight discharge mode is selected, the sheets sent to the sheet processing apparatus 200 are discharged one by one onto the stacking tray 300 as they are without undergoing predetermined processing (S2).

If the shift mode is selected in S1, it is determined whether the sheet size is large or small (S3). If the size is small, it is determined whether productivity is given priority (S4). If priority is given to productivity, the sheets discharged from the conveying path 210 are not shifted by the processing tray 220, but are discharged to the stacking tray 300 by performing the shifting operation while part of the conveying path 210 remains ( S5). If productivity is not prioritized in S4, the sheet discharged from the conveying path 210 is scraped into the processing tray 220, shifted on the processing tray 220, and discharged onto the stacking tray 300 (S6). Also when it is large size in S3, it progresses to S6.

In S1, when the staple mode is selected, the sheets discharged from the conveying path 210 are swept into the processing tray 220 and aligned to form a sheet bundle on the processing tray 220 (S7). Then, the sheet bundle is stapled (S8). After that, the sheet bundle is discharged onto the stacking tray 300 (S9).

Operations of the sheet processing apparatus 200 in each mode described above will be described with reference to FIGS. 17 to 41. FIG.

[Straight discharge mode]
The straight discharge mode will be described with reference to FIGS. 17 to 20. FIG. As shown in FIGS. 17A and 17B, when the sheet S is conveyed along the conveying path 210, the discharge roller 230 is at the retracted position, and the scraping portion 240 and trailing edge drop member 250 are at the first position. located respectively. Next, as shown in FIGS. 18A and 18B , the sheet S is discharged in a predetermined direction from the pre-processing roller 211 positioned at the downstream end of the conveying path 210 in the predetermined direction and the pre-processing nip portion 211 a between the conveying belt 212 . be done. Even in this state, the discharge roller 230 is positioned at the retracted position, and the scraping portion 240 and the trailing edge dropping member 250 are positioned at the first position.

When the sheet S is conveyed by a predetermined amount from the pre-processing nip portion 211a, as shown in FIGS. to sandwich the sheet S. At this time, the trailing edge of the sheet S does not pass through the pre-processing nip portion 211a. Therefore, the sheet S is nipped between the discharge nip portion 230a between the discharge roller 230 and the discharge belt 260 and the pre-processing nip portion 211a. However, as described above, when the discharge roller 230 descends to the contact position, the nip pressure of the pre-treatment roller 211 becomes almost zero. Therefore, the sheet S is mainly nipped and conveyed by the discharge roller 230 and the discharge belt 260, and as shown in FIGS. Ejected.

[Shift mode (productivity priority)]
Among the shift modes, the productivity priority mode will be described with reference to FIGS. 21 to 25. FIG. As shown in FIGS. 21A and 21B, when the sheet S is conveyed along the conveying path 210, the discharge roller 230 is at the retracted position, and the scraping portion 240 and trailing edge drop member 250 are at the first position. located respectively. Next, as shown in FIGS. 22A and 22B, the downstream end (leading edge) of the sheet S in the sheet conveying direction passes through the pre-processing nip portion 211a between the pre-processing roller 211 and the conveying belt 212, and After the upstream end (rear end) of the sheet S in the sheet conveying direction passes through the nip portion between the upstream roller 213 as the third rotating body and the conveying belt 212, the nip pressure of the pre-processing roller 211 is reduced from the first pressure. Change to a second pressure. That is, the nip pressure is set to approximately zero. Note that the change start timing from the first pressure to the second pressure may be before the upstream end in the sheet conveying direction passes through the nip portion between the upstream roller 213 and the conveying belt 212, or the upstream end in the sheet conveying direction may be before the upstream roller 213 and the conveying belt 212, the change to the second pressure may be completed.

In this embodiment, when the trailing edge of the sheet S passes through the inlet sensor SN1 on the conveying path 210, the ejection roller 230 starts to descend and moves toward the guide position. As a result, the nip pressure of the pre-treatment roller 211 becomes almost zero. Further, when the trailing edge of the sheet S passes through the inlet sensor SN1 on the conveying path 210, the front and rear aligning plates 271 start moving toward the edges of the sheet S in the width direction. In this state, the sheet S hangs down from the conveying path 210 toward the processing tray 220, and the widthwise edge of the hanging portion comes into contact with the first contact portion 272 of the alignment plate 271, thereby aligning the widthwise direction. is done. At this time, since the nip pressure of the pre-processing roller 211 is almost zero, the sheets are smoothly aligned by the alignment plate 271 . That is, when the aligning section 270 aligns the sheet hanging down from the conveying path 210 in the width direction, the nip pressure of the pre-processing rollers 211 is adjusted to approximately zero.

Next, when the sheet S is further conveyed, as shown in FIGS. 23A and 23B, the leading edge of the sheet S is directed downward to the discharge arm 233 of the discharge roller 230 which has moved (in motion) to the guide position. be guided towards. Then, the upper surface of the sheet S is pushed by the discharge roller 230 at the timing when the leading edge of the sheet S passes the downstream end of the discharge belt 260 in the predetermined direction. At this time, the sheet S is conveyed by the conveying belt 212 because the nip pressure of the pre-processing roller 211 is almost zero. The sheet S is placed on the conveying belt 212 by its own weight, and the contact area between the sheet S and the conveying belt 212 is secured to some extent.

As shown in FIGS. 23A and 23B, the discharge roller 230 pushes the leading edge of the sheet S downward in the width direction so that the edge of the leading edge of the sheet S in the width direction becomes the second contact of the aligning plate 271 . It faces the contact portion 273 . Further, the trailing edge of the sheet S does not pass through the pre-processing nip portion 211a. In the productivity priority mode, in this state, the first contact portion 272 and the second contact portion 273 of the pair of alignment plates 271 are brought into contact with the width direction edge of the sheet to shift the sheet S in a desired direction. . That is, in the productivity priority mode of the present embodiment, the sheet S is suspended from the conveying path 210 without being placed on the processing tray 220, and the pair of aligning plates 271 are in contact with each other at two points spaced apart in a predetermined direction. The first contact portion 272 and the second contact portion 273 are brought into contact with the edges of the sheet S in the width direction. At this time, the first contact portion 272 contacts the curved portion of the sheet SL that hangs down from the conveying path 210, and the second contact portion 273 contacts the leading edge side of the sheet SL. By moving the pair of aligning plates 271 in a desired direction, the sheet S is moved in the width direction.

When the movement (shift operation) of the sheet S in the width direction is completed, the discharge roller 230 is lowered from the guide position to the contact position as shown in FIGS. It is sandwiched between the discharge belt 260 and the discharge belt 260 . Then, the sheet S is conveyed mainly by the discharge roller 230 and the discharge belt 260, and the sheet S is discharged onto the stacking tray 300 as shown in FIGS.

In such a productivity priority mode, since there is no operation of placing the sheets S on the processing tray 220 , the shift operation of the sheets S can be performed faster than when performing the shift operation on the processing tray 220 . In addition, since the aligning plate 271 is brought into contact with the sheet S in a state in which the sheet S hangs down and is curved during the shift operation, the sheet alignment and the shift operation can be performed in a state in which the sheet S has a higher rigidity, and the sheet is less likely to be bent. Align and shift operations can be performed on the state.

Further, in this embodiment, by moving the discharge roller 230 to the guide position, the leading end of the sheet S is pushed down so that the second contact portion 273 of the aligning plate 271 can be contacted more reliably. Since the aligning plate 271 abuts on the two width direction edges of the sheet S spaced apart in a predetermined direction, the shift operation of the sheet S can be performed in a more stable state. That is, the sheet can be moved in the width direction while suppressing skewing of the sheet during the shift operation.

Note that the productivity priority mode is preferably applicable to small-sized sheets, but may be executed to large-sized sheets. Further, for example, when the length of the sheet in the predetermined direction is short, the shift operation may be performed by bringing only the first contact portion 272 into contact with the edge of the sheet in the width direction.

[Shift mode (alignment priority)]
Of the shift modes, the alignment priority mode will be described with reference to FIGS. 26 to 32. FIG. Although the alignment priority mode may be performed for small-size sheets, the case of performing it for large-size sheets will be described here. As shown in FIGS. 26A and 26B, when the sheet SL is conveyed along the conveying path 210, the discharge roller 230 is at the retracted position, and the scraping portion 240 and trailing edge drop member 250 are at the first position. located respectively.

As shown in FIGS. 27A and 27B, when the trailing edge of the sheet SL passes through the pre-processing nip portion 211a, the discharge roller 230, the scraping portion 240, and the trailing edge dropping member 250 start descending. The discharge roller 230, the scraping portion 240, and the trailing edge dropping member 250 may start descending before the trailing edge of the sheet SL passes through the pre-processing nip portion 211a. In any case, when the trailing edge of the sheet SL is dropped toward the processing tray 220 by the scraping portion 240 and the trailing edge dropping member 250, if the timing is such that the trailing edge of the sheet SL passes through the pre-processing nip portion 211a, good.

As shown in FIGS. 28A and 28B, the discharge roller 230 is lowered to the contact position, and the scraping portion 240 and the trailing edge dropping member 250 are lowered to the second position. As a result, the sheet SL discharged from the conveying path 210 is nipped between the discharge roller 230 and the discharge belt 260 , and the trailing edge of the sheet SL is directed toward the processing tray 220 by the scraping portion 240 and the trailing edge dropping member 250 . It is dropped and placed on the processing tray 220 . At this time, the sheet SL is also pinched between the scraping belt 240 a of the scraping portion 240 and the discharge belt 260 .

Next, as shown in FIGS. 29A and 29B, the scraping belt 240a and the discharge belt 260 are rotated in opposite directions to remove the sheet SL placed on the processing tray 220 from the trailing edge regulating member. Transport to 290. At this time, the return member 280 descends, and the knurled belt 281 of the return member 280 contacts the upper surface of the sheet SL on the trailing end side. By rotating the knurled belt 281 , the sheet SL is further conveyed, and the trailing edge of the sheet SL abuts against the trailing edge regulating member 290 . As a result, the sheet SL is aligned in a predetermined direction.

Next, as shown in FIGS. 30A and 30B, the discharge roller 230 is raised to the retracted position, the scraping portion 240 and the trailing edge dropping member 250 are raised to the first position, and the return member 280 is raised. to retract these members from the upper surface of the sheet SL. In this state, the front and rear aligning plates 271 are moved in the width direction to align and shift the sheet SL in the width direction. At this time, since the sheet SL is placed on the processing tray 220 , it contacts the second contact portion 273 of the alignment plate 271 . The second contact portion 273 is arranged from below the first contact portion 272 to the downstream side of the first contact portion 272 in a predetermined direction, and covers the width of the sheet SL in a relatively wide range in the predetermined direction. It abuts the direction edge. In addition, the second contact portion 273 is configured such that the leading edge of the sheet SL placed on the processing tray 220 protrudes toward the stacking tray 300 from the downstream end of the processing tray 220 in the predetermined direction, and the width direction edge of the sheet SL is moved. abut the edge.

When the shift operation of the sheet SL is completed, as shown in FIGS. 31A and 31B, the discharge roller 230 is lowered to the contact position, and the sheet SL is nipped between the discharge roller 230 and the discharge belt 260. . By rotating the discharge belt 260 in the forward direction, the sheet SL is discharged from the processing tray 220 to the stacking tray 300 as shown in FIGS.

As described above, in the alignment priority mode, the sheets SL are aligned and shifted on the processing tray 220, so the alignment of the sheets SL can be made better than in the productivity priority mode. In particular, in the alignment priority mode, the sheet SL is placed on the processing tray 220, the trailing edge of the sheet SL abuts against the trailing edge regulating member 290, and the second contact portion 273 moves over the entire predetermined direction of the sheet SL. The shift operation is performed by contacting the edges in the width direction. The length of the entire predetermined direction of the second contact portion 273 is longer than the sum of the length of the first contact portion 272 and part of the second contact portion that contact the sheets in the productivity priority mode. In the mode, the aligning plate 271 can be brought into contact with the edges of the sheet in the width direction over a wide range.

Further, in the productivity priority mode, the shift operation is performed while the sheet hangs down from the conveying path 210 , whereas in the alignment priority mode, the shift operation is performed while the sheet is placed on the processing tray 220 . Therefore, the sheet shift operation can be performed in a stable state. Furthermore, since the leading edge of the sheet SL protrudes further toward the stacking tray 300 than the processing tray 220 , the leading edge of the sheet SL hangs down on the stacking tray 300 and is curved. Therefore, the shift operation of the seat SL can be performed in a state in which the rigidity of the seat SL is higher than in a state in which the seat SL is not curved. For this reason, in the alignment priority mode, the alignment of the sheets SL can be made better than in the productivity priority mode.

However, in the alignment priority mode, since there is an operation to once place the sheets on the processing tray 220, processing takes longer than in the productivity priority mode. However, in the case of a large size sheet, even processing in the image forming apparatus 100 takes time. Therefore, when the alignment priority mode is executed for large size sheets, the shift operation can be performed with productivity suitable for the productivity of the image forming apparatus 100, and the alignment of the sheets can be improved. Note that the productivity priority mode as described above may be executed even for large size sheets.

[Staple Mode]
The staple mode will be described with reference to FIGS. 33 to 41. FIG. As shown in FIGS. 33A and 33B, when the first sheet S1 is conveyed to the conveying path 210, the discharge roller 230 is at the retracted position, and the scraping portion 240 and the trailing edge drop member 250 are at the retracted position. Each is located at the first position. When the trailing edge of the sheet S1 passes through the pre-processing nip portion 211a, similarly to FIG. The roller 230 is lowered to the contact position, and the raking portion 240 and the trailing edge dropping member 250 are lowered to the second position. That is, the sheet S1 discharged from the conveying path 210 is placed on the processing tray 220, and the sheet S1 is nipped between the discharge roller 230 and the discharge belt 260. 260 is also sandwiched. The discharge roller 230, the scraping portion 240, and the trailing edge dropping member 250 may start descending before the trailing edge of the sheet S1 passes through the pre-processing nip portion 211a.

Next, as shown in FIGS. 34A and 34B, the scraping belt 240a and the discharge belt 260 are rotated in opposite directions, and the sheet S1 placed on the processing tray 220 is moved to the trailing end regulating member. Transport to 290. At this time, the return member 280 descends, and the knurled belt 281 of the return member 280 contacts the upper surface of the sheet S1 on the trailing edge side. By rotating the knurled belt 281 , the sheet S<b>1 is further conveyed, and the trailing edge of the sheet S<b>1 hits the trailing edge regulating member 290 . As a result, the sheet S1 is aligned in a predetermined direction.

Next, as shown in FIGS. 35A and 35B, the discharge roller 230 is raised to the retracted position, the scraping portion 240 and the trailing edge dropping member 250 are raised to the first position, and the return member 280 is raised. to retract these members from the upper surface of the sheet S1. In this state, the front and rear aligning plates 271 are moved in the width direction to align the sheet S1 in the width direction. At this time, since the sheet S<b>1 is placed on the processing tray 220 , it contacts the second contact portion 273 of the alignment plate 271 . The process up to this point is the same as in alignment priority mode.

Next, as shown in FIGS. 36A and 36B, the return member 280 is lowered so that the trailing edge of the sheet S1 is moved between the knurled belt 281 and the processing tray 220 in preparation for the second sheet. sandwiched. As a result, even if the second sheet is conveyed onto the processing tray 220, it is possible to prevent the first sheet S1 from shifting. In this state, as in the case where the first sheet S1 is placed on the processing tray 220, the second sheet S2 discharged from the conveying path 210 is placed on the sheet S1 placed on the processing tray 220. be placed on.

Then, as shown in FIGS. 37A and 37B, the scraping belt 240a and the discharge belt 260 are rotated in opposite directions to remove the first sheet S2 placed on the processing tray 220. It is conveyed toward the trailing edge regulating member 290 . At this time, the return member 280 is once raised and then lowered at the timing when the trailing edge of the sheet S2 reaches the return member 280 . Then, the knurled belt 281 of the return member 280 contacts the upper surface of the sheet S2 on the trailing edge side. By rotating the knurled belt 281 , the sheet S<b>2 is further conveyed, and the trailing edge of the sheet S<b>2 hits the trailing edge regulating member 290 . As a result, the sheet S2 is aligned in a predetermined direction. When the number of sheets to be placed on the processing tray 220 is the second one or more, the scraping belt 240a alone is rotated in the opposite direction without rotating the discharge belt 260, and the sheet is removed in the same manner as the first sheet. The rear end abuts against the rear end regulating member 290 . Even when the trailing edge of the first sheet hits the trailing edge regulating member 290, only the scraping belt 240a may be rotated in the opposite direction without rotating the discharge belt 260. FIG.

Next, as shown in FIGS. 38A and 38B, the discharge roller 230 is raised to the retracted position, the scraping portion 240 and the trailing edge dropping member 250 are raised to the first position, and the return member 280 is raised. to retract these members from the upper surface of the sheet S2. In this state, the front and rear aligning plates 271 are moved in the width direction to align the sheet S2 in the width direction. The operation of placing the sheets on the processing tray 220 and aligning the sheets on the processing tray 220 is performed for the number of sheets based on the input job information, and the sheet bundle ST is formed on the processing tray 220 .

After forming the sheet bundle ST, as shown in FIGS. 39A and 39B, the stapling unit 400 is driven to staple the sheet bundle ST. After stapling, as shown in FIGS. 40A and 40B, the front and rear aligning plates 271 are retracted from the width direction edges of the sheet bundle ST, and the discharge roller 230 is moved to the contact position to move the raking portion. 240 are each lowered to the second position. As a result, the sheet bundle ST is sandwiched between the discharge roller 230 and the scraping belt 240 a and the discharge belt 260 . By driving the discharge belt 260 and the scraping belt 240a, the sheet bundle ST is discharged from the processing tray 220 to the stacking tray 300 as shown in FIGS.

As described above, in this embodiment, the sheet bundle ST is discharged by driving the scraping belt 240 a in addition to the conveyance by the discharge roller 230 and the discharge belt 260 . In particular, the scraping belt 240a has a stretched surface that contacts the upper surface of the sheet bundle ST, so that the conveying force of the sheet bundle ST is high. Therefore, it is possible to more reliably discharge the sheet bundle ST from the processing tray 220 .

Here, in order to increase the sheet conveying force, it is conceivable to increase the contact pressure (nip pressure) of the discharge roller 230 against the discharge belt 260 . However, in this case, it is necessary to secure the strength of the structure that supports the discharge roller 230, which increases the size of the apparatus. Also, if the discharge roller 230 is brought into strong contact with the sheet, show-through may occur. Therefore, in the present embodiment, a scraping belt 240a is brought into contact with the sheet separately from the discharge roller 230 so that the scraping belt 240a assists the sheet discharge.

Therefore, the nip pressure of the discharge roller 230 does not need to be increased more than necessary, so that the size of the apparatus can be suppressed, and the occurrence of show-through can be suppressed. Further, the scraping belt 240a has a function of conveying the sheet on the processing tray 220 toward the trailing end regulating member 290. The direction of rotation of the scraping belt 240a is simply switched from time to time. Therefore, the size of the device can be reduced as compared with the case where each function is provided separately.

[Sheet discharge operation]
An operation of discharging sheets to the stacking tray 300 in this embodiment will be described with reference to FIGS. 42 to 46. FIG. First, as shown in FIGS. 42A and 42B, the sheet S is nipped and conveyed between the discharge roller 230 and the discharge belt 260 to be discharged onto the stacking tray 300 . At this time, the stacking tray 300 is at the first stacking position. The first stacking position is the home position when no sheets are stacked on the stacking tray 300, and is a position determined according to the stacking amount when sheets are stacked.

Next, in the stacking tray 300 , the downstream end (leading end) of the sheet S discharged by the discharge roller 230 and the discharge belt 260 is placed on the sheet stacking surface 301 of the stacking tray 300 or the sheet stacking surface 301 . After contacting the sheet, the stacking tray 300 descends from the first stacking position to the second stacking position so as to reach the second stacking position. In this embodiment, as shown in FIGS. 43A and 43B, when the trailing edge of the sheet S passes through the discharge nip portion 230a between the discharge roller 230 and the discharge belt 260, the stacking tray 300 is moved to the first position. Start descending from the loading position toward the second loading position. The sheet pressing belt 320 is stretched over rollers 321 in a bent state. Therefore, when the stacking tray 300 is at the first stacking position, the sheet pressing belt 320 is slightly pushed up by the sheets placed on the stacking tray 300 . Even if the stacking tray 300 is lowered from the first stacking position to the second stacking position from this state, the sheet pressing belt 320 does not contact the sheets on the stacking tray 300 until the bending of the sheet pressing belt 320 is eliminated. Therefore, the sheet pressing effect of the sheet pressing belt 320 continues for a predetermined interval after the stacking tray 300 starts to descend.

When the sheet S is discharged from the discharge nip portion 230a, as shown in FIGS. The rear end of the sheet S is guided toward the stacking tray 300 by rotating and contacting the upstream end (rear end).

As described above, the sheet pressing belt 320 is a knurled belt, and a roller for driving the sheet pressing belt 320 is also provided on the drive shaft 261 a of the tension roller 261 that drives the discharge belt 260 . Therefore, the sheet pressing belt 320 rotates in synchronization with the ejection belt 260 . At least a part of the sheet pressing belt 320 is provided so as to protrude downstream from the standing surface 310 in a predetermined direction and below the sheet loading surface of the processing tray 220 . Therefore, by rotating the sheet pressing belt 320 , the trailing edge of the sheet S that has passed through the discharge nip portion 230 a is guided to the stacking tray 300 so as to be scraped off by the sheet pressing belt 320 . That is, the trailing edge of the sheet S is scraped off by the sheet pressing belt 320 like the locus of the sheet indicated by the dotted line and broken line in FIG. 44(b). This makes it difficult for the trailing edge of the sheet S to remain in the discharge nip portion 230a.

Next, after the upstream end of the sheet S in a predetermined direction is discharged onto the sheet stacking surface 301 or the sheets placed on the sheet stacking surface 301, the stacking tray 300 is stacked so as to reach the first stacking position. The tray 300 rises from the second stacking position to the first stacking position. In this embodiment, as shown in FIGS. 45A and 45B, after the trailing edge of the sheet S is discharged onto the stacking tray 300, the stacking tray 300 moves from the second stacking position toward the first stacking position. Start rising. As the stacking tray 300 is thus lifted from the second stacking position to the first stacking position, the sheet pressing belt 320 presses the upper surface of the trailing edge of the sheet S discharged onto the stacking tray 300 .

Next, as shown in FIGS. 46A and 46B, the sheet pressing belt 320 lifts the sheet S on the stacking tray 300 from the second stacking position to the first stacking position. Convey toward surface 310 . That is, by rotating the sheet pressing belt 320 , the sheet S on the stacking tray 300 is picked up and the trailing edge of the sheet S abuts against the standing surface 310 . At this time, the sheet pressing belt 320 may contact the upper surface of the sheet S while rotating, or may rotate after contacting the upper surface of the sheet S. FIG. That is, when the stacking tray 300 is raised from the second stacking position to the first stacking position, the rotation of the sheet pressing belt 320 may be started at least before the stacking tray 300 reaches the first stacking position. The rotation of the sheet pressing belt 320 may be started after the tray 300 reaches the first stacking position. In any case, the rotation of the sheet pressing belt 320 is stopped at the timing after the trailing edge of the sheet S hits the standing surface 310 .

In this embodiment, the upper surface of the sheet S discharged onto the stacking tray 300 is pressed by the sheet pressing belt 320 . For this reason, the stacking tray 300 can be moved up and down between the first stacking position and the second stacking position, and can be lowered from the first stacking position and raised from the second stacking position as described above in accordance with the discharge of the sheets. controlling the timing. A sheet pressing belt 320 provided at the downstream end of the processing tray 220 in a predetermined direction presses the upper surface of the trailing edge of the sheet discharged onto the stacking tray 300 .

Accordingly, even if the next sheet is discharged onto the sheet S placed on the stacking tray 300, the sheet S can be prevented from being shifted. Depending on the angle of the stacking tray 300, the trailing edge of the previously discharged sheet S may be held down by the sheet pressing belt 320 after the leading edge of the next sheet contacts. That is, when the sheet loading surface 301 of the stacking tray 300 is inclined with respect to the horizontal plane so that the downstream side in a predetermined direction faces upward, and if this angle is large, the leading edge of the next sheet has already been loaded. Even if it contacts the upper surface of the sheet, the sheet does not slip easily. Therefore, in such a case, the next sheet is discharged so that the leading edge of the next sheet comes into contact with the sheet S before the stacking tray 300 on which the sheet S is placed reaches the first stacking position. Also good.

In any case, in this embodiment, the sheet pressing belt 320 has a function of pressing the trailing edge of the sheet S discharged onto the stacking tray 300 and a function of scraping off the trailing edge of the sheet S so that it does not remain in the discharge nip portion 230a. have Therefore, in the case of this embodiment, the cost can be reduced as compared with the case where mechanisms having these functions are provided separately.

[Other embodiments]
In the above-described embodiment, the sheet processing apparatus 200 is arranged in the internal space 130 of the image forming apparatus 100. However, the sheet processing apparatus of the present invention may be mounted on the side surface of the image forming apparatus, for example. It may be a configuration. Also, the sheet processing apparatus may be configured to be controlled by a control section provided in the image forming apparatus.

200 Sheet processing apparatus 210 Conveying path 211 Pre-processing roller 212 Conveying belt 220 Processing tray 230 Discharge roller 240 Scraping unit 240a Scraping Loading belt 250 Trailing end dropping member 260 Ejecting belt 270 Aligning part 271 Aligning plate 280 Returning member 290 Trailing end regulating member 300 Loading tray 310 Standing surface 320 Seat holding belt 400 Staple unit

Claims (10)

a conveying rotor pair that nips a sheet in a nip portion and conveys it in a predetermined direction;
a processing tray on which the sheet conveyed by the pair of conveying rotators can be placed;
regulating means for regulating the upstream end of the sheet placed on the processing tray in the predetermined direction;
a transfer means for transferring the sheet placed on the processing tray toward the regulation means;
a processing unit that performs a predetermined process on the sheet placed on the processing tray and whose upstream end in the predetermined direction is regulated by the regulating unit;
a discharge belt capable of discharging the sheet placed on the processing tray downstream in the predetermined direction;
The transfer means can be moved to a first position above the nip portion of the pair of conveying rotating bodies, and can contact the upper surface of the sheet placed on the processing tray to transfer the sheet toward the regulation means. and a moving means for moving between a second position,
The sheet processing apparatus according to claim 1, wherein, at the second position, the transfer means sandwiches the sheet placed on the processing tray between itself and the discharge belt. The moving means includes a support member that supports the transfer means, and a rotation shaft that rotatably supports the support member. The sheet processing apparatus according to claim 1, wherein the sheet processing apparatus is rotatable in the direction of a discharge rotating body that sandwiches the sheet between itself and the discharge belt;
3. The sheet processing apparatus according to claim 1, wherein, at the second position, the transfer means is positioned between the conveying rotor pair and the discharging rotor with respect to the predetermined direction. It is arranged on both sides of the transport means in the width direction of the sheet intersecting the transport direction of the sheet, and moves vertically in conjunction with the transport means so that the upstream end of the sheet in the predetermined direction moves the pair of transport rotators. a pair of upstream end dropping members for dropping the upstream end of the sheet in the predetermined direction toward the processing tray after passing through the sheet;
Out of the pair of upstream edge dropping members, the discharge rotating body is arranged between the upstream edge dropping member on one side and the transfer means and between the upstream edge dropping member on the other side and the transfer means. 4. The sheet processing apparatus according to claim 3, characterized in that: 5. The sheet processing according to any one of claims 1 to 4, wherein the transporting means can transport the sheet placed on the processing tray together with the discharge belt downstream in the predetermined direction. Device. The transfer means has a transfer belt and at least two rollers on which the transfer belt is stretched. 6. The sheet processing apparatus according to any one of claims 1 to 5, wherein the sheet processing apparatus is capable of coming into contact with the sheet placed on the plate. The discharge belt is stretched by two tension rollers,
7. The apparatus according to any one of claims 1 to 6, wherein, at the second position, the transfer means sandwiches the portion where the discharge belt is stretched and the sheet between the two tension rollers. Sheet processing apparatus as described. The discharge belt is stretched by two tension rollers,
3. The conveying means, at the second position, nips the sheet through the tension roller on the upstream side in the predetermined direction of the two tension rollers and the discharge belt. 7. The sheet processing apparatus according to any one of 6. The discharge belt is stretched by two tension rollers,
In the transfer means, at the second position, the portion where the transfer belt is stretched between the two rollers is the stretch roller on the upstream side in the predetermined direction of the two stretch rollers, and the 7. The sheet processing apparatus according to claim 6, wherein the sheet is nipped via a discharge belt. a conveying rotor pair that nips a sheet in a nip portion and conveys it in a predetermined direction;
a processing tray on which the sheet conveyed by the pair of conveying rotators can be placed;
trailing edge dropping means for dropping the upstream edge of the sheet conveyed by the pair of conveying rotators toward the processing tray;
regulating means for regulating the upstream end of the sheet placed on the processing tray in the predetermined direction;
a processing unit that performs a predetermined process on the sheet placed on the processing tray and whose upstream end in the predetermined direction is regulated by the regulating unit;
a discharge belt capable of discharging the sheet placed on the processing tray downstream in the predetermined direction;
Movement of the trailing edge dropping means between a first position positioned above the nip portion of the conveying rotor pair and a second position abutting on the upper surface of the sheet placed on the processing tray. comprising means and
The sheet processing apparatus, wherein the trailing edge dropping means clamps the sheet placed on the processing tray between itself and the discharge belt at the second position.

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