JP2013107771A - Paper processing device and image forming system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To discharge a paper bundle from any upper location above a process part such as a saddle stitching process part by simplifying a mechanism for changing a discharge direction of the paper bundle.SOLUTION: A paper discharge unit 39 of a paper processing device 3 includes a pair of rollers 63, 64 and paper discharge/loading drive parts 66, 67. At least one of the rollers 63, 64 is rotatable. The paper discharge/loading drive parts 66, 67 support the rollers so that the other roller 64 can rotate around a shaft center of one roller 63 and further the other roller 64 can come into contact with or can separate from the roller 63.

Description

  The present invention relates to a sheet processing apparatus having a saddle stitching processing unit that performs a saddle stitching process on a sheet bundle in which a plurality of folded sheets are stacked, and an image forming system including the sheet processing apparatus.

  The image forming system includes an image forming apparatus that forms an image on a sheet, and a sheet processing apparatus that performs various processes on the sheet on which the image is formed. The processing performed by the paper processing apparatus includes a middle folding process for folding the paper, a cutting process for cutting the edge of a paper bundle made up of a plurality of folded paper, and a folded one end of the paper bundle in a square shape. There is a square back processing formed on the back surface. Then, the sheet bundle subjected to various processes is discharged from the paper discharge unit.

  For example, Patent Document 1 discloses a paper discharge unit that discharges a bundle of paper. The paper discharge unit of the paper processing apparatus described in Patent Document 1 includes a pair of rollers provided in the vicinity of the saddle stitching processing unit. The paper discharge unit disclosed in Patent Document 1 sandwiches a sheet bundle that has undergone saddle stitching processing by a pair of rollers being driven to rotate, and is disposed below the saddle stitching processing unit in the vertical direction. The paper is discharged to the section.

  Japanese Patent Application Laid-Open No. 2004-228688 describes a paper discharge unit including an impeller having a plurality of blades and a gripper that holds a paper bundle, and a paper discharge conveyor that discharges the paper bundle. In the paper discharge unit disclosed in Patent Document 2, the blade receives a sheet bundle from the processing unit, and the gripper holds the sheet bundle. Then, the rotation direction of the impeller changes the direction in which the sheet bundle is discharged, and the sheet bundle is delivered to the sheet discharge conveyor disposed below the impeller by its own weight.

JP 2011-90093 A JP 2002-104703 A

  However, each of the paper discharge units of the paper processing apparatuses described in Patent Document 1 and Patent Document 2 discharges a bundle of sheets subjected to the saddle stitching process from below in the vertical direction than the saddle stitching processing section. Yes. Therefore, the user has to bend over in order to receive the discharged sheet bundle from the stacking unit.

  Further, the paper discharge unit in the paper processing device disclosed in Patent Document 2 includes a plurality of blades that receive a paper bundle and a plurality of grippers that hold the paper bundle in order to change the direction of discharge of the paper bundle. The impeller is provided with a gripper opening / closing mechanism. Therefore, in the technique disclosed in Patent Document 2, the mechanism for changing the direction of the sheet bundle is complicated, which leads to an increase in the size of the apparatus.

  An object of the present invention is to simplify the mechanism for changing the direction of discharge of a bundle of sheets in consideration of the actual situation in the above-described prior art, and to remove the bundle of sheets from above in a vertical direction with respect to a processing unit such as a saddle stitching processing unit. An object of the present invention is to provide a paper processing apparatus and an image forming system capable of discharging paper.

In order to solve the above-described problems and achieve the object of the present invention, a sheet processing apparatus according to the present invention includes a saddle stitching processing unit and a saddle stitching process in a stacking unit disposed above the saddle stitching processing unit in the vertical direction And a paper discharge unit that discharges the bundle of sheets bound by the unit. The saddle stitching processing unit binds a bundle of sheets formed by collecting a plurality of folded sheets with a staple.
The paper discharge unit includes a pair of rollers and a paper discharge stacking drive. At least one of the pair of rollers is rotatable. The discharge stacking drive unit rotates the other roller about the axis of one of the pair of rollers, and supports the other roller so as to be in contact with and away from the one roller.

The image forming system of the present invention includes an image forming apparatus that forms an image on a sheet and a sheet processing apparatus. The sheet processing apparatus includes a saddle stitching processing unit and a paper discharge unit. The saddle stitching processing unit binds a bundle of sheets formed by collecting a plurality of folded sheets with a staple. The paper discharge unit discharges the sheet bundle bound by the saddle stitching processing unit to a stacking unit that is disposed above the saddle stitching processing unit in the vertical direction.
The paper discharge unit includes a pair of rollers and a paper discharge stacking drive. At least one of the pair of rollers is rotatable. The discharge stacking drive unit rotates the other roller about the axis of one of the pair of rollers, and supports the other roller so as to be in contact with and away from the one roller.

  In the sheet processing apparatus and the image forming system configured as described above, the sheet bundle is gripped when the pair of rollers approach each other. Thereafter, the paper discharge stacking drive unit rotates the other roller, and the pair of rollers lifts the sheet bundle upward in the vertical direction against gravity. As a result, the position at which the sheet bundle is discharged onto the stacking unit can be changed upward in the vertical direction from the position at which the pair of rollers grips the sheet bundle.

  According to the sheet processing apparatus and the image forming system of the present invention, the sheet bundle can be discharged above the saddle stitching processing unit, and the user first receives the sheet bundle stacked on the stacking unit. Can do. Furthermore, it is possible to simplify the mechanism for changing the direction of discharging the sheet bundle.

1 is an overall configuration diagram showing an embodiment of an image forming system of the present invention. 1 is a schematic configuration diagram illustrating a sheet processing apparatus in an image forming system of the present invention. FIG. 3A is a schematic configuration diagram illustrating a saddle stitching processing unit in the sheet processing apparatus of the present invention, FIG. 3A is a schematic configuration diagram illustrating a state in which a first stapling process is performed in the saddle stitching processing unit, and FIG. It is a schematic block diagram which shows the state which performs the staple process of the 1st time, and FIG. 3C is a schematic block diagram which shows the state which the staple process was complete | finished. It is a schematic block diagram which shows the sheet | seat bundle conveyance part in the sheet processing apparatus of this invention. It is a perspective view which shows the composite process part in the paper processing apparatus of this invention. It is a side view which shows the composite process part in the paper processing apparatus of this invention. FIG. 6 is a side view showing a first paper discharge stacking drive unit of the paper discharge unit in the paper processing apparatus of the present invention. FIG. 6 is a perspective view illustrating a first paper discharge stacking drive unit of a paper discharge unit in the paper processing apparatus of the present invention. FIG. 6 is a side view illustrating a state in which the first roller and the second roller of the paper discharge unit of the present invention grip a sheet bundle. FIG. 6 is a perspective view illustrating a state in which a first roller and a second roller in the paper discharge unit of the present invention grip a sheet bundle. FIG. 6 is a side view showing a state in which a rotating member of a first paper discharge stacking drive unit in the paper discharge unit of the present invention is rotated. FIG. 6 is a perspective view illustrating a state in which a rotating member of a first discharge stacking driving unit in the discharge unit of the present invention is rotated. FIG. 6 is a perspective view illustrating a state in which a rotating member of a second discharge stacking drive unit in the discharge unit of the present invention is rotated. FIG. 6 is a side view showing a main part before rotation in the first paper discharge stacking drive unit of the paper discharge unit of the present invention. FIG. 6 is a side view showing a main part after rotation in the first paper discharge stacking drive unit of the paper discharge unit of the present invention. It is a perspective view which shows the state which the 1st roller and 2nd roller of the paper discharge unit part of this invention rotated. FIG. 6 is a side view of a second paper discharge stacking drive unit showing a state in which a sheet bundle is discharged in the paper discharge unit of the present invention. FIG. 6 is a perspective view of a second discharge stacking drive unit showing a state in which a sheet bundle is discharged in the discharge unit unit of the present invention. FIG. 6 is a perspective view of a first paper discharge stacking drive unit showing a state in which a paper bundle is discharged in the paper discharge unit of the present invention. FIG. 6 is a side view of a first paper discharge stacking drive unit showing a state in which a paper bundle discharge process is completed in the paper discharge unit of the present invention.

  Hereinafter, exemplary embodiments for implementing the sheet processing apparatus and the image forming system (hereinafter referred to as the present example) will be described with reference to FIGS. In each figure, the same code | symbol is attached | subjected to the common member. Note that the description in this section does not limit the technical scope and the meaning of terms described in the claims.

<Image forming system>
First, the image forming system of this example will be described with reference to FIG.
FIG. 1 is an overall configuration diagram showing an embodiment of an image forming system of the present invention.

  As shown in FIG. 1, the image forming system 1 includes an image forming apparatus 2 and a sheet processing apparatus 3 connected to the image forming apparatus 2.

[Image forming apparatus]
First, the image forming apparatus 2 will be described.
The image forming apparatus 2 forms an image on a sheet by an electrophotographic method, and includes a document conveying unit 11, an image reading unit 12, an image forming unit 13, an operation display unit 14, and a control unit 15.

  In addition, an example using an electrophotographic image forming apparatus as the image forming apparatus 2 has been described. However, the image forming apparatus 2 is not limited to this. Various other image forming system apparatuses may be applied to the image forming apparatus.

  The document transport unit 11 transports documents one by one to the reading position of the image reading unit 12. The image reading unit 12 reads an image of a document transported by the document transport unit 11 or a document placed on the document table 16 and generates an image signal.

  The image forming unit 13 includes a drum-shaped photoconductor 21, a charging unit 22 disposed around the photoconductor 21, an exposure unit 23, a developing unit 24, a transfer unit 25 </ b> A, a separation unit 25 </ b> B, and a cleaning unit 26. Yes. The charging unit 22 uniformly charges the surface of the photoconductor 21. The exposure unit 23 performs exposure scanning on the photoconductor 21 based on image data read from the document to form a latent image. The developing unit 24 reversely develops the latent image by attaching toner to form a toner image on the surface of the photoreceptor 21.

  The paper S1 is stored in the paper storage unit 27. The sheet S1 is fed by the sheet feeding unit 28A and sent to the transfer position. The transfer unit 25A transfers the toner image onto the sheet S1 sent to the transfer position. The separation unit 25B erases the charge on the back surface of the sheet S1 to which the toner image is transferred, and separates the sheet S1 from the photosensitive member 21. The sheet S1 separated from the photoreceptor 21 is transported by the intermediate transport unit 28B and sent to the fixing unit 29. The fixing unit 29 heats and presses the sheet S1 to fix the toner image.

  A switching gate 28C is arranged downstream of the fixing unit 29 in the transport direction of the sheet S1. The switching gate 28C switches the transport path of the paper S1 that has passed through the fixing unit 29. That is, the switching gate 28C moves the sheet S1 straight when performing face-up discharge in single-sided image formation. As a result, the sheet S1 is discharged by the pair of discharge rollers 28D. The switching gate 28C guides the sheet S1 downward when performing face-down paper discharge and double-sided image formation in single-sided image formation.

  When performing face-down paper discharge, after the paper S1 is guided downward by the switching gate 28C, the paper transport direction is switched when the rear end of the paper S1 passes the switching gate 28C, and the pair of paper discharge rollers 28D is used. Eject paper. When double-sided image formation is performed, the sheet S1 is guided downward by the switching gate 28C and then sent to the sheet reverse conveyance unit 28E. Then, the paper S1 that is reversed upside down is sent again to the transfer position via the refeed path 28F.

  The cleaning unit 26 removes toner remaining on the surface of the photoreceptor 21.

  The operation display unit 14 has a touch panel or the like, and functions as an input unit for inputting job information for the user to operate the image forming apparatus 2 and the sheet processing apparatus 3. In the operation display unit 14, for example, selection of a paper size, selection of the number of sheets, and the like can be input as job information. Further, selection of whether or not the staple processing is performed by the sheet processing apparatus 3, the number of sheets to be bound in the staple processing, and the like can be input as job information. The job information input on the operation display unit 14 is transmitted to the control unit 15.

  The operation display unit 14 also has a start button. When the user presses the start button, the image forming apparatus 2 and the sheet processing apparatus 3 start operations related to the job information input from the operation display unit 14.

  The control unit 15 controls the image forming operation of the image forming apparatus 2 based on the received job information. Further, the communication unit 15 a of the control unit 15 is electrically connected to the communication unit 90 a of the paper processing control unit 90 in the paper processing apparatus 3, and serial communication is performed between the control unit 15 and the paper processing control unit 90. Has been done. Then, the sheet processing control unit 90 controls the sheet processing apparatus 3 to operate in conjunction with the image forming operation of the image forming apparatus 2.

[Paper Handling Device]
Next, the sheet processing apparatus 3 will be described with reference to FIGS.
FIG. 2 is a schematic configuration diagram showing the sheet processing apparatus 3.
The paper processing apparatus 3 is an apparatus that performs various processes such as a stapling process and a folding process on the paper supplied from the image forming apparatus 2.

  As shown in FIG. 2, the sheet processing apparatus 3 includes a receiving unit 31, a first sheet conveying unit 32, a middle folding processing unit 33, a second sheet conveying unit 34 (see FIG. 3), and saddle stitching. A processing unit 36 and a composite processing unit 37 are provided. The composite processing unit 37 includes a sheet bundle holding mechanism 51, a cutting processing unit 38, and a paper discharge unit unit 39 (see FIG. 6).

  A direction parallel to the horizontal direction in the sheet processing apparatus 3 and facing the image forming apparatus 2 and the sheet processing apparatus 3 is defined as a first direction X. A direction perpendicular to the first direction X and perpendicular to the vertical direction is defined as a second direction Y. A direction parallel to the vertical direction is defined as a third direction Z.

  The receiving unit 31 is provided on one side in the first direction X of the housing 30 in the paper processing apparatus 3. The receiving unit 31 opens on the surface of the housing 30 that faces the image forming apparatus 2. The paper S1 discharged from the paper discharge roller 28D (see FIG. 1) of the image forming apparatus 2 is inserted into the receiving unit 31.

  The first paper transport unit 32 includes a plurality of rollers 32 a driven by a motor (not shown) and a transport path 32 b disposed along the first direction X. The first paper transport unit 32 transports the paper S 1 received by the receiving unit 31 to the middle folding processing unit 33.

  The middle folding processing unit 33 includes two folding rollers 33a and 33a that are pressed against each other and a folding plate (not shown). The two folding rollers 33a and 33a rotate in opposite directions. The folding plate presses the sheet S and passes the center of the sheet S1 between the two folding rollers 33a and 33a. Thereafter, the two folding rollers 33a and 33a reverse the rotation direction and discharge the sheet S downward in the third direction Z. As a result, the sheet S1 is folded so that the center is convex upward in the third direction Z, and the middle folding process ends.

3A to 3C are schematic configuration diagrams of the saddle stitching processing unit 36 in the sheet processing apparatus 3 as viewed from the first direction X. FIG.
As illustrated in FIG. 3A, a second paper transport unit 34 is disposed below the two folding rollers 33 a and 33 a of the center folding processing unit 33 in the third direction Z. The second paper transport unit 34 is arranged along the second direction Y. The second paper transport unit 34 transports the paper S <b> 1 that has undergone the middle folding process by the middle folding processing unit 33 to the saddle stitching processing unit 36.

  The saddle stitching processing unit 36 includes a paper stacking unit 40, a staple processing unit 41, an alignment member 42, and a first stopper 44. The paper stacking unit 40 is formed in a substantially triangular shape when viewed from the second direction Y, and one top 40a faces upward in the third direction Z. On the top 40a of the sheet stacking unit 40, the inner side of the folded portion of the sheet S1 subjected to the middle folding process is placed. A plurality of sheets S1 are stacked on the sheet stacking unit 40 to form a sheet bundle S2.

  A staple processing unit 41 is arranged in the paper stacking unit 40. The staple processing unit 41 includes a needle receiving mechanism 41a disposed in the paper stacking unit 40, and a needle striking mechanism 41b facing the needle receiving mechanism 41a. The needle receiving mechanism 41a is supported by a support portion (not shown) so as to be movable in the third direction Z. The needle striking mechanism 41b is fixed to an attachment member (not shown) above the third direction Z in the paper stacking unit 40, that is, above the needle receiving mechanism 41a.

  In addition, an alignment member 42 and a first stopper 44 are disposed above the third direction Z in the paper stacking unit 40. The alignment member 42 is configured to be movable in the second direction Y. The first stopper 44 is configured to be movable in the third direction Z and the second direction Y. Further, on the downstream side in the second direction Y in the paper stacking unit 40, a paper bundle transport unit 43 is disposed. A second stopper 45 is disposed above the sheet bundle conveying unit 43 in the third direction Z. The detailed configuration of the sheet bundle transport unit 43 will be described later.

Here, the saddle stitching processing operation in the saddle stitching processing unit 36 will be described with reference to FIGS. 3A to 3C.
First, as shown in FIG. 3A, the alignment member 42 presses the sheet bundle S2 against the first stopper 44 after a predetermined number of sheets S1 are accumulated on the sheet accumulation unit 40 to form the sheet bundle S2. Then, the sheet bundle S2 is aligned. Next, the staple receiving mechanism 41a of the staple processing unit 41 is raised to perform the first stapling process on the sheet bundle S2. At this time, the first stopper 44 moves to a predetermined height above the third direction Z.

  When the first stapling process is performed, the alignment member 42 moves a predetermined amount downstream in the second direction Y, as shown in FIG. 3B. As a result, the sheet bundle S2 is pushed out to the position where the second stapling process is performed by the alignment member 42. Then, the needle receiving mechanism 41a of the staple processing unit 41 is raised, and the second staple process is performed on the sheet bundle S2.

  During the second stapling process, the first stopper 44 moves to the middle folding processing unit 33 side in the second direction Y and is positioned above the upstream end of the sheet bundle S2. . Further, the alignment member 42 moves in the second direction Y and performs a retreat operation to a predetermined position.

  When the second stapling process is performed, as shown in FIG. 3C, the first stopper 44 is lowered to a position facing the upstream end of the sheet bundle S2. Subsequently, the first stopper 44 moves to the second stopper 45 side in the second direction Y. As a result, the sheet bundle S2 is pushed out by the first stopper 44 and moves from the sheet stacking unit 40 to the sheet bundle conveying unit 43.

  In this example, an example in which the stapling process is performed will be described, but the sheet bundle S2 subjected to the half-folding process may be transported to the composite processing unit 37 without performing the stapling process in the staple processing unit 41. .

Next, the sheet bundle conveyance unit 43 will be described with reference to FIG.
FIG. 4 is a schematic configuration diagram of the sheet bundle conveyance unit 43 in the sheet processing apparatus 3 as viewed from the second direction Y.

  The sheet bundle conveyance unit 43 conveys the sheet bundle S2 received from the sheet stacking unit 40 (see FIG. 3C) to a position immediately below the third direction Z in the sheet bundle holding mechanism 51 of the composite processing unit 37. As shown in FIG. 4, the sheet bundle transport unit 43 includes a sheet bundle placing member 46 and a sheet bundle moving mechanism 47.

  Similarly to the paper stacking unit 40 (see FIG. 1), the sheet stacking member 46 is formed in a substantially triangular shape when viewed from the second direction Y, and one top portion is in the third direction Z. It faces upward. The sheet bundle placing member 46 is supported by a sheet bundle moving mechanism 47 so as to be movable in the first direction X.

  The sheet bundle moving mechanism 47 includes a slide rail 47a disposed substantially parallel to the first direction X, a slide member 47b that slides on the slide rail 47a and supports the sheet bundle mounting member 46, and a slide member 47b. It is comprised from the drive part not shown which moves. Then, the sheet bundle S2 is conveyed by the sheet bundle conveying unit 43 to a position immediately below the third direction Z in the sheet bundle holding mechanism 51 of the composite processing unit 37.

[Composite processing section]
Next, the composite processing unit 37 will be described with reference to FIGS.
FIG. 5 is a perspective view showing the composite processing unit 37, and FIG. 6 is a side view of the composite processing unit 37.

  As shown in FIGS. 5 and 6, the composite processing unit 37 completes the processing with the sheet bundle holding mechanism 51 that holds the sheet bundle S2 subjected to the saddle stitching process, and the cutting processing unit 38 that cuts the sheet bundle S2. A paper discharge unit 39 for discharging the paper bundle S2 and a lifting mechanism 48.

  A cutting processing unit 38 is disposed in the lower part of the composite processing unit 37 in the third direction Z, and a paper discharge unit 39 is disposed in the upper part of the composite processing unit 37 in the third direction Z. . A sheet bundle holding mechanism 51 that is supported by the elevating mechanism 48 so as to be movable up and down in the third direction Z is provided between the trimming processing unit 38 and the paper discharge unit 39 in the composite processing unit 37.

  The elevating mechanism 48 includes a pair of frames 481, an elevating drive motor (not shown), a guide rail 483, a drive transmission shaft 484, and a timing belt 485. The pair of frames 481 are disposed on both sides in the second direction Y.

  A first pulley 486 is rotatably attached to the lower side of the pair of frames 481 in the third direction Z, and the second pulley 487 is attached to the upper side of the pair of frames 481 in the third direction Z. Is rotatably mounted. Further, the two first pulleys 486 provided on the pair of frames 481 are connected by a drive transmission shaft 484.

  Further, a timing belt 485 that is an endless belt is stretched around the first pulley 486 and the second pulley 487. An elevating part 488 is fixed to the timing belt 485. Further, the sheet bundle holding mechanism 51 is fixed to the elevating unit 488.

  As shown in FIG. 6, a drive transmission belt 489, which is an endless belt, hangs around a first pulley 486 provided on a frame 481 arranged on one side in the second direction Y of the pair of frames 481. Has been. The drive transmission belt 489 is stretched over a lifting drive pulley provided in the lifting drive motor.

  Further, the pair of frames 481 is provided with guide rails 483 extending along the third direction Z. As shown in FIG. 5, the guide rail 483 is formed in a substantially L shape when viewed from the third direction Z, and one piece is fixed to the frame 481. The guide rail 483 is attached so that slide members provided on both sides in the second direction Y of a sheet bundle holding mechanism 51 described later slide.

  When the lifting drive motor is driven, the sheet bundle holding mechanism 51 moves up and down along the guide rail 483 via the slide member.

  In this example, the belt feed mechanism is used as the lifting mechanism 48, but the present invention is not limited to this. As the lifting mechanism for moving the sheet bundle holding mechanism 51 up and down, other direct feed mechanisms such as a rack and pinion mechanism, a feed screw mechanism, a direct feed mechanism, and a linear motor drive mechanism can be applied.

  Further, the composite processing unit 37 is provided with a stopper mechanism 49 that temporarily supports the sheet bundle S2. The stopper mechanism 49 is disposed slightly below the approximate center in the third direction Z in the composite processing unit 37. The stopper mechanism 49 has a stopper portion 49a with which the lower end of the sheet bundle S2 in the third direction Z abuts, and a deployment portion 49b that deploys the stopper portion 49a.

  The stopper portion 49a is made of a substantially flat member, and is normally stored in the development portion 49b. When the sheet bundle S2 is supported, the stopper portion 49a is unfolded by the unfolding portion 49b so that its main surface intersects the hoistway in which the sheet bundle holding mechanism 51 moves up and down.

[Paper bundle holding mechanism]
As shown in FIG. 5, the sheet bundle holding mechanism 51 includes a pair of pressing members 51a and 51b that hold the sheet bundle S2 subjected to saddle stitching, and a drive mechanism 51c that moves the pressing members in the first direction X. Have. The sheet bundle holding mechanism 51 is driven and driven by the drive mechanism 51c so that the pair of pressing members 51a and 51b approach and separate. When the pair of pressing members 51a and 51b approach, the sheet bundle holding mechanism 51 holds the sheet bundle S2. Then, the sheet bundle holding mechanism 51 moves up and down in the third direction Z by the lifting mechanism 48 while holding the sheet bundle S2, and conveys the sheet bundle S2 to the cutting processing unit 38 or the paper discharge unit unit 39.

  Further, a square spine processing unit 55 is provided in the upper part of the sheet bundle holding mechanism 51 in the third direction Z. The spine processing unit 55 includes a pressing roller and a roller moving mechanism that moves the pressing roller along a portion of the sheet bundle S2 where the staple is applied. The square spine processing unit 55 presses the upper end of the sheet bundle S2 in the third direction Z, that is, the stapled portion from the outside with a pressing roller, thereby causing the stapled portion of the sheet bundle S2 to be squared. Form on the back of the mold shape.

Next, the configuration of the paper discharge unit 39 will be described.
As shown in FIG. 5, the paper discharge unit 39 includes a pair of paper discharge frames 61 and 62, a first roller 63, a second roller 64, a first paper discharge stacking drive unit 66, 2, a sheet stacking drive unit 67, a stacking unit 68, a sheet bundle pressing member 69, and a semicircular guide plate 70.

  The first paper discharge frame 61 is disposed on one side in the second direction Y in the composite processing unit 37, and the second paper discharge frame 62 is disposed on the other side in the second direction Y. Each of the first paper discharge frame 61 and the second paper discharge frame 62 is formed by a substantially flat plate-like member, and is directed upward in the third direction Z on one side of the first direction X. Projecting connection pieces 61a and 62a are provided.

  A connecting bar 73 that connects the first paper discharge frame 61 and the second paper discharge frame 62 is fixed to the connection pieces 61a and 62a. A sheet bundle pressing member 69 is provided at the approximate center of the connecting bar 73 in the second direction Y.

  In addition, a stacking unit 68 and a guide plate 70 are disposed between the first paper discharge frame 61 and the second paper discharge frame 62. The guide plate 70 is provided on one side in the first direction X in the first paper discharge frame 61 and the second paper discharge frame 62. A discharge port 74 for discharging the sheet bundle S2 is formed by the guide plate 70, connection pieces 61a and 62a of the first discharge frame 61 and the second discharge frame 62, and the connecting bar 73.

  Further, a first roller 63 is provided in the approximate center of the guide plate 70 in the second direction Y. A first rotation shaft 78 (see FIG. 7) serving as the rotation center of the first roller 63 is rotatably supported by the pair of frames 61 and 62.

  The stacking unit 68 is formed in a substantially flat plate shape and is disposed on the upper part of the sheet processing apparatus 3 in the vertical direction (see FIG. 1). The stacking unit 68 is provided with a transport belt 71 that transports the stacked sheet bundle S2. The transport belt 71 is formed in an endless shape, and extends from one end of the stacking unit 68 in the first direction X to the other end. The conveyor belt 71 is rotated by a driving unit (not shown). Further, a sheet pressing member 69 is disposed above the stacking unit 68 in the third direction Z.

  The paper pressing member 69 is supported by support pieces provided on the pair of paper discharge frames 61 and 62. The sheet pressing member 69 presses the sheet bundle S2 stacked on the stacking unit 68 and prevents the bent portion of the sheet bundle S2 from being swollen by the stiffness of the sheet.

  As shown in FIG. 6, the sheet pressing member 69 has a pressing roller 72 that is rotated by a drive unit (not shown). By rotating the pressing roller 72 and the above-described transport belt 71, the sheet bundle S2 is pushed away from the paper discharge port 74. Accordingly, the sheet bundle S2 can be prevented from collecting in the vicinity of the paper discharge port 74, and the sheet bundle S2 can be smoothly stacked on the stacking unit 68.

  Further, the first paper discharge frame 61 is provided with a first paper discharge stacking drive unit 66, and the second paper discharge frame 62 is provided with a second paper discharge stacking drive unit 67. Yes. The second rotation shaft 79 serving as the rotation center of the second roller 64 is rotatably supported by the first discharge stacking drive unit 66 and the second discharge stacking drive unit 67.

[First discharge stacking drive unit]
Next, the first paper discharge stacking drive unit 66 will be described with reference to FIGS.
FIG. 7 is a side view showing the first paper discharge stacking drive unit 66, and FIG. 8 is a perspective view showing the first paper discharge stacking drive unit 66.

  As shown in FIGS. 7 and 8, the first discharge stacking drive unit 66 includes an opening / closing rotation motor 601 serving as a drive source, a first opening / closing rotation gear 602, and a second example of a rotating body. Open / close rotation gear 603, rotation member 604, first paper discharge pulley 605, and guide member 610.

  The opening / closing rotation motor 601 is attached to the first paper discharge frame 61 and has a drive pulley 601a. A driven pulley 606 is disposed near the opening / closing rotation motor 601. A first transmission belt 607, which is an endless belt, is stretched between the driving pulley 601a and the driven pulley 606.

  A first opening / closing rotation gear 602 is disposed in the vicinity of the connection piece 61 a of the first paper discharge frame 61. The first opening / closing rotation gear 602 is fixed to one end of the drive transmission shaft 608 in the axial direction.

  The drive transmission shaft 608 passes through the first discharge frame 61 and the second discharge frame 62 and is rotatably supported by the first discharge frame 61 and the second discharge frame 62. At the other end of the drive transmission shaft 608 in the axial direction, a first opening / closing rotation gear 702 of a second discharge stacking drive unit 67 described later is provided (see FIG. 13). Therefore, the first opening / closing rotation gear 602 of the first discharge stacking drive unit 66 and the first opening / closing rotation gear 702 of the second discharge stacking drive unit 67 are integrally rotated by the drive transmission shaft 608. .

  Further, the first opening / closing rotation gear 602 is provided with an opening / closing rotation pulley 602a. A second transmission belt 609 that is an endless belt is stretched around the opening / closing rotation pulley 602a and the driven pulley 606. Therefore, the driving force of the opening / closing rotation motor 601 is transmitted to the first opening / closing rotation gear 602 via the first transmission belt 607, the driven pulley 606, and the second transmission belt 609.

  The first opening / closing rotation gear 602 is engaged with the second opening / closing rotation gear 603. The second opening / closing rotation gear 603 is rotatably supported by the first rotation shaft 78 that is the rotation center of the first roller 63. As shown in FIG. 8, the second opening / closing rotation gear 603 is provided with a connection pin 611 for changing the posture of the rotation member 604.

  The rotating member 604 is formed in a substantially flat plate shape, and is rotatably supported by a first rotating shaft 78 serving as a rotation center of the first roller 63 via a bearing (not shown). Further, the turning member 604 has a relief hole 604a formed by notching it in an arc shape.

  A connecting plate 614 that is an example of a connecting member is fixed to the rotating member 604 via a connecting portion 604b. The connecting plate 614 is rotatably supported by the first rotating shaft 78. A second opening / closing rotation gear 603 is disposed between the connecting plate 614 and the rotation member 604. The connection plate 614 is formed with a first contact portion 614a and a second contact portion 614b with which the connection pin 611 provided on the second opening / closing rotation gear 603 contacts. The center of the first rotating shaft 78 is disposed between the first contact portion 614a and the second contact portion 614b.

FIGS. 9 and 10 are views showing a state in which the second opening / closing rotation gear 603 is rotated, and FIGS. 11 and 12 are views showing a state in which the rotation member 604 is rotated.
As shown in FIGS. 9 and 10, when the second opening / closing rotation gear 603 rotates, the connection pin 611 contacts the second contact portion 614 b of the connection plate 614. When the second opening / closing rotation gear 603 further rotates in this state, the connecting plate 614 is pushed by the connecting pin 611 and rotates around the first rotating shaft 78. As a result, as shown in FIGS. 11 and 12, the rotating member 604 to which the connecting plate 614 is fixed also rotates together with the connecting plate 614. That is, the rotation member 604 is rotated by a cam mechanism including the connection pin 611 and the connection plate 614.

  As shown in FIG. 8, a first synchronization gear 616 is disposed between the rotation member 604 and the second opening / closing rotation gear 603. The first synchronous gear 616 is formed in a substantially fan shape, and teeth are formed only in the arc portion (see FIGS. 12 and 14). The first synchronization gear 616 is fixed to the rotating member 604 and is rotatably supported by the first rotating shaft 78 together with the rotating member 604. The first synchronous gear 616 rotates integrally with the rotating member 604 when the rotating member 604 rotates (see FIGS. 14 and 15).

  Further, the second synchronization gear 617 provided on the first paper discharge frame 61 is engaged with the first synchronization gear 616. The second synchronization gear 617 is fixed to one end of the synchronization shaft 618 in the axial direction.

  The synchronization shaft 618 passes through the first paper discharge frame 61 and the second paper discharge frame 62 and is rotatably supported by the first paper discharge frame 61 and the second paper discharge frame 62. A second synchronization gear 717 (see FIG. 13) of a second paper discharge stacking drive unit 67, which will be described later, is fixed to the other axial end of the synchronization shaft 618. Therefore, when the second synchronization gear 617 of the first paper discharge stacking drive unit 66 rotates, the second synchronization gear 717 of the second paper discharge stacking drive unit 67 rotates via the synchronization shaft 618.

  A first paper discharge pulley 605 is disposed between the first synchronization gear 616 and the second opening / closing rotation gear 603 (see FIG. 19). The first paper discharge pulley 605 is fixed to the first rotating shaft 78 by fixing means such as parallel pins. Therefore, the first paper discharge pulley 605 rotates together with the first rotating shaft 78, that is, the first roller 63.

  Further, a first discharge transmission belt 621 is stretched between the first discharge pulley 605 and a second discharge pulley 612b provided in a first discharge gear 612, which will be described later.

  The rotating member 604 is provided with a first paper discharge gear 612 and a second paper discharge gear 613 that mesh with each other. The first paper discharge gear 612 and the second paper discharge gear 613 are rotatably supported by the rotating member 604 via shafts 612a and 613a, respectively. The first paper discharge gear 612 is provided with a second paper discharge pulley 612b, and the second paper discharge gear 613 is provided with a third paper discharge pulley 613b.

  A first discharge transmission belt 621 is hung on a second discharge pulley 612b provided in the first discharge gear 612. Therefore, the rotational force of the first paper discharge pulley 605, that is, the rotational force of the first rotary shaft 78 is transmitted to the second paper discharge pulley 612b.

  A second discharge transmission belt 622 that is an endless belt is hung on the third discharge pulley 613b of the second discharge gear 613 that meshes with the first discharge gear 612. The second delivery belt 622 is also hung on a second roller pulley 623 provided on the second rotating shaft 79.

  Note that the second paper discharge gear 613 having the third paper discharge pulley 613b meshes with the first paper discharge gear 612, and therefore, the rotational force of the first paper discharge gear 612 generates the second paper discharge gear 612. It is transmitted to the gear 613. Therefore, the second rotating shaft 79 includes a first paper discharge pulley 605, a first paper discharge transmission belt 621, a second paper discharge pulley 612b, a third paper discharge pulley 613b, and a second paper discharge pulley. The rotational force of the first rotary shaft 78 is transmitted via the transmission belt 622. Therefore, the second roller 64 provided on the second rotation shaft 79 rotates together with the first roller 63 provided on the first rotation shaft 78.

  A swing member 624 is swingably supported on the shaft 613 a of the second paper discharge gear 613. The swing member 624 is formed in a flat plate shape having a substantially rectangular shape. One end of the swing member 624 in the longitudinal direction is supported by the shaft 613a of the second paper discharge gear 613 so as to be swingable, and the other end in the longitudinal direction is supported by the second rotary shaft 79 so as to be swingable. Has been. As a result, the second rotating shaft 79 provided with the second roller 64 swings about the shaft 613a of the second paper discharge gear 613.

  One end of the second rotating shaft 79 in the axial direction passes through a relief hole 604 a provided in the rotating member 604. The other end of the second rotating shaft 79 in the axial direction passes through the escape hole 704a of the rotating member 704 in the second discharge stacking drive unit 67 (see FIG. 13). The escape holes 604a and 704a are opened corresponding to the locus when the second rotating shaft 79 swings. Therefore, it is possible to prevent interference with the rotating member 604 when the second rotating shaft 79 swings.

  Further, a guide member 610 is rotatably provided at one end of the second rotation shaft 79 in the axial direction. The guide member 610 is formed in a flat plate shape having a substantially rectangular shape. The guide member 610 is formed with an open / close guide groove 628 that is opened in a substantially rectangular shape. A connecting pin 611 provided on the second opening / closing rotation gear 603 is engaged with the opening / closing guide groove 628 so as to be rotatable and slidable.

  Further, an urging member 625 is attached to one end of the connecting pin 611 and the second rotating shaft 79 in the axial direction. The urging member 625 is made of, for example, a tension coil spring. When the first roller 63 and the second roller 64 are opened (see FIG. 5), the connecting pin 611 and the second rotating shaft 79 are compressed. Intervened between.

Next, the second discharge stack driving unit 67 will be described with reference to FIGS.
FIG. 13 is a perspective view showing the second paper discharge stacking drive unit 67, and FIG. 17 is a side view showing the second paper discharge stacking drive unit 67. 13 shows a state in which the sheet bundle S2 is gripped, and FIG. 17 shows a state in which the sheet bundle S2 is gripped and the direction of paper discharge is changed.
The second discharge stacking drive unit 67 has substantially the same configuration as that of the first discharge stacking drive unit 66. Description is omitted.

  As shown in FIGS. 13 and 17, the second paper discharge stacking drive unit 67 includes a paper discharge motor 701 as a drive source, a first opening / closing rotation gear 702, a rotation member 704, and a first roller. And a guide member 710.

  As shown in FIG. 17, the paper discharge motor 701 is attached to the second paper discharge frame 62. The paper discharge motor 701 is provided with a drive pulley 701a.

  Further, a first opening / closing rotation gear 702 is disposed in the vicinity of the connection piece 62 a of the second paper discharge frame 62. Rotational force of the first opening / closing rotation gear 602 (see FIG. 7) of the first paper discharge stacking drive unit 66 is transmitted to the first opening / closing rotation gear 702 via the drive transmission shaft 608.

  The first opening / closing rotation gear 702 is engaged with the second opening / closing rotation gear 703. The second opening / closing rotation gear 703 is provided with a connecting pin 711 in the same manner as the second opening / closing rotation gear 603 of the first paper discharge stacking drive unit 66. The other configuration is the same as that of the second opening / closing rotation gear 603 of the first paper discharge stacking drive unit 66, and therefore the description thereof is omitted.

  Further, a guide pulley 708 is provided in the vicinity of the first opening / closing rotation gear 702. A first transmission belt 707 is stretched between the guide pulley 708 and the drive pulley 701a. Further, a second transmission belt 709 is hung on the guide pulley 708. As shown in FIG. 13, the second transmission belt 709 is also hung on a first roller pulley 705 provided on the first rotating shaft 78.

  The first roller pulley 705 is a one-way clutch and is attached to the first rotating shaft 78. The first roller pulley 705 is rotated by the driving force of the paper discharge motor 701 (see FIG. 17) transmitted from the second transmission belt 709. As the first roller pulley 705 rotates, the first rotating shaft 78, that is, the first roller 63 rotates.

  The rotation member 704 is rotatably supported by the first rotation shaft 78 in the same manner as the rotation member 604 of the first paper discharge stacking drive unit 66. Further, the rotation member 704 is formed with a relief hole 704a through which the second rotation shaft 79 is slidably passed and a connection portion 704b to which the connecting plate 714 is fixed. Note that the configuration of the connection plate 714 is the same as that of the connection plate 614 of the first paper discharge stacking drive unit 66, and therefore the description thereof is omitted.

  Further, the rotating member 704 is provided with a first synchronous gear 716 formed in a fan shape and a swing shaft 713. The first synchronization gear 716 meshes with a second synchronization gear 717 provided in the vicinity of the first opening / closing rotation gear 702 in the same manner as the first synchronization gear 616 of the first discharge stacking drive unit 66. Yes.

  A swing member 724 is swingably supported on the swing shaft 713. The swing member 724 is formed in a flat plate shape having a substantially rectangular shape. One end of the swinging member 724 in the longitudinal direction is supported by the swinging shaft 713 so as to be swingable, and the other end in the longitudinal direction is supported by the second rotating shaft 79 so as to be swingable.

  A guide member 710 is attached to the other end in the axial direction of the second rotation shaft 79, similarly to the first paper discharge stacking drive unit 66. Further, similarly to the first paper discharge stacking drive unit 66, a biasing member 725 is provided on the other end in the axial direction of the second rotation shaft and the connecting pin 711. The configurations of the guide member 710 and the biasing member 725 are the same as those of the guide member 610 and the biasing member 625 of the first paper discharge stacking drive unit 66, and thus the description thereof is omitted.

[Operation of Compound Processing Unit 37]
Next, the operation of the composite processing unit 37 will be described with reference to FIGS.
First, as shown in FIG. 6, the upper end in the third direction Z of the sheet bundle S2 conveyed from the saddle stitching processing unit 36 by the sheet bundle conveying unit 43 is held by the sheet bundle holding mechanism 51. Next, cutting is performed. When processing is performed, the elevating mechanism 48 is driven, and the sheet bundle holding mechanism 51 holding the sheet bundle S2 is lowered toward the cutting processing unit 38 side. When the sheet bundle holding mechanism 51 is lowered to a predetermined position, the cutting processing unit 38 performs a cutting process on the lower end portion in the third direction Z of the sheet bundle S2. At this time, since the sheet bundle S2 is held by the sheet bundle holding mechanism 51, it is possible to prevent the sheet bundle S2 from being displaced during the cutting process.

  Further, when the square back processing unit 55 performs the square back processing, the square back processing unit 55 is driven to form the stapled portion of the sheet bundle S2 on the square-shaped back surface.

  When a predetermined process is performed on the sheet bundle S2, the sheet bundle holding mechanism 51 is moved toward the sheet discharge unit 39 along the third direction Z by the elevating mechanism 48. As shown in FIG. 5, the stopper mechanism 49 is developed below the third direction Z of the sheet bundle S2. Then, the sheet bundle holding mechanism 51 temporarily releases the holding of the sheet bundle S2 by separating the pair of pressing members 51a and 51b. At this time, since the lower end of the sheet bundle S2 in the third direction Z is supported by the stopper mechanism 49, the sheet bundle S2 does not fall below the third direction Z of the composite processing unit 37.

  Next, the lifting mechanism 48 is driven, and the sheet bundle holding mechanism 51 moves in the third direction Z to the lower end side of the sheet bundle S2. When the sheet bundle holding mechanism 51 moves to a predetermined position, the sheet bundle holding mechanism 51 brings the pair of pressing members 51a and 51b closer to hold the sheet bundle S2 again. When the sheet bundle holding mechanism 51 completes holding the sheet bundle S2 again, the stopper mechanism 49 is stored.

  As a result, as shown in FIG. 5, the lower end side in the third direction Z of the sheet bundle S2 can be held, and a delivery allowance to the paper discharge unit 39 can be secured. As a result, the sheet bundle unit 39 can easily receive the sheet bundle S2 held by the sheet bundle holding mechanism 51, and the delivery operation of the sheet bundle S2 can be easily performed.

  When the sheet bundle holding mechanism 51 conveys the sheet bundle S2 to the sheet discharge unit 39, the second roller 64 of the sheet discharge unit 39 is separated from the first roller 63 as shown in FIG. The space between the first roller 63 and the second roller 64 is open. Hereinafter, the state of the paper discharge unit 39 is referred to as a receiving position. At this time, as shown in FIGS. 7 and 8, the connecting pin 611 provided on the second opening / closing rotation gear 603 is located on one side in the longitudinal direction of the opening / closing guide groove 628.

[Gripping operation]
Next, the gripping operation of the sheet bundle S2 will be described with reference to FIG. 9, FIG. 10, and FIG.
9, 10, and 14 are views showing the first paper discharge stacking drive unit 66 in a state where the sheet bundle S <b> 2 is gripped.

  As shown in FIG. 9, when the sheet bundle S2 is inserted at a predetermined position, that is, the upper end of the sheet bundle S2 in the third direction Z is inserted between the first roller 63 and the second roller 64, the first bundle 63 is inserted. The opening / closing rotation motor 601 provided in the paper discharge stacking drive unit 66 is driven, and the drive pulley 601a rotates in the direction of the arrow R1.

  When the opening / closing rotation motor 601 is driven, the driving force of the opening / closing rotation motor 601 is applied to the first opening / closing rotation gear 602 via the driving pulley 601a, the first transmission belt 607, the driven pulley 606, and the second transmission belt 609. Is transmitted. The first opening / closing rotation gear 602 is rotated by this driving force.

  As shown in FIG. 10, when the first opening / closing rotation gear 602 rotates, the second opening / closing rotation gear 603 engaged with the first opening / closing rotation gear 602 rotates. The rotational force of the first opening / closing rotation gear 602 is transmitted to the first opening / closing rotation gear 702 of the second discharge stacking drive unit 67 via the drive transmission shaft 608. Therefore, the first opening / closing rotation gear 702 of the second discharge stacking drive unit 67 rotates together with the first opening / closing rotation gear 602 of the first discharge stacking drive unit 66 (see FIG. 13).

  When the second opening / closing rotation gear 603 rotates, the connecting pin 611 provided on the second opening / closing rotation gear 603 rotates in the direction of the arrow R <b> 2 shown in FIG. 9 against the elastic force of the biasing member 625. To do. Then, the connection pin 611 moves from the first contact portion 614a of the connection plate 614 to the second contact portion 614b beyond the center of the first rotation shaft 78.

  At this time, the connecting pin 611 slides in the open / close guide groove 628 of the guide member 610 and contacts the other end of the open / close guide groove 628 in the longitudinal direction. When the connecting pin 611 further moves, the guide member 610 is operated by the connecting pin 611 and moves to the first rotating shaft 78 side of the first roller 63. Similarly, the guide member 710 of the second discharge stacking drive unit 67 also moves to the first rotating shaft 78 side.

  A second rotating shaft 79 is attached to one end of the guide member 610 in the longitudinal direction. The second rotating shaft 79 swings about the shaft 613 a of the second paper discharge gear 613 via the swinging member 624. Further, the swinging member 724 of the second discharge stacking drive unit 67 to which the other end of the second rotating shaft 79 is attached swings around the swinging shaft 713. That is, the second rotating shaft 79 is swung by a cam mechanism including the connecting pin 611 and the guide member 610 and a link mechanism including the guide member 610 and the swinging member 624.

  Then, the second roller 64 provided on the second rotating shaft 79 approaches the first roller 63. As a result, the sheet bundle S2 is gripped by the first roller 63 and the second roller 64.

  Here, the second rotating shaft 79 and the connecting pin 611 are connected by an urging member 625 that is a tension coil spring. The second rotating shaft 79 is urged toward the connecting pin 611, that is, the first rotating shaft 78 by the urging force generated when the urging member 625 extends. As a result, the second roller 64 is attracted to the first roller 63 side, so that rattling that occurs when the first roller 63 and the second roller 64 grip the sheet bundle S2 is prevented, and the sheet bundle S2 is strengthened. Can be gripped.

  Further, the biasing member 625 expands and contracts, so that the interval between the first roller 63 and the second roller 64 can be adjusted according to the thickness of the sheet bundle S2. Thereby, even the sheet bundle S2 with a small number of sheets can be reliably gripped by the first roller 63 and the second roller 64.

  The first roller pulley 705 provided on the first rotation shaft 78 of the first roller 63 is a one-way clutch, and the first rotation shaft 78 rotates only in the direction in which the sheet bundle S2 is discharged. Only power is transmitted. Therefore, the first rotating shaft 78, that is, the first roller 63 rotates only in the direction in which the sheet bundle S2 is discharged. As a result, when the sheet bundle S2 is gripped by the first roller 63 and the second roller 64, the first roller 63 can be prevented from rotating in the reverse direction and dropping the gripped sheet bundle S2. .

  Next, when the sheet bundle S2 is gripped by the first roller 63 and the second roller 64, the sheet bundle holding mechanism 51 releases the pair of pressing members 51a and 51b to release the holding of the sheet bundle S2. To do. As shown in FIG. 4, the sheet bundle holding mechanism 51 receives the sheet bundle S <b> 2 to be processed next after being conveyed by the sheet bundle conveyance unit 43.

[Direction change operation]
Next, the operation of changing the direction of discharging the sheet bundle S2 will be described with reference to FIGS.
11, 12, and 15 are views showing the first paper discharge stacking drive unit 66 in a state in which the rotating member 604 is rotated, and FIG. 13 is a diagram in which the rotating member 704 is rotated. 2 is a diagram illustrating a second paper discharge stacking drive unit 67. FIG. FIG. 16 is a perspective view showing the paper discharge unit 39 in a state where the second roller 64 is rotated.

  As shown in FIGS. 11 and 12, when the second opening / closing rotation gear 603 further rotates, the second contact portion 614b of the connection plate 614 is pushed by the connection pin 611, and the connection plate 614 is rotated in the first rotation. It rotates about the shaft 78 in the direction of arrow R2.

  In this example, the connecting plate 614 rotates approximately 90 degrees. The rotating member 604 to which the connecting plate 614 is fixed also rotates about the first rotation shaft 78. Further, as the rotation member 604 rotates, the second rotation shaft 79 supported by the swing member 624 provided on the rotation member 604 also rotates about the first rotation shaft 78. Note that the rotation member 704 of the second discharge stacking drive unit 67 similarly rotates about the first rotation shaft 78.

  Here, as shown in FIG. 14, a first synchronization gear 616 is fixed to the rotating member 604. Therefore, as the rotation member 604 rotates, as shown in FIG. 15, the first synchronization gear 616 rotates about the first rotation shaft 78 in accordance with the rotation of the rotation member 604. . Further, the second synchronization gear 617 that meshes with the first synchronization gear 616 rotates.

  As shown in FIG. 13, the second synchronization gear 717 of the second discharge stacking drive unit 67 is provided at the other end of the synchronization shaft 618 to which the second synchronization gear 617 is fixed. . For this reason, the first paper discharge stacking drive unit 66 rotates in synchronization with the second synchronization gear 617 and the second synchronization gear 717 of the second paper discharge stacking drive unit 67 via the synchronization shaft 618.

  Thereby, the first synchronous gears 616, 716, the second synchronous gears 617, 717, and the synchronous shaft 618 are used to turn the rotating member 604 of the first paper discharge stacking drive unit 66 and the second paper discharge stacking drive unit 67. The rotation operation of the rotation member 704 can be synchronized. As a result, it is possible to prevent the rotational operation from being shifted at one end and the other end in the axial direction of the second rotating shaft 79, thereby preventing the second rotating shaft 79 from being twisted. The rotating shaft 79 can be smoothly rotated.

  Next, when the turning operation of the turning member 604 is turned to a predetermined angle, the driving of the opening / closing turning motor 601 is stopped. As a result, as shown in FIG. 16, the transport direction of the sheet bundle S2 held by the first roller 63 and the second roller 64 is changed from the third direction Z to the first direction X by approximately 90 degrees. .

  Further, since the second roller 64 rotates around the first rotation shaft 78 of the first roller 63, the upper side in the third direction Z from the position where the sheet bundle S2 is received from the sheet bundle holding mechanism 51. Can lift up against gravity. As a result, the sheet bundle S2 faces the sheet discharge port 74 formed by the pair of sheet discharge frames 61 and 62, and the sheet bundle S2 is discharged from above the saddle stitching processing unit 36 (see FIG. 1). it can.

  Furthermore, according to the paper discharge unit 39 of this example, the gripping operation of the sheet bundle S2 by the first roller 63 and the second roller 64 and the sheet bundle S2 can be performed only by driving one opening / closing rotation motor 601. The direction of paper discharge can be changed. This makes it possible to reduce the size of the device.

[Output operation]
Next, the sheet discharge operation of the sheet bundle S2 will be described with reference to FIGS.
FIGS. 17 and 18 are diagrams showing the second paper discharge stacking drive unit 67 in a state in which the paper bundle S2 is discharged. FIG. 19 is a diagram illustrating the first paper discharge stacking drive unit 66 in a state in which the paper bundle S2 is discharged.

  As shown in FIG. 17, a paper discharge motor 701 provided in the second paper discharge stacking drive unit 67 is driven. As shown in FIGS. 17 and 18, when the paper discharge motor 701 is driven, the drive pulley 701a rotates in the direction of the arrow R3. Then, the driving force of the paper discharge motor 701 is transmitted from the driving pulley 701 a to the first roller pulley 705 via the first transmission belt 707, the guide pulley 708 and the second transmission belt 709.

  The first driving pulley 705 is rotated by the transmitted driving force, and the first rotating shaft 78 is rotated. Then, the first roller 63 provided on the first rotating shaft 78 rotates in the direction of discharging the sheet bundle S2.

  When the first rotating shaft 78 rotates, as shown in FIG. 19, the first paper discharge pulley 605 provided in the first paper discharge stacking drive unit 66 rotates. By rotating the first paper discharge pulley 605, the first paper discharge transmission belt 621, the first paper discharge gear 612, the second paper discharge gear 613, and the second paper discharge transmission belt 622 are used. Thus, the rotational force is transmitted to the second roller pulley 623. Since the second roller pulley 623 is fixed to the second rotating shaft 79, the second rotating shaft 79, that is, the second roller 64 rotates in the direction in which the sheet bundle S2 is discharged.

  Accordingly, the first roller 63 and the second roller 64 can be rotated by one paper discharge motor 701. Therefore, according to the paper discharge unit 39 of this example, the number of motors can be reduced, and the apparatus can be downsized.

  Then, as shown in FIG. 16, the sheet bundle S <b> 2 gripped by the first roller 63 and the second roller 64 is discharged to the stacking unit 68. When the paper discharge process for the sheet bundle S2 is completed, the drive of the paper discharge motor 701 is stopped, and the rotation of the first roller 63 and the second roller 64 is stopped.

  As described above, according to the paper discharge unit 39 of this example, the first roller 63 and the second roller 64 operate to grip the paper bundle S2, change the direction of the paper bundle S2, and discharge the paper bundle S2. Three processing operations are performed. Accordingly, it is not necessary to provide components according to each operation as in the conventional paper discharge unit, and the number of components can be reduced and the apparatus can be downsized.

[Operation finished]
Next, a state in which the sheet bundle S2 paper discharge process has been completed will be described with reference to FIG.
FIG. 20 is a side view of the first paper discharge stacking drive unit in a state where the paper discharge process for the sheet bundle S2 has been completed.

  As shown in FIG. 20, the opening / closing rotation motor 601 provided in the first discharge stacking drive unit 66 is driven in the direction of the arrow R4, which is the opposite direction to the arrow R1 shown in FIG. As a result, the second opening / closing rotation gear 603 rotates in the direction of the arrow R5. As the second opening / closing rotation gear 603 rotates, the connection pin 611 moves from the second contact portion 614b of the connection plate 614 to the first contact portion 614a beyond the first rotation shaft 78.

  When the connecting pin 611 moves, the guide member 610 engaged with the connecting pin 611 is operated and moved in a direction away from the first rotation shaft 78. Further, the second rotating shaft 79 attached to one end of the guide member 610 in the longitudinal direction swings around the shaft 613 a of the second paper discharge gear 613 via the swinging member 624.

  Further, the swinging member 724 of the second discharge stacking drive unit 67 to which the other end of the second rotating shaft 79 is attached swings around the swinging shaft 713. Then, the second roller 64 provided on the second rotating shaft 79 is separated from the first roller 63.

  When the second opening / closing rotation gear 603 and the connection pin 611 further rotate, the first contact portion 614 a of the connection plate 614 is pushed by the connection pin 611. Then, the rotating member 604 to which the connecting plate 614, the second rotating shaft 79, and the connecting plate 614 are fixed rotates around the first rotating shaft 78. As a result, the paper discharge unit 39 returns to the receiving position shown in FIGS. When the paper discharge unit 39 returns to the receiving position, the driving of the opening / closing rotation motor 601 is stopped.

  In addition, the paper discharge unit 39 is provided with a sensor (not shown) that detects the end of the operations of gripping the paper bundle S2, changing the direction of the paper bundle S2, and discharging the paper bundle S2. .

  The embodiments of the post-processing apparatus and the image forming system have been described above including the effects thereof. However, the post-processing apparatus and the image forming system of the present invention are not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention described in the claims. It is.

  In the embodiment described above, an example in which both the first roller 63 and the second roller 64 rotate to discharge the sheet bundle S2 has been described, but the first roller 63 or the second roller 64 has Of these, at least one of the rollers may be rotated.

  Further, the sheet bundle S2 is discharged after the direction of the sheet bundle S2 is changed, but the opening / closing rotation motor 601 and the discharge motor 701 are simultaneously driven to change the direction of discharge of the sheet bundle S2. The sheet discharge operation of the sheet bundle S2 may be performed while performing.

  Further, in order to change the direction of the sheet bundle S2, the example has been described in which the rotating member 604, the second rotating shaft 79, and the second roller 64 are rotated by approximately 90 degrees, but the present invention is not limited thereto. is not. The rotation angle of the rotation member 604, the second rotation shaft 79, and the second roller 64 is determined by the saddle stitching processing unit 36 by lifting the sheet bundle S2 against gravity when discharging the sheet bundle S2. Also, the angle may be less than 90 degrees as long as the sheet can be discharged upward.

  Further, in the above-described embodiment, the opening / closing rotation motor 601 is provided for the gripping operation and the direction changing operation of the sheet bundle S2, and the discharge motor 701 is provided for the discharge operation of the sheet bundle S2. It is not limited to. For example, a motor may be provided for each gripping operation, direction changing operation, and paper discharge operation, or all operations may be performed with a driving force of one motor.

For example, with the following configuration, all of the gripping operation, the direction changing operation, and the paper discharge operation can be performed with the driving force of one motor.
In the above-described embodiment, when the rotation member 604 rotates, the first opening / closing rotation gear 602 and the first paper discharge gear 612 provided on the rotation member 604 are engaged. As a result, the rotational force of the first opening / closing rotation gear 602 is transmitted to the first paper discharge gear 612. Note that when the first opening / closing rotation gear 602 and the first paper discharge gear 612 are engaged, the engagement between the first opening / closing rotation gear 602 and the second opening / closing rotation gear 603 is released.

  The rotational force transmitted to the first paper discharge gear 612 is transmitted through the first paper discharge transmission belt 621 to the first paper discharge pulley 605, the second paper discharge gear 613, and the second paper discharge gear 613. This is transmitted to the second roller pulley 623 via the paper delivery belt 622. As the first paper discharge pulley 605 and the second roller pulley 623 rotate, the first rotation shaft 78 and the second rotation shaft 79 rotate, and the first roller 63 and the second roller 64 rotate. To do.

  As a result, all of the gripping operation, the direction changing operation, and the paper discharge operation can be performed with a single motor. As a result, the number of parts can be reduced as compared with the above-described embodiment.

  Further, in the above-described embodiment, an example in which a single color image is formed has been described. However, the present invention may be applied to an image forming apparatus that forms a color image by providing a plurality of image forming units.

DESCRIPTION OF SYMBOLS 1 ... Image forming system, 2 ... Image forming apparatus, 3 ... Paper processing apparatus, 11 ... Document conveyance part, 12 ... Image reading part, 13 ... Image forming part, 14 ... Operation display part, 15 ... Control part, 16 ... Document 21: Photoconductor, 22: Charging unit, 23: Exposure unit, 24: Development unit, 25A ... Transfer unit, 25B ... Separation unit, 26 ... Cleaning unit, 27 ... Paper storage unit, 29 ... Fixing unit, 30 ... Housing 31, receiving unit 32 32, first sheet conveying unit 33, half-folding processing unit 34, second sheet conveying unit 36, saddle stitching processing unit 37, compound processing unit 38, cutting process , 39 ... paper discharge unit, 40 ... paper stacking unit, 41 ... staple processing unit, 43 ... paper bundle transport unit, 46 ... paper bundle placement member, 48 ... lifting mechanism, 51 ... paper bundle holding mechanism, 61 ... A first discharge frame, 2 ... 2nd paper discharge frame, 63 ... 1st roller, 64 ... 2nd roller, 66 ... 1st paper discharge stacking drive part, 67 ... 2nd paper discharge stacking drive part, 68 ... Stacking part, 74: paper discharge port, 78: first rotating shaft, 79: second rotating shaft, 601: opening / closing rotation motor (drive source), 602, 702 ... first opening / closing rotation gear, 603, 703 ... first 2 opening / closing rotation gears (rotating bodies), 604, 704 ... rotation members, 605 ... first discharge pulley, 610, 710 ... guide members, 611, 711 ... connection pins, 612 ... first discharge gears. 613 ... second discharge gear, 613a, 713 ... shaft (oscillating shaft), 614,714 ... connection plate (connection member), 616 ... first synchronization gear, 617 ... second synchronization gear, 623 ... Second roller pulley, 624, 724, swing member, 625 , 725 ... Biasing member, 701 ... Paper discharge motor (drive source), 705 ... Pulley for first roller, S1 ... Paper, S2 ... Paper bundle, H ... Height direction, W ... Width direction, D ... Depth direction, X ... 2nd direction, Y ... 1st direction, Z ... 3rd direction (vertical direction)

Claims (7)

A saddle stitching processing unit for binding a bundle of sheets formed by stacking a plurality of folded sheets with a staple,
A paper discharge unit that discharges the bundle of sheets bound by the saddle stitching processing unit on a stacking unit that is disposed vertically above the saddle stitching processing unit;
The paper discharge unit is
A pair of rollers, at least one of which is rotatable;
A paper discharge stacking drive unit that rotates the other roller around the axis of one of the pair of rollers and supports the other roller so as to be in contact with and away from the one roller; and
A paper processing apparatus. The sheet processing apparatus according to claim 1, further comprising: a sheet bundle holding mechanism that holds the sheet bundle bound by the saddle stitching processing unit and conveys the sheet bundle from the saddle stitching processing unit to the paper discharge unit unit. . The sheet processing apparatus according to claim 2, wherein the sheet bundle holding mechanism conveys the sheet bundle from a vertically lower side of the sheet discharge unit unit. The sheet processing apparatus according to claim 1, wherein the pair of rollers are rotatable only in a direction in which the sheet bundle is discharged to the stacking unit. The sheet processing apparatus according to claim 1, wherein the rotation of the other roller and the approach and separation of the other roller are driven by a single drive source. The paper discharge stacking drive unit
A rotating member rotatably supported by the axis of the one roller;
A connecting member fixed to the rotating member and rotatably supported by an axis of the one roller;
A rotating pin that is provided with a connecting pin that contacts the connecting member and rotates the connecting member, and is rotatably supported by the axis of the one roller;
A drive source for rotating the rotating body,
The sheet processing apparatus according to claim 5, wherein the other roller is swingably supported by the rotating member. An image forming apparatus for forming an image on paper;
A center folding processing unit for folding a plurality of sheets supplied from the image forming apparatus, a sheet stacking unit for stacking a plurality of folded sheets to form a sheet bundle, and a saddle stitching process for binding the sheet bundle with a staple. And a paper discharge unit that discharges the bundle of sheets bound by the saddle stitching processing unit on a stacking unit that is disposed vertically above the saddle stitching processing unit; With
The paper discharge unit is
A pair of rollers, at least one of which is rotatable;
A paper discharge stacking drive unit that rotates the other roller around the axis of one of the pair of rollers and supports the other roller so as to be in contact with and away from the one roller; and
An image forming system.

Images