JP6689320B2 - Sheet processing apparatus and image forming system including the same - Google Patents

Description

  The present invention relates to a sheet bundle binding processing device that binds sheets, and relates to an improvement of the binding processing device that is capable of binding processing with a plurality of binding means.

  Generally, an apparatus that stacks sheets discharged from an image forming apparatus on a processing tray, performs a binding process by a stapling apparatus, and stores the sheets in a stack tray on the downstream side is widely known as a post-processing apparatus. The configuration is such that a sheet carry-in path is connected to a sheet discharge port of the image forming apparatus, a processing tray is arranged at the path sheet discharge port, the image-formed sheets are collated and collected, and the binding process is performed on the tray. A structure in which the sheets are bound by a unit and then stored in a stack tray arranged on the downstream side is adopted.

  For example, in Patent Document 1, a post-processing device having a binding processing function is arranged on the downstream side of the image forming apparatus, and the sheets sent from the image forming apparatus are collated and stacked on a processing tray to perform binding processing, and then the downstream side. Apparatus for storing in a stack tray of the above is disclosed.

JP 2005-096392 A (FIG. 1)

  An object of the present invention is to provide a sheet processing apparatus capable of executing a plurality of binding processes.

In order to solve the above-mentioned problems, the sheet processing apparatus of the present invention includes a conveyance path along which a sheet is conveyed, a conveyance unit that conveys the sheet in a conveyance direction, and discharges the sheet from an outlet of the conveyance path. wherein the first stacking means sheet discharged from the discharge port are stacked, the sheet bundle stacked on the first stacking means, by contacting the end portion in the direction intersecting the transport direction by the transport means, the By contacting the first regulating means for regulating the position of the sheet bundle in the intersecting direction and the upstream end of the sheet bundle stacked on the first stacking means in the transport direction, A second restricting means for restricting a position in the carrying direction, and a second restricting means for moving from one side to the other side of the apparatus by moving in the intersecting direction and the other side to the one side. An end portion of the sheet bundle on the one side that is configured to move to the side and is in contact with the first restricting means, and an end portion of the sheet bundle in the transport direction that is in contact with the second restricting means, A first binding means for binding the corner portion of the sheet bundle using a needle to the end portion of the sheet bundle on the one side where the first regulating means is in contact, and the second regulating means is in contact. The second binding means for binding the corner portion of the sheet bundle including the end portion of the sheet bundle in the transport direction without using a needle, and the sheet bundle stacked on the first stacking means. A moving unit that moves the sheet bundle from the first stacking unit by moving the sheet bundle in a direction, and a second stacking unit that stacks the sheet bundle moved from the first stacking unit by the moving unit and can move up and down. Can be raised and lowered integrally with the second loading means Has a click, a lifting motor for lifting the second stacking means, is configured to mate with the rack, and a pinion for elevating the rack is rotated by the rotation of the elevating motor, The first binding means is movable in a state of being separated from the second binding means, and is configured so as not to move integrally with the second binding means at all times, and the pinion is the first binding means with respect to the transport direction. The first binding unit is disposed downstream of the first binding position for binding the sheet bundle, the second binding unit is disposed downstream of the second binding position for binding the sheet bundle in the transport direction, and the first stacking unit is the sheet. Is disposed below a stacking surface for stacking sheets, and the first restricting unit has a restricting surface that is in contact with an end portion of the sheet bundle stacked on the first stacking unit in the intersecting direction. , The above The upstream end in the transport direction is located downstream of the binding position where the second binding unit binds the sheet bundle stacked on the first stacking unit in the transport direction .

  The present invention can execute a plurality of binding processes.

FIG. 1 is an explanatory diagram of the overall configuration of an image forming system according to the present invention. FIG. 2 is a perspective explanatory view showing an overall configuration of a post-processing device in the image forming system of FIG. 1, and is a state diagram in which a sheet bundle is set in a manual feed section. FIG. 3 is a side cross-sectional view of the device of FIG. 2 (device front side). 3A and 3B are explanatory views of a sheet carrying-in mechanism in the apparatus of FIG. 2, in which FIG. 3A shows a state in which a paddle rotating body is in a standby position, and FIG. 3B shows a state in an engaging position. FIG. 3 is an explanatory diagram showing a positional relationship between each area and a matching position in the device of FIG. 2. FIG. 3 is an explanatory view of a configuration of a side aligning unit in the apparatus of FIG. Explanatory drawing of the moving mechanism of a stapler unit. Explanatory drawing which shows the binding position of a stapler unit. Explanatory drawing of multi-binding and left-corner binding of the stapler unit. The state of the stapler at the binding position is shown, (a) shows the state of the right corner binding position, (b) shows the state of the needle loading position, and (c) shows the state of the manual binding position. 3A and 3B are explanatory views of a sheet bundle unloading mechanism in the apparatus of FIG. 2, in which (a) shows a standby state, (b) shows a succeeding conveyance state, (c) shows a structure of a second conveyance member, and (d). Indicates the state of being discharged to the stack tray. (A) thru | or (d) are the binding processing methods of a sheet bundle. (A) is a structural explanatory view of a stapler unit, (b) is a structural explanatory view of a press bind unit. FIG. 3 is a structural explanatory view of a stack tray in the apparatus of FIG. 2. FIG. 3 is an arrangement relational diagram of drive units in the device of FIG. 2. Explanatory drawing of a state in which the open / close cover is opened and staples are added to the stapler unit. FIG. 3 is an explanatory diagram of a sheet detection sensor arranged on a manual feed setting surface in the apparatus of FIG. 2. (A) thru | or (f) Explanatory drawing of the kicker means in the apparatus of FIG. Explanatory drawing of the control structure in the apparatus of FIG. Operation flow of staple binding processing mode. Eco-binding mode operation flow. Printout mode operation flow. Sort mode operation flow. A common operation flow for loading a sheet onto the processing tray. Operation flow of manual staple binding process.

  The present invention will be described in detail below with reference to the preferred embodiments shown in the drawings. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sheet bundle binding processing mechanism that binds a sheet bundle that has been image-formed and collated and accumulated in an image forming system or the like to be described later. The image forming system shown in FIG. 1 includes an image forming unit A, an image reading unit C, and a post-processing unit B. Then, the original image is read by the image reading unit C, and the image is formed on the sheet by the image forming unit A based on the image data. Then, the sheets on which the images have been formed are aligned and accumulated in the post-processing unit B (sheet bundle binding processing device; the same applies hereinafter) to perform binding processing, and are stored in the stack tray 25 on the downstream side.

  The post-processing unit B, which will be described later, is incorporated as a unit in a paper discharge space (stack tray space) 15 formed in the housing of the image forming unit A, and the image forming sheet sent to the paper discharge port 16 is placed on the processing tray. 1 illustrates an inner finisher structure including a post-processing mechanism in which sheets are aligned and accumulated, bound, and then stored in a stack tray arranged on a downstream side. The present invention is not limited to this, and the image forming unit A, the image reading unit C, and the post-processing unit B may be configured as independent stand-alone structures, and each device may be connected by a network cable to form a system.

[Sheet bundle binding processing device (post-processing unit)]
The post-processing unit B has an apparatus housing 20, a sheet carry-in path 22 arranged in the housing, and a downstream side of the path discharge port 23, as shown in the perspective structure in FIG. 2 and the sectional structure in FIG. And a stack tray 25 arranged further downstream thereof.

  The processing tray 24 is provided with a sheet carrying-in means 35 for carrying in the sheets, a sheet regulating means (positioning means) 40 for accumulating the carried-in sheets in a bundle, and an aligning means 45. At the same time, a staple binding unit 26 (first binding unit) that staples the sheet bundle and a needleless binding unit 27 (second binding unit) that staples the sheet bundle are arranged on the processing tray 24. . Each configuration will be described in detail below.

[Device housing]
The device housing 20 is composed of a device frame 20a and an outer casing 20b, and the device frame is composed of a frame structure that supports each mechanism unit (path mechanism, tray mechanism, transport mechanism, etc.) described later. The illustrated one has a binding mechanism, a transport mechanism, a tray mechanism, and a drive mechanism arranged on a pair of left and right side frame frames (not shown) facing each other, and has a monocoque structure integrated by an outer casing 20b. The outer casing 20b has a monocoque structure in which left and right side frame frames 20c and 20d and a stay frame (bottom frame frame 20e described later) that connects the both side frame frames are integrated by molding using a resin or the like, and a part thereof (device) The front side) is exposed so that it can be operated from the outside.

  That is, the outer periphery of the frame framework is covered with the exterior casing 20b, and the frame casing is built in the paper discharge space 15 of the image forming unit A described later. In this state, the exterior case on the front side of the apparatus is exposed so that it can be operated from the outside. On the front side of the outer casing 20b, a cartridge mounting opening 28 for a staple, which will be described later, a manual feed setting portion 29, and a manual operation button 30 (the illustrated one is a switch having a built-in indicator lamp) are provided.

  The outer casing 20b has a length dimension Lx in the sheet discharge direction and a length dimension Ly in the sheet discharge orthogonal direction set based on the maximum size sheet, and is smaller than the sheet discharge space 15 of the image forming unit A described later. Is set to.

[Sheet carry-in route (paper discharge route)]
As shown in FIG. 3, a sheet carry-in path 22 (hereinafter referred to as “paper discharge path”) having a carry-in port 21 and a paper discharge port 23 is arranged in the apparatus housing 20 described above. It is configured to receive, convey in a substantially horizontal direction, and carry out from the paper discharge port 23. The paper discharge path 22 is formed by an appropriate paper guide (plate) 22a and has a built-in feeder mechanism for conveying the sheet. The feeder mechanism is composed of a pair of conveying rollers arranged at predetermined intervals according to the path length. In the illustrated example, a pair of carrying-in rollers 31 is arranged in the vicinity of the carry-in port 21, and a pair of discharging rollers 32 is arranged in the vicinity of the paper discharging port 23. Has been done. Further, a sheet sensor Se1 that detects the leading edge and / or the trailing edge of the sheet is arranged in the sheet discharge path 22.

  The paper discharge path 22 is formed as a substantially horizontal linear path so as to cross the apparatus housing 20. This is to avoid stress on the sheet in a curved path, and the path is formed with the linearity allowed by the device layout. The pair of carry-in rollers 31 and the pair of discharge rollers 32 are connected to the same drive motor M1 (hereinafter, referred to as a carry motor), and carry the sheet at the same peripheral speed.

[Processing tray]
Explaining in accordance with FIG. 3, the processing tray 24 is arranged at the paper exit 23 of the paper exit path 22 with a step d formed downstream thereof. The processing tray 24 is provided with a paper placing surface 24a for supporting at least a part of the sheets in order to stack the sheets sent from the sheet discharge port 23 upward and accumulate them in a bundle. The structure shown in the figure adopts a structure (bridge support structure) in which the sheet front end side is supported by a stack tray 25 described later and the sheet rear end side is supported by the processing tray 24. This reduces the tray size.

  The processing tray 24 collects the sheets sent from the paper discharge port 23 in a bundle, performs a binding process after aligning them in a predetermined posture, and carries out the processed sheet bundle to a stack tray 25 on the downstream side. Is configured. For this reason, the processing tray 24 incorporates a "sheet loading mechanism 35", a "sheet alignment mechanism 45", "binding processing mechanisms 26 and 27", and a "sheet bundle unloading mechanism 60".

"Sheet carry-in mechanism (sheet carry-in means)"
A processing tray 24 is arranged with a step d formed in the above-mentioned paper discharge port 23. A sheet carrying-in means 35 for smoothly carrying the sheet in the correct posture on the processing tray is required. The illustrated sheet carry-in means 35 (friction rotator) is composed of a paddle rotator 36 that moves up and down, and when the rear end of the sheet is carried out from the paper discharge port 23 onto the tray, the paddle rotator 36 discharges the sheet in the opposite direction. The sheet is moved (rightward in FIG. 3) and abutted on (aligned with) a sheet end regulating means 40 described later.

  Therefore, the paper output port 23 is provided with an elevating arm 37 that is pivotally supported on the apparatus frame 20a by a support shaft 37x, and the paddle rotating body 36 is rotatably axially supported by the tip end of the elevating arm. There is. The support shaft 37x is equipped with a pulley (not shown), and the above-mentioned transport motor M1 is connected to this pulley.

  Along with this, an elevating motor M3 (hereinafter referred to as a paddle elevating motor) is connected to the elevating arm 37 via a spring clutch (torque limiter), and rotation of the motor causes the elevating arm 37 to move to an upper standby position Wp and a lower operating position (seat). It is configured to move up and down between the engagement position) Ap. That is, the spring clutch raises the elevating arm 37 from the operating position Ap to the standby position Wp by one-way rotation of the paddle elevating motor M3, and waits at the standby position after hitting a locking stopper (not shown). The spring clutch is relaxed by the opposite rotation of the paddle lifting motor M3, and the lifting arm 37 is lowered by its own weight from the standby position Wp to the lower operating position Ap to engage with the uppermost sheet on the processing tray.

  In the illustrated apparatus, as shown in FIG. 5, a pair of paddle rotating bodies 36 are arranged symmetrically with respect to the seat center (center reference Sx) with a predetermined distance therebetween. In addition, a total of three paddle rotating bodies may be arranged at the seat center and both sides thereof, or one paddle rotating body may be arranged at the seat center.

  The paddle rotating body 36 is composed of a flexible rotating body such as a rubber plate member and a plastic blade member. In addition to the paddle rotating body, the sheet carrying-in means 35 can be constituted by a friction rotating member such as a roller body or a belt body. Further, the apparatus shown in the drawing shows a mechanism for lowering the paddle rotating body 36 from the upper standby position Wp to the lower operating position Ap after the rear end of the sheet is carried out from the paper discharge port 23, but the following elevating mechanism is adopted. Is also possible.

  An elevating mechanism different from the one shown in the drawing is, for example, when the front end of the sheet is carried out from the paper ejection port 23, the friction rotator is lowered from the standby position to the operating position, and simultaneously rotated in the paper ejection direction so that the rear end of the sheet is ejected. At the timing of carrying out from 23, this rotating body is reversely rotated in the direction opposite to the paper discharge. This makes it possible to transfer the sheet carried out from the paper discharge port 23 to the predetermined position of the processing tray 24 at high speed and without skewing.

"Scraping rotator (scraping conveying means)"
When the sheet is conveyed to a predetermined position of the processing tray 24 by the sheet carry-in mechanism 35 (paddle rotating body) arranged in the above-described sheet discharge port 23, the leading end of the sheet is moved to the downstream side due to the influence of a curled sheet, a skewed sheet, or the like. The scraping and conveying means 33 for guiding to the restriction stopper 40 is required.

  The apparatus shown in the figure is a scraping rotary member (scraping conveying means) that applies a conveying force to the regulating member side of the uppermost sheet stacked on the upstream side of a sheet end regulating stopper 40 described below below the discharge roller pair 32. ) 33 are arranged. In the illustrated example, a ring-shaped belt member 34 (hereinafter referred to as "scraping belt") is arranged above the front end of the processing tray 24, and the scraping belt 34 engages with the uppermost sheet on the paper mounting surface and is regulated. It rotates in the direction in which the sheet is conveyed to the member side.

  For this reason, the scraping belt 34 is made of a flexible material such as rubber and is made of a belt material having a high frictional force (such as a knurled belt), and is connected to a drive motor (the one shown in the drawing is common with the transport motor M1). A nip is supported between 34x and the idle shaft 34y. The rotational force in the counterclockwise direction in FIG. 3 is applied from the rotary shaft 34x. At the same time, the scraping belt 34 presses the leading edge of the sheet carried in along the uppermost sheet stacked on the processing tray and abuts against the downstream-side regulation stopper 40.

  The scraping belt 34 is configured to be vertically moved above the uppermost sheet on the tray by a belt shift motor M5 (hereinafter referred to as a knurling lifting motor) (the lifting mechanism is omitted). Then, at the timing when the leading edge of the sheet enters between the belt surface and the uppermost sheet, the scraping belt 34 descends and engages with the carry-in sheet. Further, the scraping belt 34 controls the knurling motor M5 so that the scraping belt 34 is separated from the uppermost sheet and waits upward when being transferred from the processing tray 24 to the stack tray 25 on the downstream side by the sheet bundle discharging means 60 described later.

"Sheet alignment mechanism"
The processing tray 24 is provided with a sheet aligning mechanism 45 for positioning the carried-in sheet at a predetermined position (processing position). The illustrated sheet aligning mechanism 45 includes a "sheet end regulating unit 40" that regulates the position of the end face (either the leading end face or the rear end face) of the sheet sent from the sheet discharge port 23 in the sheet discharge orthogonal direction (sheet It is composed of a "side aligning means 45" for aligning in the width direction. This will be described below in this order.

"Seat edge control means"
The illustrated sheet edge regulating means 40 is composed of a trailing edge regulating member 41 that abuts and regulates the trailing edge of the sheet in the sheet discharge direction. The trailing edge regulating member 41 includes a regulating surface 41 a that regulates the trailing edge of the sheet carried in along the sheet mounting surface 24 a on the processing tray in the sheet ejection direction, and is fed by the scraping conveying means 33. The trailing edge of the sheet to be abutted and stopped.

  In the trailing edge regulating member 41, the stapler unit moves along the sheet trailing edge (in the direction perpendicular to the sheet discharge) when performing multi-binding by the stapler unit 26 described later. In order not to hinder the movement of the unit, (1) adopt a mechanism for moving the trailing edge regulating member into and out of the movement path (movement locus) of the binding unit, or (2) move the position integrally with the binding unit. Or (3) the rear end regulating member is formed of, for example, a channel-shaped bent piece inside the binding space formed by the head of the binding unit and the anvil.

  In the illustrated example, the trailing edge regulating member 41 is configured by a plate-shaped bending member having a U-shaped cross section (channel shape), which is arranged in the binding space of the staple binding unit 26. Then, the first member 41A is arranged at the seat center based on the smallest size sheet, and the second and third members 41B and 41C are arranged on the left and right with a distance from this (see FIG. 5). This enables the staple binding unit 26 to move in the sheet width direction.

  As shown in FIGS. 5 and 7, a plurality of rear end regulating members 41 formed of channel-shaped bent pieces are fixed to the processing tray 24 (the tip ends of the members are fixed to the tray rear wall with screws). . A regulation surface 41a is formed on each of the trailing edge regulation members 41, and an inclined surface 41b for guiding the sheet end to the regulation surface is continuously provided at the bent front end portion thereof.

"Side matching means"
The processing tray 24 is provided with an aligning unit 45 (hereinafter referred to as a “side aligning member”) for positioning the sheet that has abutted against the trailing edge regulating member 41 in the paper discharge orthogonal direction (sheet width direction).

  The side alignment member 45 has a different configuration depending on whether the sheets of different sizes are aligned on the processing tray on the basis of the center or on the one side. In the apparatus shown in FIG. 5, sheets of different sizes are discharged from the sheet discharge port 23 based on the center standard, and the sheets are aligned on the processing tray with the center standard. Then, according to the binding process, the sheet bundles aligned in a bundle with the center reference are offset to the binding positions Ma1 and Ma2 in the alignment posture in the case of multi-binding and by a predetermined amount in the left-right direction in the case of left-right corner binding. The stapler unit 26 binds to the positions Cp1 and Cp2.

  For this reason, the aligning means 45 is arranged so that the left and right side aligning members 46 (46F, 46R) that project upward from the paper placing surface 24a of the processing tray and have the restricting surfaces 46x that engage with the side edges of the sheets are opposed to each other. To place. Then, the pair of left and right side aligning members 46 are arranged on the processing tray 24 so as to be capable of reciprocating with a predetermined stroke. This stroke is set by the size difference between the maximum size sheet and the minimum size sheet and the offset amount by which the aligned sheet bundle is moved (offset-conveyed) in the left or right direction. That is, the moving strokes of the left and right side aligning members 46F and 46R are set by the moving amount for aligning different size sheets and the offset amount of the aligned sheet bundle.

  Therefore, as shown in FIG. 6, the side aligning member 46 is composed of a right side aligning member 46F (apparatus front side) and a left side aligning member 46R (apparatus rear side). The restricting surfaces 46x that engage with the ends are supported by the tray member so as to move toward or away from each other. The processing tray 24 is provided with a slit groove 24x penetrating through the front and back, and a side aligning member 46 having a restricting surface 46x engaging with a side edge of the sheet is slidably fitted to the upper surface of the tray from this slit.

  The side aligning members 46F and 46R are slidably supported by a plurality of guide rollers 49 (may be rail members) on the back side of the tray, and a rack 47 is integrally formed. Matching motors M6 and M7 are connected to the left and right racks 47 via pinions 48. The left and right alignment motors M6, M7 are configured by stepping motors, position detection of the left and right side alignment members 46F, 46R is performed by a position sensor (not shown), and each regulation member is moved in either the left or right direction based on the detected value. It is configured so that the position can be moved by a designated movement amount.

  Instead of the illustrated rack-pinion mechanism, it is also possible to adopt a configuration in which the side aligning members 46F and 46R are fixed to the timing belt, and the belt is connected to a motor that reciprocates the belt with a pulley.

  With such a configuration, the control unit 75, which will be described later, causes the left and right side aligning members 46 to wait at a predetermined standby position (sheet width size + α position) based on the sheet size information provided from the image forming unit A or the like. In this state, the sheet is loaded onto the processing tray, and the aligning operation is started at the timing when the sheet edge hits the sheet edge regulating member 41. This alignment operation rotates the left and right alignment motors M6 and M7 by the same amount in opposite directions (approaching directions). Then, the sheets carried into the processing tray 24 are positioned on the basis of the sheet center and stacked in a bundle. By repeating the loading operation and the aligning operation of the sheets, the sheets are collated and collected in a bundle on the processing tray. At this time, sheets of different sizes are positioned on the basis of the center.

  In this manner, the sheets stacked on the processing tray on the basis of the center can be subjected to the binding processing of the trailing edge (or the leading edge) of the sheets at predetermined intervals in multiple positions (multi-binding processing). When binding the sheet corners, one side of the left and right side aligning members 46F and 46R is moved to a position where the sheet side edge coincides with the designated binding position and is made to stand still. Then, the side alignment member on the opposite side is moved in the approaching direction. The amount of movement in the approach direction is calculated according to the sheet size. As a result, the sheets carried onto the processing tray 24 are aligned so that the right edge is aligned with the binding position when the right corner is bound, and the left edge is aligned with the binding position when the left corner is bound. .

When the sheet bundle aligned at the predetermined position on the processing tray as described above is offset-moved for the “eco-binding processing” described later,
(1) The aligning member on the rear side in the moving direction is moved in the direction orthogonal to the preset amount while the aligning member on the front side in the moving direction is retracted to a position away from the expected offset position, or
(2) The left and right alignment members are moved by the same amount in the conveyance orthogonal direction, and either drive control is adopted.

  Position sensors (not shown) such as position sensors and encode sensors are arranged on the left and right side aligning members 46F and 46R and the aligning motors M6 and M7 to detect the position of the side aligning member 46. There is. The alignment motors M6 and M7 are stepping motors, the home position of the side alignment member 46 is detected by a position sensor (not shown), and the motors are PWM-controlled to provide a relatively simple control configuration. 46F, 46R can be controlled.

[Sheet bundle unloading mechanism]
The sheet bundle unloading mechanism (sheet bundle unloading means 60) shown in FIG. 11 will be described. A sheet bundle unloading mechanism that unloads the sheet bundle bound by the first and second binding units 26 and 27 to the stack tray 25 on the downstream side is arranged on the processing tray 24. In the processing tray 24 described with reference to FIG. 5, the first sheet trailing edge regulating member 41A is arranged at the sheet center Sx, and the second and third sheet trailing edge regulating members 41B and 41C are arranged at right and left sides thereof with a distance. ing. The sheet bundle locked by the regulation member 41 is bound by the binding means 26 (27) and then carried out to the stack tray 26 on the downstream side.

  For this reason, a sheet bundle unloading means 60 is arranged on the processing tray 24 along the paper placing surface 24a. The illustrated sheet bundle unloading means 60 is composed of a first transport member 60A and a second transport member 60B. The first section L1 on the processing tray is the first transport member 60A and the second section L2 is the second transport member. Relay transfer at 60B. In this way, by taking over and carrying the sheet by the first and second carrying members 60A and 60B, the mechanism of each carrying member can have a different structure. The member that conveys the sheet bundle from the substantially same starting point as the sheet trailing edge regulating unit 40 is a member (long support member) with less shaking, and the member that drops the sheet bundle onto the stack tray 25 at the conveying end point is a member. , Must be small (because of traveling on a loop locus).

  The first carrying member 60A is composed of a first carry-out member 61 formed of a bent piece having a channel-shaped cross section, and has a locking surface 61a for locking the rear end surface of the sheet bundle and an engaging surface on this surface. A paper surface pressing member 62 (elastic film member; Mylar piece) that presses the top surface of the stopped sheet is provided. Since the first transport member 60A is composed of a channel-shaped bent piece as shown in the figure, when fixed to a carrier member 65a (belt) described later, it does not rock easily and travels integrally with the belt. To move (feed out) the rear end of the sheet bundle in the transport direction. The first transport member 60A reciprocates along the stroke Str1 along a substantially linear locus without traveling along a curved loop locus as described later.

  The second conveying member 60B is composed of a claw-shaped second discharging member 63, and is provided with a locking surface 63a for locking the rear end surface of the sheet bundle and a paper surface pressing member 64 for pressing the upper surface of the sheet bundle. . The paper surface pressing member 64 is pivotally supported by the second carry-out member 63 so as to be swingable, and is provided with a paper surface pressing surface 64a. The paper surface pressing surface is a biasing spring 64b so as to press the upper surface of the sheet bundle. Being energized.

  The paper surface pressing surface 64a is formed of an inclined surface inclined in the traveling direction as shown in the drawing, and when moved in the direction of the arrow in FIG. At this time, the paper surface pressing surface 64a is deformed upward (counterclockwise in the figure) in the arrow direction against the biasing spring 64b. Then, as shown in FIG. 10C, the paper surface pressing surface 64a presses the upper surface of the sheet bundle toward the paper mounting surface side by the action of the biasing spring 64b.

  The first carry-out member 61 configured as described above is the first carrier member 65a, and the second carry-out member 63 is the second carrier member 65b that reciprocates from the base end of the paper placing surface 24a to the exit end. To do. For this reason, the drive pulleys 66a and 66b and the driven pulley 66c are arranged on the paper placing surface 24a at positions separated by the transport stroke. Reference numerals 66d and 66e are idle pulleys.

  A first carrier member 65a (a toothed belt is shown) is provided between the drive pulley 66a and the driven pulley 66c, and a second carrier member 65b (toothed belt is provided between the drive pulley 66b and the driven pulley 66c). ) Is bridged via idle pulleys 66d and 66e. A drive motor M4 is connected to the drive pulleys 66a and 66b, and the rotation of the motor is transmitted to the first carrier member 65a at low speed and to the second carrier member 65b at high speed. The pulley 65a has a small diameter and the second drive pulley 65b has a large diameter.

  In other words, the first drive member 60A is connected to the common drive motor M4 at a low speed, and the second transfer member 60B is connected at a high speed via a reduction mechanism (belt-pulley, gear connection, etc.). Along with this, a cam mechanism that delays drive transmission is built in the second drive pulley 66b. This is because the moving stroke Str1 of the first carrying member 60A and the moving stroke Str2 of the second carrying member 60B are different and the standby position of each member is adjusted as described later.

  With the above configuration, the first transport member 60A reciprocates in a straight line trajectory from the rear end regulation position of the processing tray 24 with the first stroke Str1, and the first section Tr1 is set within this stroke, and the second transport member The member 60B reciprocates from the first section Tr1 to the exit end of the processing tray 24 with a second stroke Str2 in a semi-looped trajectory, and the second section Tr2 is set within this stroke.

  When the drive motor M4 rotates in one direction, the first conveying member 60A moves from the sheet trailing edge regulating position to the downstream side (FIG. 11 (a) to (b)) at the speed V1 and the locking surface 61a of the sheet bundle Push the rear end to transfer. After a predetermined time delay from the first transport member 60A, the second transport member 60B projects from the standby position on the back side of the processing tray (FIG. 11A) onto the paper mounting surface and follows the first transport member 60A. The vehicle travels in the same direction at a speed V2. At this time, since the speed V1 <V2 is set, the sheet bundle on the processing tray is taken over from the first transport member 60A to the second transport member 60B.

  FIG. 11B shows the succeeding conveyance state, in which the sheet bundle traveling at the speed V1 is caught up by the second conveying member 60B traveling at the speed V2. That is, after passing the first section Tr1, the first conveying member 60A is caught up with the second conveying member 60B, the second conveying member 60B engages with the sheet rear end surface, and conveys the second section Tr2 to the downstream side.

  Then, when the second conveying member 60B collides with the sheet bundle traveling at the speed V1 at a high speed at the takeover point, the paper surface pressing member 64 causes the paper surface pressing surface 64a to press the upper surface of the sheet bundle and the carrier member (belt) 65a. The sheet bundle is carried out toward the stack tray 25 while holding the trailing end of the sheet bundle so as to nip it with (65b).

"Binding method (binding position)"
As described above, the sheets sent to the carry-in port 21 of the sheet discharge path 22 are collated and accumulated on the processing tray, and are positioned (aligned) by the sheet edge regulating member 40 and the side aligning member 46 in a preset position and posture. To be done. Then, the sheet bundle is bound and carried out to the stack tray 25 on the downstream side. A binding processing method in this case will be described.

  The apparatus shown in the figure is provided with “first binding means 26 for stapling sheet bundles” and “second binding means 27 for stapleless binding of sheet bundles” on the processing tray 24 as binding processing methods. The control means 75, which will be described later, has a first characteristic that the sheet bundle is bound by the first and second selected binding means 26 (27) and then carried out to the downstream side. This enables bookbinding binding that does not easily come off when the sheet bundle is bound with staples, but it may be necessary to conveniently separate the bound sheet bundle depending on the user's application. In addition, when the used sheet bundle is cut with a shredder, recycled paper is used, etc., metal needles pose a problem. Therefore, "with needle" or "without needle" binding means can be selected and used. This is because.

  In addition, the apparatus shown in the figure separates sheets created outside the apparatus (outside the system) from a series of post-processing operations of carrying in the sheets from the sheet carry-in path (sheet discharge path) 22, aligning and stacking them, and then binding them. The second feature is that binding processing (hereinafter referred to as "manual stapling processing") is performed.

  Therefore, the manual insertion setting portion 29 for setting the sheet bundle from the outside is arranged in the outer casing 20b, the manual insertion setting surface 29a for setting the sheet bundle is formed in the casing, and the staple binding unit (the stapler unit 26) described above is formed. The processing tray 24 is configured to move from the sheet carry-in area Ar to the manual feed area Fr.

  Each binding processing method will be described with reference to FIGS. 8 to 10. The illustrated apparatus binds a manually set sheet with "multi-binding positions Ma1 and Ma2" that performs binding processing on the re-folding positions of sheets with staples, "corner binding positions Cp1 and Cp2" that performs binding processing on sheet corners. The "manual binding position Mp" to be processed and the "needleless binding position Ep" to staple the sheet corners are set. The positional relationship between the binding positions will be described.

  The binding processing method will be described with reference to FIG. The apparatus shown in the figure is a "multi-binding position Ma1, Ma2" that performs binding processing on the reciprocal positions of sheets with staples, a "corner binding position Cp1, Cp2" that performs binding processing on sheet corners, and binding processing for manually set sheets. “Manual binding position Mp” and “Needleless binding position Ep” for binding the sheet corners without staples are set. The positional relationship between the binding positions will be described.

"Multi-binding"
As shown in FIG. 5, in the multi-binding process, the edge of the sheet bundle (hereinafter referred to as “aligned sheet bundle”) positioned by the sheet edge regulating member 41 and the side aligning member 46 on the processing tray 24 (the one shown in the figure is The trailing edge) is bound. In FIG. 9, binding positions Ma1 and Ma2 that perform binding processing at two locations at intervals are set. The stapler unit 26, which will be described later, moves from the home position to the binding position Ma1 and then to the binding position Ma2 in this order to perform binding processing. The multi-binding position Ma is not limited to two locations, and may be bound at three locations or more. FIG. 12A shows a state of multi-binding.

"Corner binding"
The corner stapling process is performed at two positions on the left and right, a right corner stapling position Cp1 for stapling the right corner of the aligned sheet bundle stacked on the processing tray 24 and a left corner stapling position Cp2 for binding the left corner of the aligned sheet bundle. The spelling position is set. In this case, the staples are tilted at a predetermined angle (about 30 degrees to about 60 degrees) to perform the binding process. (A stapler unit 26, which will be described later, is mounted on the apparatus frame so that the entire unit inclines at a predetermined angle at this position.) FIGS. 12B and 12C show a state in which corners are bound.

  The illustrated device specifications show a case where either the left or right side of the sheet bundle is selected for binding processing, and a case where the staples are inclined at a predetermined angle and binding processing is performed. The present invention is not limited to this, and it is possible to adopt a configuration in which only one of the right and left corners is bound, or a configuration in which the staples are bound in parallel with the sheet edge without being inclined.

"Manual binding"
The manual binding position Mp is arranged on a manual setting surface 29a formed on an external casing 20b (a part of the device housing) described later. The manual setting surface 29a is located at a height position where it is substantially flush with the paper mounting surface 24a of the processing tray, and is arranged (parallelly arranged) adjacent to the paper mounting surface 24a via the side frame 20c. . In the illustrated example, the paper tray 24a and the manual setting surface 29a of the processing tray both support the sheet in a substantially horizontal posture and are arranged at substantially the same height position. FIG. 12D shows a state of manual binding.

  That is, in FIG. 5, the manual setting surface 29a is arranged on the right side and the paper placing surface 24a on the left side via the side frame 20c. The manual binding position Mp is arranged on the same straight line as the above-mentioned multi-binding position Ma arranged on the paper surface. This is for binding the both binding positions by the common stapler unit 26. Therefore, the processing tray 24 is provided with a sheet carry-in area Ar, a manual feed area Fr on the front side of the apparatus, and an eco-binding area Rr described later on the rear side of the apparatus.

"Needleless binding position"
The stapleless binding position Ep (hereinafter referred to as “eco binding position”) is arranged so as to perform binding processing on the side edge portion (corner portion) of the sheet as illustrated in FIG. The illustrated eco-stapling position Ep is arranged at a position for binding one side edge portion of the sheet bundle in the sheet discharge direction, and binds at an angular position inclined by a predetermined angle with respect to the sheets. Further, the eco-stapling position Ep is arranged in the eco-stapling area Rr which is separated from the sheet carry-in area Ar of the processing tray 24 toward the apparatus rear side.

"Relationship between each spelling position"
The multi-binding positions Ma1 and Ma2 are arranged inside (inside) the carry-out area Ar of the sheets carried into the processing tray 24 from the paper discharge port 23. Further, the corner binding positions Cp1 and Cp2 are arranged outside the sheet carry-in area Ar at a reference position (side alignment reference) that is a predetermined distance away from the sheet discharge reference Sx (center reference) to the right or left. ing. As shown in FIG. 6, the right corner binding position Cp1 is outside the side edge of the maximum size sheet (to be bound), and the right corner binding position Cp1 is offset from the sheet side edge to the right by a predetermined amount (δ1). The position Cp2 is arranged at a position deviated to the left by a predetermined amount (δ2) from the side edge of the sheet. Both deviation amounts are set to the same distance (δ1 = δ2).

  The multi-binding positions Ma1 and Ma2 and the manual binding position Mp are arranged on a substantially straight line. Further, the corner binding positions Cp1 and Cp2 are set to have a left-right symmetrical inclination angle (for example, an angle position of 45 degrees) via the paper discharge reference Sx.

  The manual binding position Mp is located outside the sheet carry-in area Ar in the manual feed area Fr on the apparatus front side, and the eco-binding position Ep is located outside the sheet carry-in area Ar and in the eco-binding area Rr on the machine rear side. Has been done.

  The manual binding position Mp is arranged at a position offset by a predetermined amount (Of1) from the right corner binding position of the processing tray, and the eco binding position Ep is offset by a predetermined amount (Of2) from the left corner binding position of the processing tray 24. It is located in a position. In this way, the multi-binding position Mp is set based on the carry-out standard (center standard) of the processing tray for carrying in the sheets, the corner binding position Cp is set based on the maximum size sheet, and further, the apparatus is started from the left and right corner binding positions. The manual binding position Mp is set at a position offset by a predetermined amount on the front side, and the eco-binding position Ep is set at a position offset by a predetermined amount Off2 on the rear side of the apparatus in the same manner, so that the sheet movements do not interfere with each other and are arranged in an orderly manner. Can be arranged.

  The sheet movement in each binding process will be described. In the multi-binding process, a sheet is carried into the processing tray on the basis of a center reference (may be one side reference), and in that state, the sheets are aligned and bound. After the binding process, the posture is carried out to the downstream side. During the corner binding process, the sheets are aligned at the specified alignment position on the side and are bound. After the binding process, it is carried out to the downstream side in that posture.

  In the eco-binding process, the sheets carried in on the processing tray are stacked in a bundle and then offset by a predetermined amount Of2 toward the rear side of the apparatus, and the binding process is performed after the offset movement. After the binding process, the sheet center is offset by a predetermined amount (for example, the same or a small shift amount as the offset Of2), and then the sheet is discharged to the downstream side.

  In manual binding, the operator sets the sheet on the manual feed setting surface, which is a predetermined amount of offset Of1 away from the alignment reference located on the front side of the processing tray 24. As a result, a plurality of binding processes are distributed in the sheet set position in the conveyance orthogonal direction and the binding process is executed, so that the processing speed is fast and the process with less sheet jam is possible.

  In the eco-binding process, the control unit 75, which will be described later, sets the binding position Ep by offsetting the sheets from the rear end reference position by a predetermined amount in the paper discharge direction Of3. This is to avoid interference between the stapler unit 26 and the eco-binding unit (press bind unit 27 described later) for binding the sheets to the left corner. Therefore, when the eco-stapling unit 27 is mounted on the apparatus frame 20 so as to be movable between the binding position and the retracted position retracted similarly to the staple binding unit 26, it is not necessary to make the offset Of3 in the paper discharge direction.

  Here, the apparatus front side Fr means the front side of the exterior casing 20b which is set at the time of designing the apparatus and the operator performs various operations. Normally, a control panel, a seat cassette mounting cover (door), or an opening / closing cover 28c for replenishing staples of the stapler unit is arranged on the front side of the apparatus. Further, the device rear side Re refers to, for example, the side facing the wall surface of the building when the device is installed (installation condition with a wall on the back surface in design).

  As described above, the illustrated apparatus has the manual binding position Mp on the apparatus front side Fr and the eco binding position Ep on the apparatus rear side Re outside the area with reference to the sheet carry-in area Ar. At this time, the distance Ofx between the reference of the sheet carry-in area Ar (sheet carry-in reference Sx) and the manual binding position Mp is longer than the distance Ofy between the carry-in reference Sx and the eco-binding position Ep (position away from Ofx> Ofy). Is set to.

  In this way, the manual binding position Mp is set to a position far from the sheet loading reference (Sx) of the processing tray 24, and the eco binding position Ep is set to an approaching position near the loading reference from the outside to the manual binding position Mp. This is because, when the sheet bundle is set, the operation is easy because it is far from the processing tray 24. At the same time, the eco-stapling position Ep is set to a position closer (closer) to the carry-in reference Sx by reducing the movement amount when the sheets (aligned sheet bundle) carried on the processing tray are offset-moved to the binding position. This is because the binding processing is speedy (improvement in productivity).

"Stapler unit movement mechanism"
Although the structure of the stapler unit 26 (first binding processing means) will be described later, the stapler unit 26 is equipped with a staple cartridge 39, a staple head 26b, and an anvil member 26c in a unit frame 26a (referred to as a first unit frame). The unit 26 is supported by the apparatus frame 20a so as to reciprocate with a predetermined stroke along the sheet end surface of the processing tray 24. The support structure will be described below.

  FIG. 7 shows a front structure in which the stapler unit 26 is attached to the apparatus frame 20, and FIG. 8 shows a plan structure thereof. 9 and 10 are partial explanatory views of a guide rail mechanism that guides the stapler unit.

  As shown in FIG. 7, a chassis frame 20e (hereinafter referred to as a "bottom frame") is arranged on the left and right side frame frames 20c and 20d that form the device frame 20a. A stapler unit 26 is mounted on the bottom frame 20e so as to be movable with a predetermined stroke. A travel guide rail 42 (hereinafter simply referred to as “guide rail”) and a slide cam 43 are arranged on the bottom frame 20e. The guide rail is formed with a traveling rail surface 42x, and the slide cam 43 is formed with a traveling cam surface 43x. The traveling rail surface 42x and the traveling cam surface 43x cooperate with each other to form the stapler unit 26 (hereinafter referred to as "moving unit"). Is supported so that it can reciprocate with a predetermined stroke, and at the same time, its angular posture is controlled.

  The travel guide rail 42 and the slide cam 43 are formed with a rail surface 42x and a cam surface 43x so as to reciprocate within a movement range (sheet loading area, manual feed area and eco-binding area) SL of the moving unit (FIG. 8). reference). The travel guide rail 42 is a rail member having a stroke SL along the rear end regulating member 41 of the processing tray 24, and the illustrated one is an opening groove formed in the bottom frame 20e. A traveling rail surface 42x is formed at the opening edge, and the traveling rail surface is arranged in the same straight line as the rear end regulating member 41 of the processing tray and in a mutually parallel relationship. A slide cam 43 is arranged at a distance from the traveling rail surface, and the one shown in the figure is a groove cam formed on the bottom frame 20e. A traveling cam surface 43x is formed on the groove cam.

  The moving unit 26 (stapler unit) is fixed to a traveling belt 44 connected to a drive motor (traveling motor) M11. The traveling belt 44 is wound around a pair of pulleys pivotally supported by the device frame 20e, and a drive motor is connected to one of the pulleys. Therefore, the stapler unit 26 reciprocates with the stroke SL by the forward / reverse rotation of the traveling motor M11.

  The traveling rail surface and the traveling cam surface are parallel spacing portions (span G1) 43a and 43b which are parallel to each other, narrow swing spacing portions (span G2) 43c and 43d, and swing spacing portions (span G3) having a narrower spacing. ) 43e, a space is formed. The relationship is span G1> span G2> span G3. In the span G1, the swinging angle is changed so that the unit is in a posture parallel to the rear edge of the seat, in the span G2, the unit is inclined to the left or right, and in the span G3, the unit is further inclined.

  The traveling guide rail 42 is not limited to the open groove structure, and various structures such as a guide rod, a protruding rib, and the like can be adopted. Further, the slide cam 43 is not limited to the groove cam, and various shapes can be adopted as long as it has a cam surface for guiding the moving unit 26 in a predetermined stroke direction such as a protruding rib member.

  The moving unit 26 is engaged with the traveling guide rail 42 and the slide cam 43 as follows. As shown in FIG. 7, the moving unit 26 includes a first rolling roller 50 (rail fitting member) which engages with the traveling rail surface 42x and a second rolling roller 51 (which engages with the traveling cam surface 43x). A cam follower member) is provided. Along with this, the moving unit 26 is provided with sliding rollers 52 that engage with the supporting (supporting) surface of the bottom frame 20e (two sliding balls 52a and 52b are formed in the figure in the figure). A guide roller 53 that engages with the bottom surface of the bottom frame frame is formed in the moving unit to prevent the moving unit 26 from floating above the bottom frame.

  With the above configuration, the moving unit 26 is movably supported by the bottom frame 20e by the sliding rollers 52a and 52b and the guide roller 53. At the same time, the first rolling roller 50 travels along the running rail surface 42x, and the second rolling roller 52 travels along the row cam surface 43x while following the rail surface 42x and the cam surface 43x.

  Therefore, the space between the rail surface 42x and the cam surface 43x is formed at the illustrated position 43a where the parallel interval portion (span G1) faces the aforementioned multi-binding position Ma1Ma2 and the illustrated position 43b which faces the manual binding position Mp. . In this span G1, the moving unit 26 is held in a posture orthogonal to the sheet edge without swinging, as shown in FIGS. 9 (a) and 10 (c). Therefore, at the multi-binding position and the manual binding position, the sheet bundle is bound by the staples parallel to the sheet edges.

  Further, the rail surface 42x and the cam surface 43x are formed such that a swinging interval (span G2) is located at an illustrated position 43e facing the right corner binding position and an illustrated position 43d facing the left corner binding position. . Then, as shown in FIGS. 9A and 10A, the moving unit is held in a tilted posture to a right tilt angle posture (for example, a tilt of 45 degrees to the right) and a left tilt angle posture (for example, a tilt of 45 degrees to the left). Has been done.

  The rail surface 42x and the cam surface 43x are formed such that a swinging interval (span G3) is formed at a position 43c shown in the figure that faces the position for needle loading. The span G3 is formed at an interval shorter than that of the span G2, and in this state, the moving unit 26 is held in the right tilt angle posture (for example, tilt of 60 degrees) as shown in FIG. 10B. The reason why the angle of the moving unit 26 is changed at the needle loading position is to match the unit posture in the angular direction in which the needle cartridge 39 is attached to the unit, and the angle is set in relation to the opening / closing cover 28c arranged in the outer casing. .

  When the traveling rail surface 42x and the traveling cam surface 43x deflect the angular posture of the moving unit, a second traveling cam surface is provided or a stopper cam surface is provided in order to shorten the moving length. It is preferable that the angle is deflected in cooperation with the above because of the compactness of the layout.

  The illustrated stopper cam surface will be described. As shown in FIG. 8, the side frame 20e includes a right corner binding position Cp1 on the front side of the apparatus and a part of a moving unit (the sliding roller 52a shown in the figure) for changing the unit posture at the manual binding position Mp. The stopper surfaces 43y and 43z to be engaged are arranged at the positions shown in the figure. As a result, it is necessary to correct the inclination of the unit tilted at the needle loading position at the manual binding position Mp, but changing the angle only with the cam surface and the rail surface makes the moving stroke redundant.

  Therefore, when the moving unit is stopped by the stopper surface 43y and is advanced to the manual binding side, the unit returns from the inclined state to the original state. Further, when the unit is returned to the opposite direction from the manual binding position, the stopper surface 43z tilts (forces) the unit to face the corner binding position.

[Stapler unit]
The stapler unit 26 is already widely known as a device for binding with staples. An example thereof will be described with reference to FIG. The stapler unit 26 is configured separately from the sheet bundle binding processing device B (post-processing device). A box-shaped unit frame 26a, a drive cam 26d pivotally supported by the frame, and a drive motor M8 for rotating the drive cam 26d are mounted on the frame.

  A staple head 26b and an anvil member 26c are disposed on the drive cam 26d so as to face each other at the binding position, and the staple head is biased by a drive cam (not shown) from an upper standby position to a lower staple position (anvil member). Move up and down. A needle cartridge 39 is detachably attached to the unit frame.

  A linear blank needle is accommodated in the needle cartridge 39, and the needle is fed to the head 26b by a needle feeding mechanism. The head portion 26b internally includes a former member that bends a linear needle in a U-shape, and a driver that press-fits the bent needle into the sheet bundle. With such a configuration, the drive motor M8 rotates the drive cam 26d to store energy in the biasing spring. Then, when the rotation angle reaches a predetermined angle, the head portion 26b vigorously descends to the anvil member 26c side. By this operation, the staple is bent into a U shape and then inserted into the sheet bundle by a driver. Then, the tip thereof is bent by the anvil member 26c and stapled.

  Further, a staple feeding mechanism is built in between the staple cartridge 39 and the staple head 26b, and a sensor (empty sensor) for detecting the absence of staples is arranged in the staple feeding portion. Alternatively, the unit frame 26a is provided with a cartridge sensor (not shown) that detects whether or not the needle cartridge 39 is inserted.

  The illustrated staple cartridge 39 has a structure in which staples connected to a box-shaped cartridge in a band shape are stacked and stored, and a structure in which they are stored in a roll shape.

  Further, the unit frame 26a is provided with a circuit for controlling the above-mentioned sensors and a circuit board for controlling the drive motor M8 so that a warning signal is issued when the staple cartridge 39 is not housed and the staples are empty. It has become. Further, this staple control circuit controls the drive motor so as to execute the stapling operation by the staple needle signal, and when the staple head moves from the standby position to the anvil position and returns to the standby position, the "operation end signal" is given. Is configured to originate.

[Press Binder Unit]
The configuration of the press binder unit 27 will be described with reference to FIG. As the press binder mechanism, a folding binding mechanism (see JP 2011-256008A) for binding several sheets by forming a cutout opening in the binding portion and folding one side of the cutout opening, and a press binding and separation mechanism which can freely separate from each other. A press binding mechanism is known in which uneven surfaces are formed on the pressing surfaces 27b and 27c and the sheet bundle is pressed and deformed to bind the sheet bundle.

  FIG. 13B shows a press binder unit, in which a movable frame member 27d is swingably supported by a base frame member 27a, and a support shaft 27x swings both frames so that they can be pressed and separated from each other. A follower roller 27f is arranged on the movable frame member 27b, and a drive cam 27e arranged on the base frame 27a is engaged with this follower roller.

  A drive motor M9 arranged on the base frame member 27a is connected to the drive cam 27e via a reduction mechanism, and the drive cam 27e rotates by the rotation of the motor, and the cam surface (the eccentric cam shown in the drawing) moves the movable frame. It is configured to swing the member 27d.

  The lower pressing surface 27c is arranged on the base frame member 27a, and the upper member pressing surface 27b is arranged on the movable frame member 27d. A biasing spring (not shown) is arranged between the base frame member 27a and the movable frame member 27d, and biases both pressing surfaces in a direction in which they are separated from each other.

As shown in the enlarged view of FIG. 13 (b), the upper pressing surface 27b and the lower pressing surface 27c are formed with a protrusion on one side and a concave groove on the other side, which is adapted to this. The ridge and the concave groove are formed in a ridge (rib) shape having a predetermined length. Therefore, the sheet bundle pinched by the upper pressure surface 27b and the lower pressure surface 27c is transformed into a corrugated plate shape and comes into close contact. A position sensor (not shown) is arranged on the base frame member 27a (unit frame), and is configured to detect whether the upper and lower pressing surfaces 27b and 27c are at the pressing position or the separating position.

[Stack tray]
The structure of the stack tray will be described with reference to FIG. The stack tray 25 is disposed on the downstream side of the processing tray 24, and stacks and stores the sheet bundle accumulated on the processing tray. A tray elevating mechanism is provided so that the stack tray 25 can be sequentially lowered according to the stacking amount of the stack tray 25. The stacking surface (top sheet height) of this tray is controlled to a height position that is substantially flush with the paper mounting surface of the processing tray. Further, the stacked sheets are inclined at an angle at which the trailing edge of the stacked sheets hits the tray alignment surface 53 (standing surface) due to its own weight.

  When the specific configuration is moved, the elevating rails 54 are fixed to the apparatus frame 20a in the vertical direction in the stacking direction, and the tray base 25x is slidably fitted to the elevating rails by the slide rollers 55 and the like. Along with this, a rack 25r is integrally formed on the tray base 25x in the vertical direction, and a drive pinion 56 axially supported by the apparatus frame is meshed with this rack. A lift motor M10 is connected to the drive pinion 56 via a worm gear 57 and a worm wheel 58.

  Therefore, when the elevating motor M10 is rotated in the normal direction, the rack 25r connected to the drive pinion 56 moves up and down above and below the apparatus frame. With this configuration, the tray base 25x can be lifted and lowered in a cantilevered state. As the tray lifting mechanism, a pulley suspension belt mechanism or the like can be adopted in addition to the rack and pinion mechanism.

  A stack tray 25 is integrally attached to the tray base 25x, and the stacking surface 25a is configured to stack and store sheets. Further, a tray alignment surface 20f that supports the trailing edge of the sheets is formed on the device frame above and below in the stacking direction of the sheets.

  Further, the stacking tray 25 integrally attached to the tray base 25x is formed to be inclined in the illustrated angle direction, and the angle is set so that the trailing end of the sheet hits the tray alignment surface 20f due to the weight of the sheet (for example, 20 degrees to 60 degrees). ) Has been.

[Sheet pressing mechanism]
The stacking tray 25 is provided with a paper pressing mechanism 53 that presses the stacked uppermost sheet. The illustrated paper pressing mechanism includes an elastic pressing member 53a for pressing the uppermost sheet, a shaft supporting member 53b for rotatably supporting the elastic pressing member on the apparatus frame 20a, and rotating the shaft supporting member in a predetermined angle direction. It is composed of a drive motor M2 that operates and a transmission mechanism thereof. The illustrated drive motor M2 is drivingly coupled with the drive motor of the sheet bundle unloading mechanism as a drive source, and when the sheet bundle is carried in (carried out) to the stack tray 25, the elastic pressing member 53a retracts to the outside of the tray. After the rear end of the sheet bundle is stored on the uppermost sheet of the stacking tray, the sheet bundle is rotated counterclockwise in the drawing from the standby position to engage and press the uppermost sheet.

Further, the elastic pressing member 53a is retracted from the paper surface of the uppermost sheet on the stacking tray to the retracted position by the initial rotation operation of the drive motor M2 that carries out the sheet bundle on the processing tray toward the stack tray.
[Level sensor]

  A level sensor for detecting the paper height of the uppermost sheet is arranged on the stacking tray 25, and the winding motor is rotated by the detection signal of the level sensor to raise the tray paper mounting surface 25a. Various types of level sensor mechanisms are known, but the one shown in the figure irradiates detection light from above the tray alignment surface 20f of the apparatus frame to above the tray, detects the reflected light, and places the sheet at that height position. It employs a detection method that detects whether or not it exists.

[Loaded sheet amount sensor]
Like the level sensor, the stacking tray 25 is provided with a sensor for detecting removal of a sheet from the tray. Although the structure will not be described in detail, for example, by providing a sensor lever that rotates integrally with the above-mentioned paper pressing elastic pressing member 53 and submitting this sensor lever as a sensor element, it is determined whether or not there is a sheet on the stacking surface. Can be detected.

  Then, when the height position of the sensor lever is different (changed) before and after the sheet bundle is carried out, the control means 75 described later stops the paper discharge operation or raises the tray to a predetermined position, for example. Note that such an operation is an abnormal operation, and is a malfunction that occurs when a user carelessly takes out a sheet from the stack tray while the apparatus is operating. Further, a lower limit position is set to the stack tray 25 so that the tray does not descend abnormally, and a limit sensor Se3 for detecting the tray is arranged at this lower limit position.

[Bypass set mechanism]
The mechanism of the above-described manual feed setting unit 29 will be described with reference to FIGS. 5 and 15 to 17. The exterior casing 20b that constitutes the apparatus housing 20 is provided with a manual feed setting section 29 for inserting and setting a sheet bundle from the outside on the apparatus front side Fr (see FIG. 2). The manual-feed setting unit 29 is provided with a manual-feed setting surface 29a, and has a tray shape for placing and supporting a sheet bundle. The illustrated manual setting surface (hereinafter simply referred to as "setting surface") is integrally formed with the outer casing 29b by resin molding.

  As shown in FIG. 5, the setting surface 29a is arranged so as to support the sheets (bundle) on substantially the same plane as the paper mounting surface 24a of the processing tray. The paper placing surface 24a and the setting surface 29a do not have to be horizontal surfaces, and may be a surface inclined at a predetermined angle or a curved surface, or a slight step difference may be formed. That is, as described above, the stapler unit 26, which moves between the sheet carry-in area Ar and the manual feed area Fr, is arranged so that the sheet bundle on the paper placing surface and the sheet bundle on the setting surface can be bound. Just go.

  The paper placing surface 24a and the setting surface 29a are arranged side by side via the side frame 20c of the apparatus frame 20. As shown in FIG. 5, the multi-binding position Ma is set on the paper mounting surface side, and the manual binding position Mp is set on the setting surface side.

  The manual feed setting part 29 is integrally formed with the outer casing 20b and has a recessed part (slit part; the same applies hereinafter) in which the first drive part 80 is arranged in the upper part and the second drive part 81 is arranged in the lower part as shown in FIG. The setting surface 29a is formed in the recess by being integrally molded. The first drive unit 80 includes a paddle lifting motor M3, a knurling motor M5, and a transmission mechanism thereof. A stack tray lifting motor M10 and a transmission mechanism (a rack and pinion, etc.) are arranged in the second drive unit 81.

  As described above, since the first driving unit 80 is arranged above the manual insertion setting unit 29 formed by the slit-shaped concave portion and the second driving unit 81 is arranged below the manual feeding setting unit 29, the apparatus is compactly constructed. At the same time, it is less likely that foreign matter will fall and enter the set surface 29a.

  Further, an open / close cover 28c is formed on the outer casing 20b at a position different from the setting surface 29a. The setting surface 29a and the opening / closing cover 28c are arranged at positions facing each other with the stapler unit 26 interposed therebetween. An opening / closing cover 28c is arranged in the. By disposing the setting surface 29a and the opening / closing cover 28c at different positions in the outer casing 20b in this manner, the setting surface does not rattle or shift in position due to the cover opening / closing operation.

  The relationship between the opening / closing cover 28c and the stapler unit 26 will be described with reference to FIG. As described in FIG. 5, the stapler unit 26 is supported by the guide rails (running rail surface 42x formed in the opening groove of the bottom frame 20e) and the running cam surface 43x (slide cam; cam member). The stapler unit 26 moves in the manual feed area Fr between the needle loading position Np and the manual binding position Mp (see FIG. 8). Then, at the needle loading position Np, the stapler unit 26 swings the angle to a predetermined angle (60 degrees) by the action of the stopper surface 43y, and this angle is aligned with the angular direction in which the staple cartridge 39 is loaded (FIG. 16).

  On the above-mentioned setting surface 29a, the abutting restriction surfaces 29x and 29y of the sheet bundle to be set are arranged. A first restricting surface 29x that locks the side edge end surface of the sheet bundle and a second restricting surface 29y that locks the trailing edge end surface of the sheet bundle are provided inside the setting portion 29. Therefore, when the sheet bundle is inserted into the slit-shaped setting surface 29a from the outside of the apparatus, the side edge of the sheet bundle is locked by the first restriction surface 29x and the rear edge is positioned by the second restriction surface 29y.

  As shown in FIG. 17, the setting surface 29a is provided with a sensor Se4 that detects a state in which the sheet bundle is engaged with the first regulation surface 29x and the second regulation surface 29y. The first regulation surface 29x has a first paper contact lever 85 that engages with the subsequent sheet bundle, and the second regulation surface 29y has a second paper contact lever 86 that engages with the rear edge of the sheet bundle. It is pivotally supported.

  A sensor flag 85f that is driven by the swing motion of the first paper contact lever 85 and a sensor flag 86f that is driven by the swing motion of the second paper contact lever 86 are arranged, and this sensor flag 85f (86f) is used by the photo sensor Se4. It is arranged to detect. That is, the first paper contact lever 85 holds the sensor flag 85f in the OFF position by an unillustrated biasing spring, and similarly the second paper contact lever 86 also holds the sensor flag 86f in the OFF position by an unillustrated biasing spring. . When the sheet bundle is inserted, both the first and second paper contact levers 85 and 86 move the sensor flags 85f and 86f to the ON position, which is detected by the photo sensor Se4.

[Image forming system]
As shown in FIG. 1, the image forming unit A includes a paper feeding unit 1, an image forming unit 2, a paper discharging unit 3, and a signal processing unit (not shown), and is incorporated in the apparatus housing 4. The sheet feeding unit 1 is composed of a cassette 5 for accommodating sheets, and the one shown in the figure is composed of a plurality of cassettes 5a, 5b, 5c so that sheets of different sizes can be accommodated. Each of the cassettes 5a to 5c includes a sheet feeding roller 6 for feeding a sheet and a separating unit (separating claw, separating roller, etc .; not shown) for separating the sheets one by one.

  Further, the sheet feeding section 1 is provided with a sheet feeding path 7 to feed the sheet from each cassette 5 to the image forming section 2. A pair of registration rollers 8 is provided at the end of the sheet feeding path 7 to align the leading edges of the sheets sent from the cassettes 5 and to wait until the sheets are fed in accordance with the image forming timing of the image forming section 2.

As described above, the sheet feeding unit 1 is configured by a plurality of cassettes according to the device specifications and is configured to feed the sheet of the size selected by the control unit to the image forming unit 2 on the downstream side. Each of the cassettes 5 is detachably attached to the apparatus housing 4 so that sheets can be replenished.

  The image forming unit 2 can employ various image forming mechanisms for forming an image on a sheet. The one shown in the figure shows an electrostatic image forming mechanism. As shown in FIG. 1, a plurality of drums 9a to 9d composed of photoconductors (photoconductors) are arranged in the apparatus housing 4 in accordance with color components. A light emitting device (laser head or the like) 10 and a developing device 11 are arranged on each of the drums 9a, 9b, 9c and 9d.

  Then, a latent image (electrostatic image) is formed on the drums 9a to 9d by the light emitting device 10, and toner ink is attached by the developing device 11. The ink images attached on the respective drums are transferred to the transfer belt 12 for each color component, and the images are combined. The transferred image formed on the belt is transferred to the sheet sent from the paper feeding unit 1 by the charger 13 and fixed by the fixing device (heating roller) 14 and then sent to the paper discharge unit 3.

  The paper discharge unit 3 is composed of a paper discharge port 16 that carries a sheet into a paper discharge space 15 formed in the apparatus housing 4, and a paper discharge path 17 that guides the sheet from the image forming unit 2 to this paper discharge port. There is. A duplex path 18, which will be described later, is connected to the paper discharge unit 3 so that the sheet on which the image is formed is turned upside down and fed again to the image forming unit 2.

  The duplex path 18 reverses the sheet on which the image is formed on the front side by the image forming unit 2 and retransmits it to the image forming unit 2. Then, after the image is formed on the back side by the image forming section 2, the image is ejected from the paper discharge port 16. Therefore, the duplex path 18 is composed of a switchback path for reversing the conveying direction of the sheet sent from the image forming unit 2 and returning it to the apparatus, and a U turn path 18a for reversing the sheet returned to the apparatus. ing. In the illustrated apparatus, this switchback path is formed in the sheet discharge path 22 of the post-processing unit C described later.

[Image reading unit]
The image reading unit C includes a platen 19a and a reading carriage 19b that reciprocates along the platen. The platen 19a is formed of transparent glass, and is composed of a still image reading surface for scanning a still image by the movement of the reading carriage 19b and a running image reading surface for reading a document image traveling at a predetermined speed.

  The reading carriage 19b includes a light source lamp, a reflecting mirror that changes the reflected light from the original, and a photoelectric conversion element (not shown). The photoelectric conversion element is composed of a line sensor arranged in the document width direction (main scanning direction) on the platen, and the reading carriage 19b reciprocates in the sub-scanning direction orthogonal to the line sensor to read the document image in line order. It has become. Further, above the traveling image reading surface of the platen 19a, an automatic document feeding unit D for traveling the document at a predetermined speed is mounted. The automatic document feeding unit D is configured by a feeder mechanism that feeds document sheets set on a paper feed tray one by one to a platen 19a, reads an image, and then stores the image in a paper discharge tray.

[Description of control configuration]
The control configuration of the above-described image forming system will be described with reference to the block diagram of FIG. The image forming system shown in FIG. 19 includes a control unit 70 (hereinafter referred to as “main body control unit”) of the image forming unit A and a control unit 75 (hereinafter referred to as “binding process”) of a post-processing unit B (sheet bundle binding processing device; Control unit)). The main body control unit 70 includes a print control unit 71, a paper feed control unit 72, and an input unit 73 (control panel).

  Then, the "image forming mode" and the "post-processing mode" are set from the input unit 73 (control panel). The image forming mode includes mode settings such as color / monochrome printing, double-sided / single-sided printing, and image forming conditions such as sheet size, sheet quality, number of printouts, and enlarged / reduced printing. The "post-processing mode" is set to, for example, "print-out mode", "staple binding processing mode", "eco-binding processing mode", "jog sorting mode", or the like. Note that the illustrated apparatus is provided with a "manual binding mode", in which, apart from the main body control unit 70 of the image forming unit A, the binding processing operation of the sheet bundle is executed off-line.

  Further, the main body control unit 70 transfers the post-processing mode, the number of sheets, the number of copies information, the paper thickness information of the sheets to be image-formed, etc. to the binding processing control unit 75. At the same time, the main body control unit 70 transfers a job end signal to the binding processing control unit 75 each time image formation is completed.

  Explaining the above-mentioned post-processing mode, in the above-mentioned “print-out mode”, the sheets from the paper discharge port 23 are accommodated in the stack tray 25 via the processing tray 24 without binding processing. In this case, the sheets are stacked on the processing tray 24 and stacked, and the stacked sheet bundle is carried out to the stack tray 25 by a jog end signal from the main body control unit 70.

  In the "staple binding processing mode (second paper ejection mode)", sheets from the paper ejection port 23 are accumulated on the processing tray and aligned, and the bundle of sheets is bound and then stored in the stack tray 25. In this case, as a general rule, the sheets to be imaged are designated by the operator as sheets having the same paper thickness and the same size. In this staple binding processing mode, any one of “multi-binding”, “right corner binding”, and “left corner binding” is selected and designated. Each binding position is as described above.

  The "jog sorting mode" is divided into a group in which sheets on which images are formed in the image forming unit A are stacked on the processing tray by offsetting, and a group in which the sheets are stacked without being offset, and are alternately stacked on the stack tray 25. The offset sheet bundle and the non-offset sheet bundle are stacked. Particularly, in the illustrated apparatus, an offset area (see FIG. 5) is provided on the front side of the apparatus, and a group in which sheets carried out by the center reference Sx from the sheet discharge port 23 are stacked on the processing tray in that posture, and the center reference is also used. The sheets carried out by Sx are divided into groups in which the sheets are offset by a predetermined amount on the front side Fr of the apparatus and stacked.

  The reason why the offset area is arranged on the apparatus front side Fr in this way is to secure a work area for manual binding processing, needle cartridge replacement processing, etc. on the apparatus front side. The offset area is set to a size (about several centimeters) that divides the sheet bundle.

"Manual binding mode"
On the front side of the apparatus, the outer casing 20b is provided with a manual feed setting section 29 for setting a sheet bundle to be bound by an operator. A sensor for detecting the set sheet bundle is arranged on the setting surface 29a of the manual feeding setting unit 29, and the binding process control unit 75, which will be described later, moves the stapler unit 26 to the manual binding position by a signal from the sensor. To do. When the operator presses the operation switch 30, the binding process is executed.

  Therefore, in this manual binding mode, the binding processing control unit 75 and the main body control unit 70 are controlled off-line. However, when the manual binding mode and the staple binding mode are executed at the same time, the mode is set so that one of them takes precedence.

[Binding control unit]
The binding processing control unit 75 operates the post-processing unit C according to the post-processing mode set by the image forming control unit 70. The binding processing control unit 75 shown in the figure is composed of a control CPU (hereinafter simply referred to as control means). A ROM 76 and a RAM 77 are connected to the control CPU 75, and a control program stored in the ROM 76 and control data stored in the RAM 77 execute a paper discharge operation described later. Therefore, the control CPU 75 is connected to the drive circuits of all the drive motors described above, and controls the start, stop, and forward / reverse rotation of each motor.

[Description of post-processing operation]
The operation state of each binding process will be described below with reference to FIGS. For convenience of explanation, the "paddle" means the sheet carrying-in means (paddle rotating body 36, etc.), the "knurling" means the scraping rotating body 33, the "aligning plate" means the side aligning member 45, and the "assisting". "" Means the first and second conveying members 60A, 60B, "button" means an operation switch of the stapling apparatus, and "LED" means an indicator lamp that the stapling operation is being executed.

"Staple mode"
In FIG. 20, the final paper for image formation is image-formed and is carried out from the upper image forming unit main body (St01). At this time, a job end signal is issued from the image forming unit, and the binding operation control unit 75 causes the paddle 36 to be positioned and waits at a predetermined position (waiting for paddle blades) (St02). At the same time, the left and right matching plates 46R and 46F are moved to the standby position (St03). Then, the sheet fed from the sheet discharge port 16 of the image forming unit A is carried in from the carry-in port 21 of the sheet carry-in path (sheet discharge path) 22, and the sheet sensor Se1 discharges the sheet rear end from the sheet discharge roller 32. It is detected (St04).

  The control means 75 lowers the paddle 36 waiting on the processing tray when the trailing edge of the sheet leaves the discharge roller 32 (St05). This operation is executed by activating the paddle lifting motor M3. Simultaneously with the paddle lowering operation, the control means 75 raises the knurl 33 and retracts the uppermost sheet on the processing tray upward (St08).

  By the above operation, the sheet sent from the image forming unit A is sent to the sheet carry-in path 22 and the rear end of the sheet passes through the sheet discharge roller 32, and then the paddle 36 is discharged while the knurl 33 is retracted above the tray. The sheet is conveyed backward by rotating in the direction opposite to the paper. As a result, the sheet sent to the sheet carry-in path 22 is reversed in the conveying direction at the sheet discharge port 23 and is stored in the processing tray 24 below the sheet discharge port.

  Next, the control means 75 conveys the sheet back from the sheet discharge port 23 in the opposite direction to the sheet discharge, and after a predetermined time, raises the paddle to retract the sheet (St06). At the same time, the knurl 33 rotating in the direction opposite to the sheet discharge is lowered from the standby position to engage with the sheet carried onto the processing tray (St09).

  Through the above operation, the sheet is sent out from the sheet discharge port 23 by the sheet discharge roller 32, is reversed and conveyed in the opposite direction to the sheet discharge from the sheet discharge port 23 by the paddle 36, and is carried onto the processing tray. Then, the knurls 33 feed the processing tray toward a predetermined position (rear end regulating member 41).

  In the above-described paper discharge operation, sheets of different sizes are carried out from the paper discharge port 23 according to the center reference Sx. It is also possible to carry out the paper from the paper discharge port 23 on the basis of one side, but for convenience of description, a case where the paper is carried out at the center reference Sx will be described.

  Next, the control unit 75 uses the paddle 36 at the estimated time when the trailing edge of the sheet carried onto the processing tray hits the predetermined trailing edge regulation stopper (rear edge regulation member) 41 based on the detection signal of the sheet ejection sensor Se2. To the home position (HP) (St07). Similarly, the knurl 33 also moves to the home position HP (St10).

  Next, the control means 75 causes the aligning means 45 to align the sheets with the trailing edge abutting the trailing edge regulating member 41. In this alignment operation, the alignment position of the sheet is made different when the "multi-binding mode" is designated and when the "corner binding mode" is designated. When the "multi-binding mode" is designated, the control unit 75 separates the sheet carried on the processing tray from the alignment position that matches the size width according to the discharge standard (the center standard Sx in the figure) to the outside. The left and right side aligning members 46F and 46R are reciprocally moved to and from the standby position (center alignment). That is, the control unit 75 moves the side aligning members 46F and 46R based on the size information sent from the image forming unit A from the standby position wider than the size width to the aligning position suitable for the size width, thereby aligning the sheets. (St11-13).

  Further, when the "corner binding mode" is designated, the control means 75 moves the side alignment member on the binding position side of the left and right side alignment members 46F and 46R to the binding position and makes it stand still, based on the size information. The side alignment member on the side is moved from the standby position retracted from the side alignment member to the alignment position based on the size width of the sheet carried into the processing tray 24. The alignment position (of the movable-side alignment member) is set to have a distance relationship (corner binding position alignment) with the stationary alignment position (of the binding position-side alignment member) that matches the size width. Therefore, at the time of the corner binding process, one side alignment member is moved to the designated binding position on either the left side or the left side, and the side alignment member on the opposite side is adjusted to the size width after the sheet enters the processing tray 24. , The position is moved to match (one-sided reference). (St14 to St16)

  Next, the control unit 75 executes the binding operation (St17). In the case of multi-binding, the stapler unit 26 which is stationary at the binding position is operated in advance to perform the binding process at that position, and then the unit is moved along the trailing edge of the sheet for a predetermined distance to perform the binding process at the second binding position ( St18-St20). At the time of corner binding, the stapler unit 26 that is stationary at the binding position is operated in advance to perform binding processing.

  Next, when the control means 75 receives the signal indicating the end of operation from the stapler unit 26, the control means 75 operates the sheet bundle carry-out means 60 to carry out the sheet bundle from the processing tray 24 toward the stack tray 25 on the downstream side (St21). When the sheet bundle unloading operation is completed, the control means 75 returns the sheet bundle unloading means 60 to the initial position (St22). At the same time, the aligning means 46 is moved back to the initial position (standby position for loading the sheet into the processing tray 24) (St23).

  Further, the control means 75 rotates the bundle pressing means (elastic pressing member) 53 arranged on the stack tray by the drive motor (the drive motor M2 shown is the same as the paddle rotating body 36) (St24). The uppermost sheet of the sheet bundle carried into the stack tray 25 is pressed and held (St25).

"Eco-binding mode"
In the eco-binding operation, the control means 75, similar to the above-described operation, positions the sheet carried on the processing tray against the trailing edge regulating member 41 and positions the same. The operations from step St01 to step St10 are the same as those described above. Therefore, the same reference numerals are given and description thereof will be omitted.

  When the stapleless binding process is designated, the control unit 75 sets the left side alignment member 46R located on the binding unit side to the alignment position (eco-position) close to the eco-binding position Ep before loading the sheet on the processing tray. It moves to the alignment position Ap2) and stands by in a stationary state (St26). Simultaneously with this operation, the control means 75 moves the sheet bundle guide guide from the retracted position above the tray to the operating position on the tray (St27). This shift of the guide height is configured so that the height position of the guide surface moves from the high retracted position to the low operating position in conjunction with the position movement of the stapler unit 26 in the drawing. Therefore, the control means 75 moves the stapler unit 26 from a predetermined position (home position) to a position where it engages with the sheet bundle guide. In the case of the present application, it is set so as to engage with the sheet bundle guide when it is at the position Gp between Ma2 (multi-binding position on the left in the drawing) and CP2 (in the corner binding position on the left in the drawing) in FIG.

  After that, the control unit 75 moves the opposite right side alignment member 46F to the standby position away from the side edge of the sheet carried on the tray (St28). Then, the alignment motor is driven to move the right side alignment member 46F to the alignment position (St29). This alignment position is set at a position where the distance from the left side alignment member 46R that is stationary at the eco alignment position matches the width size of the sheet.

  As described above, the present invention is characterized in that the carry-in sheet is not aligned with the binding position on the processing tray during the eco-binding, but is aligned with the eco-alignment position Ap2 apart from the binding position. When the eco-alignment position Ap2 is set as the carry-out standard (for example, the center standard) of the sheet from the paper discharge port 23, the eco-aligned position Ap2 becomes the same as the alignment position of the multi-binding process. When this is set to a position close to the eco-stapling position Ep, the sheets do not interfere with the eco-stapling unit 27 to cause a sheet jam when the sheets are aligned, and the distance to move the sheet bundle to the eco-stapling position after the sheet is aligned. Can be shortened. Therefore, it is preferable that the eco-alignment position Ap2 is set to a position as close as possible within a range where the sheet does not interfere with the binding unit.

  Next, the control means 75 offset-moves the sheet bundle aligned at the eco-alignment position Ap2 to the eco-binding position Ep by the side alignment member 46 (St30). Then, the side aligning member 46F located on the front side of the apparatus is retracted so as to be separated from the seat by a predetermined amount (St31). Therefore, the aligning unit 45 drives the sheet bundle conveying unit 60 to move the sheet bundle by a predetermined amount to the downstream side in the paper discharge direction (St32). At the same time, the stapler 26 is moved to the initial position and the sheet bundle guide (not shown) is made to stand by at the retracted position above the tray (St33). Next, the control means 75 moves the right side alignment member 46F to the home position (St34).

  Therefore, the control means 75 sends a command signal to the stapleless binding means (press binder unit) 27 to execute the binding processing operation (St35). Then, the control means 75 operates the kicker means constituted by the side alignment member 46R (apparatus rear side) located on the eco binding position side. In the operation of the kicker means, first, the side aligning member 46R is moved backswing (FIG. 15; overrun amount) to a position away from a position where the side aligning member 46R engages with the side edge of the sheet. This backswing amount is set in consideration of the rise time (self-excitation time) of the matching motor M6. That is, the matching member 46R (kicker means) is provided with a run-up time, and the overrun amount is set to the rise time at which the motor reaches a predetermined output torque.

  Therefore, when the control means 75 receives the processing end signal from the binder unit 27, it drives the alignment motor M6 of the left side alignment member 46R to move the alignment member to the sheet center side by a predetermined amount. The sheet bundle pinched by the press binder unit 27 by this operation is peeled off and offset to the sheet center side by being kicked to the sheet center side from a state of being in close contact with the uneven pressure surface (St37).

Explaining this kicker mechanism,
(1) The kicking direction of the illustrated left side aligning member 46R (kicker means) (the direction in which the sheet is fed with a conveying force; the same applies hereinafter) is the same direction as the linear direction (rib direction) of the pressing surface, or this is the reference. It is preferable that the angle direction is slightly inclined in the ± direction (for example, about 0 degree to 30 degrees). As shown in FIG. 18, when the conveying force is applied in the z direction (direction orthogonal to the rib) as viewed in the arrow, the bundling of the sheet bundle is loosened and easily separated, and when the conveying force is applied in the w direction as illustrated, the sheet bundle is bound. In this state, it is easy to peel from the pressure surface. This angle direction is set by an experiment, but in the experiment by the present inventor, 0 ± 30 degrees is preferable based on the rib direction (0 degree).

(2) The kicker means employs a mechanism that presses (feeds) the edge of the bound sheet bundle toward the sheet center. For example, as shown in the figure, the sheet on the processing tray is configured by a left side aligning member 46R (in the case of right corner binding, a right side aligning member 46F) that aligns the sheets in the widthwise direction (in the direction perpendicular to the sheet discharge). As described above, it is preferable to employ a conveyance mechanism that applies a force in the separating direction to the entire stack when separating the bound sheet bundle from the pressing surface. For example, when the sheet is conveyed from above the sheet bundle in the kick direction by the nip roller, only the sheet in contact with the roller is peeled off, which causes a problem of loosening the bundle.

(3) As a kicker means, a floating mechanism is employed that applies a kick force in a direction of separating the bound sheet bundle (a direction intersecting the sheet discharge direction) and at the same time floats the lower surface of the sheet bundle from the pressing surface of the binder mechanism. It is also possible to do so. Although the structure is not shown, for example, a bent bottom piece that engages with the lower surface of the sheet bundle is provided, and an inclined cam surface that protrudes above the paper loading surface at the binding position is provided on the back surface of the processing tray. ) Provide. Along with this, the side aligning member is provided with a restricting surface that engages with the sheet bundle end surface on the paper mounting surface.

  When the side aligning member 46R (kicker means) is positioned outside the paper loading surface (back swing area), the bent bottom piece supports the sheet in the same plane as the paper loading surface without being affected by the inclined cam surface. . Then, when the side aligning member is kicked to the binding position side, the bent bottom piece pushes the sheet bundle upward, and at the same time, the regulation surface functions to push the end surface of the sheet bundle to the sheet front end side. That is, when the side aligning member 46R is kicked toward the binding position, an action member (bottom support member) that pushes up the bound sheet bundle upward from the pressing surface and an action member that pushes the edge of the sheet bundle toward the center side. By providing the (side surface regulating member), the sheet bundle can be more reliably peeled off from the pressing surface.

"Printing out"
It will be described with reference to FIG. When the sheet is unloaded from the image forming unit A (St40), the front end of the sheet sensor is detected, and the paddle rotating body 36 is moved to the standby position (St41). At the same time, the side aligning member 46 is moved to the standby position (St42). Next, when the trailing edge of the sheet passes through the paper discharge roller 32 (St43), the control means 75 lowers the paddle rotating body 36 to the operating position (St44). Along with this, the knurled rotor 33 is raised and retracted (St45).

  The control means 75 raises the paddle rotating body 36 and moves it to the retracted position when a predetermined time elapses after the trailing edge of the sheet passes through the paper discharge roller 32 (St46). At the same time, the knurled rotor 33 is lowered to the operating position and the sheet is transported toward the trailing edge regulating member 41 (St47). The control means 75 moves the paddle rotating body 36 to the home position at the estimated time when the rear end of the seat reaches the regulating member 41 (St48). Alternatively, the knurled rotor 33 is moved to the home position (St49).

  Therefore, the control means 75 moves the side aligning member 45 to the aligning position to execute the aligning operation. In this aligning operation, sheets of different sizes are stacked based on the sheet center, and the sheets are sent to the stack tray 25 in the subsequent unloading operation. When a large-sized sheet is carried onto the tray in this print-out sheet discharge operation, an out-of-specification size sheet discharge operation described later is executed.

  The control unit 75 aligns and stacks the sheets on the processing tray, and discharges the sheet bundle to the stack tray 25 on the downstream side. The operation moves the first conveying member 60A of the sheet bundle discharging mechanism 60 in the paper discharge direction (St50). Next, the tray sheet pressing member 53 is moved to the standby position (St51). Then, at the timing when the sheet bundle is loaded onto the stack tray, the tray sheet pressing member 53 is rotated by a predetermined angle to press the uppermost sheet (St52). After that, the control means 75 returns the side alignment member 45 to the sheet carry-in position (St53).

"Sort (jog) mode"
The jog mode shown in FIG. 23 is executed in substantially the same steps as the above-mentioned printout mode, and therefore, the same steps will be denoted by the same reference numerals and description thereof will be omitted, and different steps will be described. When the sheets are loaded onto the processing tray, the control means 75 collects the sheets at different positions in the group that aligns the sheets with the center reference Sx and the group that aligns the sheets with the right side reference (St54), and in that posture, the downstream side. To the stack tray 25. It should be noted that the sheets are aligned on the right side reference because the processing tray 24 is arranged at a position biased to the front side of the apparatus, and the sheets on the paper placing surface are stacked on the basis of the center and the sheets on the right side of the operator's side. Therefore, it becomes easy to take out the sheet bundle from the stack tray 25.

"Common operation in each mode"
A common operation of loading a sheet onto the processing tray when executing each of the above-described post-processing modes will be described with reference to FIG. When the sheet is discharged from the image forming unit A (St60), the control unit 75 positions the paddle rotating body 36 at the standby position (St61) by the leading edge detection signal from the sheet sensor Se1 and waits for the predetermined alignment member 45. Move to the position (St62). In this operation, the sheet size signal sent from the image forming unit A causes the aligning member 45 to be positioned at the standby position whose width size is slightly wider.

  Next, the control means 75 lowers the paddle rotating body 36 from the upper standby position to the lower operating position at the timing when the trailing edge of the sheet passes through the discharge roller 32 (St63) (St64). At the same time, the knurled rotor 34 is lowered from the standby position above the paper mounting surface to the operating position on the paper mounting surface (St65). At this time, both the paddle rotating body 36 and the knurling rotating body 34 are rotating in the direction opposite to the sheet discharge.

  Then, the control means 75 raises the paddle rotating body 36 from the operating position to the standby position when a predetermined time (expected time when the rear end of the sheet reaches the knurling rotating body position) has passed (St65). The control unit 75 raises the knurled rotor 36 by a small amount after a predetermined time (the time when the leading edge of the sheet reaches the trailing edge regulating member) elapses (St69). The lift amount of the paddle rotating body is set in advance and is set from an experimental value that reduces the pressing force on the sheet.

  Next, the control means 75 moves the side aligning member 45 to the aligning position (St70). This alignment position is set to a different position in the binding processing mode, and the sheets are stacked at the reference position described above for each mode.

That is, when (1) multi-stapling is performed in the staple binding processing mode, the sheets carried onto the processing tray are aligned with the center reference. Further, in the case of right corner binding, the sheet carried in on the processing tray is aligned with the right side reference Ap1, and in the case of left corner binding, the sheet carried in on the processing tray is aligned with the left side reference Ap2. In either case, the stapler unit 26 stands by at the binding position and prepares for the subsequent binding processing operation.
(2) In the stapleless binding processing mode, the control unit 75 aligns from the stapleless binding position to the stapleless alignment position Ap3 determined by the sheet center or the center reference.
(3) In the print-out processing mode, the control means 75 matches the center reference.
(4) In the jog processing mode, the control means 75 alternately repeats the group aligned with the center reference and the group aligned with the right side reference, and carries out to the stack tray 25 in that posture.

  Next, after finishing the above-mentioned alignment operation, the control means 75 moves the side alignment member 45 to the initial position (St71), and then lowers the knurling rotor 34 in the direction of pressing the sheet (St72). At the same time, the control means 75 raises the paddle rotating body 36 to the home position standby position and holds it at that position (St73).

"Manual stapling operation"
The manual binding operation will be described with reference to FIG. A sheet presence / absence sensor is provided in the manual feed setting unit, and when the sheet presence / absence sensor Se4 (hereinafter referred to as a sensor “Se4”) detects a sheet, the control unit 75 executes a staple binding operation.

  The control means 75 determines whether or not the taper unit is executing the binding processing operation based on the ON signal (St80) of the sensor Se4. When it is determined that the binding processing operation can be interrupted, the stapler 26 is moved to the manual binding position Mp (still when the stapler is located at this binding position) (St81). Then, the LED lamp indicating that the manual operation is being executed is turned on (St82).

  Next, the control means 75 confirms that the sensor Se4 is ON (St83), and then determines whether or not the operation button 30 has been operated (St84). When the sensor is on, or when the sensor is off and the LED lamp is turned on for a predetermined time (the one shown in the figure is set to 2 seconds) (St85), the LED lamp is turned on again (St86) and the sensor Se4 is turned on. After confirming that there is (St87), it is further determined whether or not a predetermined time has elapsed after the LED lamp is turned on. Then, the stapling operation is executed (St88).

  Next, after the stapling operation is performed, the control means 75 returns to a predetermined step and executes the stapling operation again when the sensor Se4 is in the ON state. This is because the binding process is executed at the rearmost positions of the sheet bundle. If the sensor Se4 detects the paper-out state and the paper-out state continues for a predetermined time, the stapler unit 26 is returned to the home position on the assumption that the sheet has been removed from the setting surface. When the stapler unit 26 sets the manual binding position to the home position, the stapler unit 26 is maintained at that position (St93).

  In the present invention, the manual stapling operation is performed by the ON / OFF signal of the sensor Se4 described above while the printout processing, the jog sorting processing, the stapleless binding processing are being executed on the processing tray, or during the preparation thereof. Perform processing operations. Further, during execution of the multi-binding operation on the processing tray and during execution of the corner binding operation, the manual operation is executed when the sheet stacking operation is executed and the jog end signal is not transmitted from the image forming unit A. It is possible. Even if the jog end signal is transmitted, the manual stapling operation is executed when the interrupt processing is instructed.

  As described above, it is preferable to adopt either means for prioritizing the manual stapling operation and the stapling operation for the processing tray when designing the apparatus, or arranging a priority execution key to allow the operator to select.

Ma1 Multiple binding position Ma2 Multiple binding position Cp1 Right corner binding position Cp2 Left corner binding position Mp Manual binding position Ep Needleless binding position (Eco binding position)
Sx Paper discharge standard (center standard)
20 device housing 20a device frame 20b exterior casing 20c right side frame 20d left side frame 20e bottom frame 22 sheet carry-in path (paper discharge path)
24 Processing Tray 25 Stack Tray 26 Staple Binding Means (First Binding Means)
27 Needleless binding means (second binding means) (press bind unit)
28c Open / close cover 29 Manual feed setting section 29a Manual setting surface 29x First restriction surface 29y Second restriction surface 30 Manual operation button 39 Needle cartridge 40 Sheet end restriction means (regulation stopper)
41 Rear end regulating member 42 Travel guide rail 43 Slide cam 45 Aligning means (side aligning member)
46 side aligning member 46F right side aligning member (apparatus front side)
46R Left side alignment member (device rear side)
60 sheet bundle unloading means 80 first drive unit 81 second drive unit 85 first paper contact lever 86 second paper contact lever

Claims (8)

A sheet processing apparatus for processing a sheet,
A transport path along which the sheet is transported,
Transporting means for discharging the sheet from the discharge port of the transport path by transporting the sheet in the transport direction,
First stacking means for stacking the sheets discharged from the discharge port by the conveying means,
Of the first sheet bundle stacked on the stacking means, by contacting the end portion in the direction intersecting the transport direction, of the sheet bundle, to regulate the position of the intersecting direction, and the first regulating means,
Second regulation means for regulating the position of the sheet bundle in the conveyance direction by contacting an upstream end of the sheet bundle stacked on the first stacking means in the conveyance direction,
The one-side sheet, which is configured to move from one side of the device to the other side and move from the other side to the one side by moving in the intersecting direction, and in which the first restricting means is in contact First binding means for binding the corner portion of the sheet bundle including the end portion of the bundle and the end portion of the sheet bundle in the transport direction, which is in contact with the second restriction means, with a needle,
A corner portion of the sheet bundle including an end portion of the sheet bundle on the one side with which the first regulating means contacts and an end portion of the sheet bundle with the second regulating means in the transport direction A second binding means for binding without using a needle,
Moving means for moving the sheet stack stacked on the first stacking means in the transport direction to move the sheet stack from the first stacking means;
A second stacking unit capable of stacking the sheet bundle moved from the first stacking unit by the moving unit and moving up and down;
A rack that can move up and down integrally with the second stacking means,
An elevating motor for elevating the second stacking means,
A pinion configured to mesh with the rack and rotated by the rotation of the lifting motor to lift and lower the rack;
The first binding means is movable in a state of being separated from the second binding means, and is configured so as not to move integrally with the second binding means at all times.
The pinion is arranged downstream of the first binding position where the first binding unit binds the sheet bundle in the transport direction, and downstream of the second binding position where the second binding unit binds the sheet bundle in the transport direction. And the first stacking means is arranged below a stacking surface for stacking sheets ,
The first restricting unit has a restricting surface that is in contact with an end portion of the sheet bundle stacked on the first stacking unit in the intersecting direction,
An upstream end of the regulation surface in the transport direction is located downstream of a binding position in the transport direction where the second binding unit binds the sheet bundle stacked on the first stacking unit.
A sheet processing apparatus characterized by the above. The second binding unit binds the sheet bundle by pinching the sheet bundle,
The sheet processing apparatus according to claim 1, wherein: The second binding means has a first surface on which a plurality of protrusions are formed and a second surface on which a plurality of recessed grooves matching the plurality of protrusions are formed. The sheet bundle is bound by pressing the sheet bundle with two surfaces,
A corner portion of the sheet bundle including an end portion of the sheet bundle on the one side with which the first regulating means contacts and an end portion of the sheet bundle with the second regulating means in the transport direction When the second binding means binds, a plurality of traces corresponding to the plurality of protrusions are formed in the sheet bundle side by side in a direction inclined by a predetermined angle with respect to the intersecting direction,
The sheet processing apparatus according to claim 2, wherein: Wherein the first binding means, said second regulating means is in contact, the end of the sheet bundle in the conveying direction, it is possible to bind a plurality of locations, one of the claims 1 to 3, characterized in that 2. The sheet processing apparatus according to item 1. An image forming apparatus for forming an image on a sheet,
An image forming means for forming an image on a sheet,
A transport path along which the sheet transported in the transport direction from the image forming unit is transported,
Transporting means for discharging the sheet from the discharge port of the transport path by transporting the sheet in the transport direction,
First stacking means for stacking the sheets discharged from the discharge port by the conveying means,
Of the first sheet bundle stacked on the stacking means, by contacting the end portion in the direction intersecting the transport direction, of the sheet bundle, to regulate the position of the intersecting direction, and the first regulating means,
Second regulation means for regulating the position of the sheet bundle in the conveyance direction by contacting an upstream end of the sheet bundle stacked on the first stacking means in the conveyance direction,
The one-side sheet, which is configured to move from one side of the device to the other side and move from the other side to the one side by moving in the intersecting direction, and in which the first restricting means is in contact First binding means for binding the corner portion of the sheet bundle including the end portion of the bundle and the end portion of the sheet bundle in the transport direction, which is in contact with the second restriction means, with a needle,
A corner portion of the sheet bundle including an end portion of the sheet bundle on the one side with which the first regulating means contacts and an end portion of the sheet bundle with the second regulating means in the transport direction A second binding means for binding without using a needle,
Moving means for moving the sheet stack stacked on the first stacking means in the transport direction to move the sheet stack from the first stacking means;
A second stacking unit capable of stacking the sheet bundle moved from the first stacking unit by the moving unit and moving up and down;
A rack that can move up and down integrally with the second stacking means,
An elevating motor for elevating the second stacking means,
A pinion configured to mesh with the rack and rotated by the rotation of the lifting motor to lift and lower the rack;
The first binding means is movable in a state of being separated from the second binding means, and is configured so as not to move integrally with the second binding means at all times.
The pinion is arranged downstream of the first binding position where the first binding unit binds the sheet bundle in the transport direction, and downstream of the second binding position where the second binding unit binds the sheet bundle in the transport direction. And the first stacking means is arranged below a stacking surface for stacking sheets ,
The first restricting unit has a restricting surface that is in contact with an end portion of the sheet bundle stacked on the first stacking unit in the intersecting direction,
An upstream end of the regulation surface in the transport direction is located downstream of a binding position in the transport direction where the second binding unit binds the sheet bundle stacked on the first stacking unit.
An image forming apparatus characterized by the above. The second binding unit binds the sheet bundle by pinching the sheet bundle,
The image forming apparatus according to claim 5 , wherein The second binding means has a first surface on which a plurality of protrusions are formed and a second surface on which a plurality of recessed grooves matching the plurality of protrusions are formed. The sheet bundle is bound by pressing the sheet bundle with two surfaces,
A corner portion of the sheet bundle including an end portion of the sheet bundle on the one side with which the first regulating means contacts and an end portion of the sheet bundle with the second regulating means in the transport direction When the second binding means binds, a plurality of traces corresponding to the plurality of protrusions are formed in the sheet bundle side by side in a direction inclined by a predetermined angle with respect to the intersecting direction,
The image forming apparatus according to claim 6 , wherein An image forming apparatus for forming an image on a sheet,
A sheet processing device for accumulating and binding the sheets sent from the image forming apparatus,
An image forming system, wherein the sheet processing apparatus is the sheet processing apparatus according to any one of claims 1 to 4 .

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