JPH0977354A - Sheet post-handling device provided with sheet bundle stacking device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To stop driving means relating to a stack and continue the operation of a sheet sorting device when a taking-out cover for taking out a bundle of stacked sheets is opened. SOLUTION: When a bin cover is opened to take out a bundle of sheets stacked on a stack unit, a bin cover switch 301a interlocking with the bin cover is operated, for example turned OFF, the second driving means, such as a bundle handling moving-up/down motor M4, motors in a bundle handling unit (for example, M7, M8, M9, M10), a stack unit moving-up/down motor M11, and motors in the stack unit (for example, M13, M14), are stopped and the first driving means, such as a bin shift motor, a M1 straightening motor M2, transfer motors (M14, M15, M16) are continuously drived, thereby continuing the sorting operation of a sheet sorting device and keeping the working efficiency of the sheet sorting device.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to, for example, sheets which are sequentially discharged and conveyed one by one from an image forming apparatus.
The present invention relates to a sheet post-processing device that sorts and stacks sheets on a stacking unit, stacks a sheet bundle on a stack unit by binding and transferring the bundle in a bundle processing unit.

[0002]

2. Description of the Related Art Conventionally, there is known a sheet sorting apparatus for stacking discharged sheets to be conveyed and stacking them on a stacking means. A plurality of stacking means are provided above and below, and while the sheets are sorted by one stacking means, the other stacked sheet bundle is bound by the binding means in the bundle processing unit and stacked by the transfer means. A sheet post-processing apparatus that conveys the sheet to the unit has been considered.

The bundle processing unit in this sheet post-processing apparatus moves the sheet bundle to the upper and lower positions corresponding to the sorted stacking means and stops it. In order to receive the sheet bundle from the bundle processing unit, the stack unit can be stopped not only in a vertical position below the bundle processing unit but also in a take-out position for taking out the sheet bundle.

The apparatus main body of the sheet post-processing apparatus includes a front plate as a front door for covering the front surface of the apparatus main body, an upper cover for covering the upper portion of the apparatus main body, a bin cover for covering the sheet sorting apparatus section,
Etc. are provided. The front cover is opened and closed during maintenance of the inside of the apparatus, jam processing, and when taking out the sheet bundle stacked in the stack unit.

When the front cover is opened, all of the sheet post-processing devices such as the sorting operation of the sheet sorting device, the stack processing operation of the stack processing unit, and the stack operation of the stack unit are performed by the operation of the switch by opening the front cover. Is supposed to stop working.

[0006]

However, in the above-mentioned apparatus, if the opening of the front cover of the apparatus main body is for maintenance or jam processing, it is necessary to stop the operation of the entire sheet post-processing apparatus. As necessary, the operation of taking out the sheet bundle in the stack unit is
Since it is not an abnormal state for the device such as maintenance or jam processing, stopping the operation of the entire sheet post-processing device is not only the operation efficiency of the sheet post-processing device but also the image to output the sheet to this. There is a problem that the operating efficiency of the forming apparatus main body decreases.

According to the present invention, in order to take out a sheet bundle in the stack unit, even if the cover is opened, the operation of conveying the sheets to the stacking means, the shifting operation of the plurality of bins in the stacking means, and the alignment of the stacked sheets are performed. It is an object of the present invention to provide a sheet post-processing apparatus which enables continuous sorting operations of the sheet sorting apparatus such as operations and the like and maintains the operation efficiency of the sheet sorting apparatus.

[0008]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and a plurality of vertically arranged stacking means for sorting and stacking sheets conveyed by the conveying means, and the above-mentioned stacking means. An aligning means for aligning the sheet bundle, a bundle processing unit for performing the bundle processing of the aligned sheet bundle, a transfer means provided in the bundle processing unit for transferring the sheet bundle, and a binding means for binding the sheet bundle, A stack unit that stores the sheet bundle transferred by the transfer unit, a stack tray and a reference plate that are vertically movable in the stack unit, a unit that drives the transport unit, and a plurality of bin trays of the stacking unit. First driving means including means for shifting the stacking means and means for driving the aligning means, and the bundle processing unit at a vertical position corresponding to the stacking means. Means for lowering, means for driving transfer means and binding means in the bundle processing unit, means for raising and lowering the stacking means to a vertical position corresponding to the stacking means and a take-out position in the middle thereof, stack in the stacking unit Second driving means including a means for driving the tray and the reference plate, a take-out cover that is opened and closed for operating the stack unit at the take-out position, and a take-out cover switch that is turned on and off when the take-out cover is opened and closed. When the take-out cover is opened and the take-out cover switch is turned off, the driving operation of the first drive means is continued, and the second
A sheet post-processing apparatus having a stacking device, the control means controlling the driving operation of the driving means of 1. to be stopped.

[Operation] Based on the above configuration, the sheets conveyed by the conveying means are stacked on the stacking means and aligned by the aligning means. The aligned sheet bundle is bound by the binding means in the bundle processing unit as needed, and then stacked and stored in the stack unit.

At the time of taking out the sheet bundle in the stack unit, the stack unit is moved to the take-out position, and the take-out cover dedicated to taking out the sheet bundle is opened. When the take-out cover switch is turned off by opening the take-out cover, the driving operation of the second drive means, that is, the lifting and lowering operations of the bundle processing unit and the stack unit, the binding operation and the transfer operation of the sheet bundle in the bundle processing unit, and the stack For example, only the operation of raising and lowering the stack tray in the unit is stopped.

Thus, the operation of transporting the sheets to the stacking means, the bin shifting operation of the stacking means, the aligning operation of the sheet bundle on the stacking means, etc. are performed regardless of the opening of the take-out cover.
Sheets are sorted continuously. As a result, the operating efficiency of the sheet post-processing device can be maintained.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows an electrophotographic copying machine (image forming apparatus) 200 as a sheet output device.

The electrophotographic copying machine 200 includes a copying machine main body 20.
1 and an automatic document feeder 2 arranged at the top of the copying machine main body
02, and a sheet post-processing device 203 arranged on the side of the copying machine main body 201 where the sheet S is discharged. The sheet post-processing device 203 includes a folding device 204 and a stapling / stacking device 205.

The document table 20 of the automatic document feeder 202
6 are separated in order from the bottom,
Pass 20 on the platen glass 208 of the copying machine body 201
After being read by the optical system 210 of the main body 201 of the copying machine, the sheet is discharged from the platen glass 208 via the path 211 to the uppermost surface on the document table 206. The sheet S is fed from the deck 212, image-formed by the image forming unit 213, fixed by the fixing unit 214, and generally passes through the folding device 204 to staple / staple.
The sheet is conveyed to the sheet entrance 215 of the stacking device 205.

The image forming process of the copying machine 200, which is the main body of the present invention, is well known and will not be described here. The stapling / stacking device 205 is shown in FIG.
As shown in FIG. 2, it has bin modules B ₁ and B ₂ which are vertically divided into _two , and each bin module has a plurality of bins (sheet trays) B _{11 to} B _1n and B _{21 to} B _2n (in the figure, n =
6). Each bin module can change the bin interval and bin position independently and move each bin to the sheet receiving position or the sheet bundle discharging position.

At the sheet carry-in port 215, the first upward
It is driven by a solenoid SL3 (not shown) that switches between the transport path 1 and the second transport path 2 in the downward direction. The deflector 3 determines the traveling direction of the sheet S. Further, the first transport path 1 is branched into a carry-out path 6 to the non-sort tray 5 and an upper bin module B _{1 to the} path 7 by a deflector 4 driven by a solenoid SL4 (not shown).

On the other hand, the second transport path 2 is a path to the lower bin module B as it is. Therefore, for each roller pair 8a to 8p, the non-sort tray 8a, 8p
b, 8c, 8a, 8b, 8d to 8 for the upper bin module
g, the lower bin module is conveyed by roller pairs 8a and 8h to 8p.

Further, the stapling / stacking device 205
1 has a grip / staple unit (bundle processing unit) 9 in a space between the path to the upper bin module and the path to the lower bin module. After being conveyed in the right direction and selectively stapled by the stapler 11, the front end of the bundle is nipped by the conveyance gripper 12 and further conveyed in the right direction. Similarly, in the space between the path to the upper bin module and the path to the lower bin module, the stack unit 13 stands by below the grip / staple unit 9,
The bundle transported by the transport gripper 12 is stored.

As shown in FIG. 2, the right end of the stapler 11 and the left end of the stack unit 13 are substantially overlapped in the left-right direction (area of width l _{15 in} FIG. 2).

After the bins B _{11 to} B ₁₆ of the upper bin module B ₁ are filled with the sheet bundle, the grip / staple unit 9 is moved to the position shown by the broken line in FIGS. 1 and 2.
While the sheet bundle is being taken out of the bin, the sheet is conveyed to the bins B _{21 to} B ₂₆ of the lower bin module, and the bins B ₁₁ to B ₂₆ are conveyed.
After the bundle is taken out from B ₁₆ and after being conveyed to the lower bin module bins B _{21 to} B ₂₆ , the bundle is taken out from the lower bin module at the position shown by the solid line in FIGS. 1 and 2.
By repeating this operation, copying can be continued continuously until the stack unit becomes full.

Next, the folding device 204 will be described with reference to FIG. Here, the folding device 204 can operate according to three modes such as a through-pass mode, a Z-folding mode, and a C-folding mode.

The first through-pass mode is a mode in which the sheet S is allowed to pass through without requiring a folding operation. In this mode, the folding sheet 251 carried by the pair of inlet rollers 227 and 228 operates the inlet deflector 229. Is guided to the paper path 230, and the discharge roller pair 231 and 2
The sheet 32 is sent to the sheet post-processing device 203.

In the second C-folding mode, the LGL folding sheet 251 is folded into two LTRs (vertical size), and the folding sheet guided from the inlet rollers 227 and 228 to the inlet decreter 229 is used. 251 is introduced into the folding path 236 by operating the deflector 234.

Thus, as shown in FIG. 34 (a), when the leading end of the folding sheet 251 abuts on the stopper 243, the loop 250 formed in the central portion on the downstream side of the folding sheet 251 is folded. As shown in FIGS. 34 (b) and 34 (a), a fold 251A is formed at the center of the folding sheet 251 on the downstream side by being held in the nip between the rollers 238 and 239. It becomes a half-folded sheet. Thus, the folded sheet 251 for folding is then passed through the path 240 and delivered by the pair of discharge rollers 231 and 232.

In the third Z-folding mode, the folding sheet 2 is used.
It is a mode in which 51 is once folded in half and then one of them is folded back to the other side.
The sheet 251 for folding is sent to the path 233 by the inlet deflector 229 from 7, 228. Further, this sheet is sent to the path 242 by the deflector 234,
The tip thereof contacts the stopper 245. Thus, as in the two-fold mode, a loop is formed at about 1/4 from the leading edge of the sheet 251, and the loop is held in the nip between the pair of folding rollers 238 and 237 and the fold 251B. Are formed into a half-folded sheet (FIG. 35 (a)).

Next, the folding sheet 251 thus folded is introduced into the folding path 236, and the fold 251B of the folded sheet 251 folded into two is abutted against the stopper 244. A loop is formed in the center of the folded folding sheet 251 in the same manner as described above, and this loop is held in the nip between the pair of folding rollers 238 and 239 to form the second fold 251C.
Are formed (FIG. 35 (b)). As described above, the Z-folded sheet 251 folded back to the front and back passes through the path 240 and is delivered by the pair of paper ejection rollers 231 and 232.

Next, the grip / staple unit 9 will be described (FIGS. 12 and 13). 12 is a top view of the grip / staple unit 9, and FIG. 13 is a front view.

The overall structure is a frame body in which guide stays 52, 53 and a right stay 54 are arranged between the unit front side plate 50 and the unit rear side plate 51, and two frames are arranged on the left and right sides of the frame body for a total of four frames. The raising / lowering roller 55 of the above is caulked. A member 53a that guides the sheet bundle when the sheet bundle is conveyed is attached to the inner side of the lower guide stay 53. The four rollers 55 are guided in two rails 56 fixed to the main body side. The rack integrally cut with the rail 56 and the pinion gears 58 provided at both ends of the frame body laterally penetrating 57 mesh with each other to transmit the driving force from the elevating motor M4 to the gear and the entire frame body is transmitted. It can be moved up and down.

Three moving bodies are arranged in the frame body. The first-out gripper 10 is configured to be movable in the direction of arrow D in FIG. 12, grips the vicinity of the right end of the sheet bundle S on the bin on the front reference side, and pulls out the sheet bundle to the right. The distance l ₄ from the right end of the advance gripper 10 to the leading end of the sheet bundle S is set to be longer than the distance l ₅ from the left end of the stapler 11 to the leading end of the sheet bundle S at the completion of drawing.

The stapler 11 can be moved in the direction of arrow E in the figure, and can be moved to a front or rear retracted position that does not overlap with the sheet width or an arbitrary position of the leading end of the sheet bundle.

The transport gripper 12 is movable in the direction of arrow F in FIG. 12, and is also movable in the direction of arrow G in the figure, including the front and rear side plates 59 and 60 as a whole. The transport gripper 12 grips the approximate center position of the sheet width in the direction of arrow F according to the size of the sheet bundle, and
The sheet bundle is conveyed in the direction (rightward in the drawing), the sheet bundle is completely pulled out from the bin, and is conveyed to the stacker described later.

The movement of the transport gripper 12 in the direction of arrow F is
In addition to moving according to size as described above, it is also used for sorting on the stacker. That is, when the bundle is conveyed to the stacker, the conveyance amount in the arrow G direction depends on the sheet bundle size, but by changing the conveyance amount of the sheet bundle in the F direction, the sheet bundles of the same size are sorted or different. Jobs can be sorted.

The depth dimension l ₆ of the transport gripper 12 is set so that the leading edge of the sheet bundle S can be held even when the stapler 11 is operating with respect to the sheet bundle S.

The moving bodies 10, 11, 12 in the grip / staple unit 9 will be described in detail below.

First, the grip portion for sandwiching the sheet bundle will be described. This is a configuration common to the first-out gripper 10 and the transport gripper 12 (FIG. 14).

The side plates 62, 62 have three shafts 63, 64,
65 is supported. An upper gripper 66 and a lower gripper 67 are arranged on the shaft 65, and a lower gripper cam 68 fixed to the shaft 63 and an upper gripper cam 69 fixed to the shaft 64 are rotated in the arrow direction. Arrow H,
Repeated swinging in the direction of arrow I (solid line and broken line diagram). Also,
The spring member 70 biases the cam portion 67 a of the lower gripper 67 toward the lower gripper cam 68, and the spring member 71 causes the upper gripper 66 to move.
The cam portion 66a is urged against the upper gripper cam 69 so that the contact pressure between the upper gripper and the lower gripper is controlled to be substantially constant. The cams 69 and 68 of the upper / lower grippers are driven by motors M5 (holding the first-out gripper) and M6 (holding the transport gripper) (not shown).

The first-out gripper 10 and the transport gripper 12 have the same basic structure as described above, but the conditions such as the clamping pressure, the width of the gripper, and the maximum opening amount are optimally set in accordance with the respective usage conditions. I don't mind.

For example, in the case of the present embodiment, the first-out gripper holds the width small in terms of space, but clamps only on the reference side. Therefore, the clamping pressure is set to a high value to prevent misalignment of the bundle, and the opening amount is set to the bin. Hold down to get in between. On the other hand, since the transport gripper can clamp the sheet bundle center, the clamping pressure can be set low. Other,
It can be generally set according to the curl amount of the sheet, the basis weight, the presence or absence of folding, the number of sheets, and the like.

Next, the drive configuration of the first-out gripper 10 will be described (FIGS. 15 and 16). FIG. 15 is a top view, FIG.
6 is a front view.

A roller 72 having a groove is crimped on the front side surface of the advance gripper, and the slot 50a is provided in the unit front side plate 50 of the grip / staple unit 9.
Is engaged. The elongated hole 50a is formed substantially horizontally on the right side of FIG. 16 near the stapler 11, but on the left side of FIG. 16 near the bin is an elongated hole having an angle according to the inclination of the bin. . The tip ends of the shafts of the two rollers 72 are connected by a connecting metal plate 73, and the pin member 7 is attached to the metal plate 73.
4 is attached.

On the other hand, on the front side of the unit front side plate 50,
A first-out motor M7 is attached, and a swing arm 76 is fixed to the tip of its drive shaft. Swing arm 7
An elongated hole 76a is formed at the other end of 6, and the tip portion of the pin member 74 is engaged with this elongated hole 76a. By driving the advance motor M7, the swing arm 76 is moved to the position shown in FIG.
5. Reciprocate between the position indicated by the solid line in FIG.
As a result, the advance gripper 10 moves the unit front side plate 50.
The sheet bundle is grasped along the long hole at the inclined position, conveyed to the horizontal position, separated at the horizontal position, and returned to the inclined position again.

Next, the drive configuration of the transport gripper 12 will be described (FIGS. 17 and 18). 17 is a top view and FIG. 18 is a front sectional view.

First, driving in the left-right direction in FIGS. 17 and 18 and in the sheet bundle conveying direction will be described.

The transport gripper 12 has two
It is supported by book shafts 77, 78. One shaft 77 is a ball screw, and the other shaft 78 is a normal shaft. Both ends of the shaft 77 are rotatably supported between the front and rear side plates (the front side plate is omitted; the rear side plate 60), and the shaft 78 is supported.
Both ends of are completely fixed. A guide roller 79 is attached to each side plate, and the roller 79 is a unit side plate 51.
It can move to the left and right along the slotted hole 5la.

The transport gripper left and right moving motor M8 is attached to the unit side plate 51, and the motor pulley 8
Drive is transmitted to the penetrating shaft 83 via 0, the belt 81, and the pulley 82. A driving pulley 84 is attached to each of the front side and the rear side of the penetrating shaft 83, and a belt 806 is wound between the driven pulleys 85 facing each other. A part of the belt 806 is attached to the rear plate 6 by the regulating member 87.
By being fixed on 0, the drive of the motor M8 is transmitted to the transport gripper 12 and can be moved in the left and right directions in FIGS. 12 and 13.

Next, driving in the vertical direction of FIG. 17, that is, in the direction orthogonal to the sheet bundle conveyance will be described.

On the rear side plate 60, a transport gripper forward / backward moving motor M9 is attached via a base 88. Motor M via motor pulley 89, belt 90, and pulley 91
The drive of 9 is transmitted to the ball screw shaft 77. Since a similar screw is also cut on a portion of the transport gripper 12 that is engaged with the ball screw shaft 77, the transport gripper 12 can be moved forward and backward by rotating the ball screw shaft 77.

The position of the transport gripper 12 is determined by detecting its home position and the rotation amount of the motor M8. In the left-right direction, the projection 8 above the regulating member 87
7a is detected by the home position sensor S7, the amount of movement is detected by the sensor S8 that reads the encoder 92 of the motor M8, and stopped at a predetermined position.

On the other hand, when the transport gripper 12 is moved forward and backward, the negative portion of the transport gripper is detected at the home position S9, the movement amount is detected by the sensor SlO which reads the encoder 93 of the motor M9, and the transport gripper 12 is moved at a predetermined position. To stop.

Further, as shown in FIG. 1, a control device (CPU) for controlling the operation of each of the above parts is provided.

Based on the above configuration, the operation of each component will be described below. First, the basic operation of the device will be described.

First, an original is set on the original placing table 105 of the automatic original feeder 202 provided in the copying machine main body 201 (FIG. 1), and a predetermined mode condition is input by an operation unit (not shown) to start. The key is pressed. Each unit of the sheet post-processing device 203 is controlled to be in a standby state in response to the start key pressing signal. Hereinafter, description will be given separately for each mode condition.

(A) Non-sort mode In FIGS. 2 and 26, the deflector 3 is oriented in the direction of the solid line,
The deflector 4 is positioned in the direction of the broken line, and the roller pairs 8a, 8 existing from the first transport path 1 to the carry-out path 6 are present.
The motor M14 is controlled so that b and 8c rotate (FIG. 26). Of course, the roller pair in the upper part of the folding device 204 is also rotated by the folding motor M17 (not shown), and the sheet can be received.

However, the above standby operation may be performed after the copying operation described below and before the sheet is discharged from the copying machine main body 201. When the sheet post-processing apparatus is in the standby state, the original 206 shown in FIG.
7, the copying machine main body 201 enters the copying operation.

The first sheet that has undergone image formation processing in the copying machine main body 201 and is discharged passes through the upper path of the folding device 204 and enters the stapling / stacking device 205 from the carry-in port 215. The sheet is deflected vertically upward by the deflector 3, is conveyed vertically upward on the right side of the deflector 4, and is ejected onto the non-sort tray 5 by the ejection roller pair 8c.

(B) In case of sort mode Although special control may be performed depending on the sheet condition and the mode setting condition, the operation in the general sort mode will be described.

First, as a standby operation, the deflector 3 is positioned in the direction of the solid line and the deflector 4 is positioned in the direction of the solid line, and the rollers and 8 of the upper path of the folding device 204 are arranged.
The roller pairs a, 8b, and 8d to 8g rotate. The upper and lower bin modules B ₁ and B ₂ are shifted so that the uppermost bins B ₁₁ and B ₂₁ are located at positions facing the discharge roller pairs 8g and 8p. The alignment wall 15 of the bin module stands by at the home position corresponding to the width of the sheet.

Since the guide member for origami is not operated, it is checked that it is in the retracted position where it does not project to the bin side. Further, regarding the drive of the bin standing portion, the control device 270 checks that it is in the inoperative position.

The grip / staple unit 9 is located at a position corresponding to the sheet bundle removal of the upper bin module (see FIG. 2).
Move to the position (broken line) and wait.

The movable body in the grip / staple unit 9 will be described with reference to FIG. The first-out gripper 10 stands by at the position shown in FIG. 12 so as not to obstruct the sheet on the bin when the bin is moved up and down in the bin module located on the left side of the grip / staple unit 9.

Since the stapler 11 is not operated, as shown in FIG.
In FIG. 2, it moves to the front retracted position indicated by the broken line. As shown by the broken line in FIG. 12, the transport gripper 12 grips the approximate center of the conveyed sheet bundle in the arrow F direction, and in the arrow G direction.
The leading edge of the sheet bundle advanced by the advance gripper 10 waits at the grippable position 12a.

Both the first-out gripper 10 and the transport gripper 12 stand by at the respective positions with the upper and lower grippers open.

Next, the stack unit 13 moves to the position shown by the broken line in FIG. 2 so that the stack of sheets conveyed by the grip / staple unit 9 can be received. In FIG. 23, the stack tray 116 inside the stack unit 13, the reference wall 117, and the pressing member 118 are positioned so that the upper surface of the stack tray 116 can receive the sheet bundle, and other positions corresponding to the stack tray 116. Move to. As shown in FIG. 23, the tip of the pressing member 118 is in a state of protruding toward the stack tray 116 side.

As described above, the sheet post-processing apparatus is placed in the standby state, the original is fed, the image is formed, and the sheet is fed, as in the non-sort mode. In FIG. 2, the first sheet passes through the upper path of the folding device, enters from the carry-in port 215, is conveyed by the deflector 3 above the vertical 1, and is further conveyed by the deflector 4 to the left side.
Then, it is discharged onto the bottle Bll.

[0065] detects that the sheet of the first sheet to the bin Bll in discharge sensor Sl8 is discharged, the bottle is shifted to one bin upwards, the bin B ₁₂ rises in sea Bok stowed position.
When the sheets having the same image are discharged to all the bins of the upper bin module by repeating the above operation, the original is replaced and the image is formed on the second original. In the bins of the upper bin module, the lowermost bin (B _{16 in} FIG. 2) is at the sheet accommodation position, and the second sheet is accommodated in order from the lowermost bin. The above operation is repeated for all originals, and the operation for accommodating the sheets in the bin is completed. In this end state, if the number of originals is odd, the lowermost bin B ₁₆ is at the sheet storage position, and if the number of originals is even, the uppermost bin B ₁₁ is at the sheet storage position.

Next, the operation of taking out the sheet bundle from the bin is started. In the present embodiment, in the upper bin module, the taking-out position of the sheet bundle, that is, the gripper /
The stapling unit 9 is on standby at a position that is two bins below the sheet storage position. Therefore, the control of the stack take-out order changes depending on whether the number of originals is odd or even.

(B)-(i) When the number of originals is an even number If the number of originals is an even number, the bin position after the sorting is the same as at the start, and the state is as shown in FIG. In this case, do not take out from the bin B _{13 at} the bundle take-out position,
First, lowering by 2 bins to the state of FIG. 28, the uppermost bin B ₁₁
The bundle is taken out in order from B ₁₆ to B ₁₆ (FIG. 29).

Next, the upper bin module B ₁ is raised by 2 bins to the state shown in FIG. 30, and the preparation for receiving the next sheet bundle is completed. Even in the next opportunity for the upper bin module to receive the sheet in the continuous job, since the number of originals is even, if the sorting is started in the state of FIG. 30, the sorting is finished in the state of FIG. In this case, since there is no bin corresponding to the bundle take-out position, the upper bin module B
And ₁ to state 2 bottle content lowered 29, the lowermost bin B ₁₆
Bundles are taken out from 6 to B ₁₁ . At this time, FIG.
Since it is in the state of 8, the state is raised by 2 bins and returns to the state of FIG. Therefore, when the upper bin module repeats a plurality of times to receive the sheet bundle, the state change described above is repeated.

(B)-(ii) When the number of originals is odd When the number of originals is odd, the bin position after sorting is completely opposite to that at the start. That is, if the sorting is started from the state of FIG. 27, the state is that of FIG. 30 at the end. This time, B from the lowest bin B ₁₆ in the state of FIG. 29 2 Lower bottle content since there is a bin corresponding to the beam extraction in order
_Take out the bundle up to ₁₁ . At this time, since the state shown in FIG. 28 is reached, the bin is raised by 2 bins and the preparation for receiving the next sheet bundle is completed in the state shown in FIG. If the same job, the number of originals is an odd number at the next sheet receiving opportunity, so if sorting is started in FIG. 27, it ends in FIG. Therefore, also in this case, the state change shown above is repeated.

In the case of the lower bin module, in the present embodiment, the relationship between the sheet receiving position of the bin and the bundle take-out position is opposite, and the bundle take-out position is located two bins above. Although the bin control in the lower bin module will not be described in detail here, it is controlled by repeatedly changing the state in the same manner as in the case of the upper bin module described above. The subsequent operation of the sort mode will be described below.

The sheets stacked on the bin are aligned with the reference rods 14a and 14b shown in FIG. 3 by operating the alignment wall 15 in the direction orthogonal to the sheet conveyance. When the sorting and the alignment are completed, the first-out gripper 10 that holds the sheet bundle S on the bin moves from the solid line position to the broken line position while holding the first-out gripper 10 in FIG. 13, and then holds the sheet bundle S. Bottle standing part B shown in FIG.
The sheet bundle in which j is released by the solenoid SLl and the sheet bundle can be conveyed is the reference rod 14 in FIG.
1 a and 14 b, and the alignment rod 15 on the back side,
Both sides are regulated by the two guide members 53a, and the lower side is guided by the bin surface and the tilted bin standing surface, the guide stay 53, and the upper direction by the guide stay 52, and is conveyed rightward in the drawing. . Then, it stops at the position indicated by the solid line in FIG. 13, where the advance gripper 10 and the transport gripper 1
The bundle between the two is delivered.

First, the transport gripper 12, which is open and waits at the position indicated by the broken line in FIG. 12, holds the substantially central portion of the sheet bundle. Next, the first-out gripper 10 releases the clamp and prepares for the next conveyance. The transport gripper 12 is driven in the right direction of the arrow G in FIG. 12 to transport the sheet bundle in the right direction, and stops at an appropriate position according to the size. In this state, as shown in FIG. 34, the rear end of the sheet bundle S is dropped on the upper surface of the stack tray 116, the left side is regulated by the stacker reference wall 117, and the upper surface of the bundle is driven by the solenoid. It is pressed by the pressing member 118. From this state, the transport gripper 12 is opened and the leading end of the sheet bundle is also dropped onto the stack tray.

At this time, the pressing member 118 has a function of preventing a shift in the falling bundle.

Next, when the second bundle of sheets is conveyed, the conveyance gripper 12 grasps the substantially central portion of the sheet bundle,
The operation up to the point where the bundle is transferred between the grippers is the same as that of the first bundle, so only the subsequent operation will be described.

After delivering the bundle, the transport gripper 12 moves by a predetermined amount in the direction of arrow F in FIG. At this time, the reference rod, the alignment wall, and the guide member 53a may escape so that the trailing edge of the sheet bundle is not regulated. Further, after the trailing edge of the sheet bundle is completely removed from these width regulating members, The transport gripper 12 may be moved in the arrow F direction. By this movement, when stacking the sheet bundle on the stack tray 116, it is possible to identify the sheet bundle from the first sheet bundle.
While the sheet is conveyed rightward by the conveying gripper 12, as shown in FIG. 35, before the rear end of the sheet bundle S reaches a predetermined position, the central portion of the sheets first falls onto the upper surface of the sheet bundle on the stack tray 116. If the sheet bundle S ₂ being conveyed is conveyed, the sheet bundle S ₂ being conveyed is already loaded.
May disturb the alignment of ₁ . At this time, as shown in FIG. 35, by pressing the upper surface of the already stacked sheet bundle S ₁ with the pressing member 118, the deviation of the already stacked sheet bundle S ₁ can be prevented.

With regard to the sheet bundle stacked on the stack tray 116, the uppermost surface thereof is always detected by the sensor,
The stack tray 1116 is gradually lowered and controlled so that the distance between the upper grip / stapling unit 9 and the uppermost stacking surface is always constant.

Regarding the sheet bundle on the stack tray 116, the sheet bundle can be arbitrarily taken out when the stack unit 13 is not in operation. When the operator presses a take-out button (not shown), the stack unit 13 moves to the take-out position, and only the stack take-out cover can be opened and closed.

Further, after taking out the sheet bundle, the processing can be continued by closing the cover.

(C) Staple Sort Mode Since the conveyance of the sheet and the sheet bundle is the same as in the sort mode described above, the description thereof will be omitted. Here, the movement control of the stapler will be described.

As shown in FIGS. 12 and 22, the stapler 11 can be stopped at an arbitrary position between the front retracted position 1la and the rear retracted position 1lb.

(C)-(i) Single front binding mode In the non-stapling mode, the stapler 11 was at the front retracted position 1la, but if the front single binding mode was selected, the stapler 11 11 is shown in FIGS.
It waits at the position of 1 lc shown in 2. As shown in FIG. 12, even when the stapler is at the position of 1 lc, the transport grippers 12 can stand by at the position of 12 a without interfering with each other. After the stapler 11 performs the stapling operation on the sheet bundle conveyed by the first-out gripper 10,
The sheet bundle is moved to the retracted position 1la on the front side, and then the sheet bundle is conveyed to the right by the conveyance gripper 12. When the trailing edge of the sheet bundle comes out of the moving area of the staple 11, the stapler 11 moves again to the single binding position 1lc,
Wait for the next stack of sheets.

(C)-(ii) In the case of binding at two places The binding positions at two positions are various depending on the size in the width direction of the sheet bundle, but there are two positions of stapler positions 1ld and 1le shown in FIGS. It is assumed that there is a size in which is the binding position. Also in this case, as shown in FIG. 12, even if the stapler is located at either 1ld or 1le, it does not interfere with the position of the transport gripper 12a. At the time of standby for binding at two places, the stapler moves from the retracted position 1la on the front side to the driving position 1ld on the front side of the two places and waits.
At this time, the transport gripper 12 stands by at the position of the solid line 12b.

When the sheet bundle is conveyed by the first-out gripper 10, the first-out gripper 10 staples one sheet on the front side at the position 1ld while holding the sheet bundle. Next, the stapler 11 moves to the position of 1 le and staples the two positions on the back side. When the stapler 11 moves from the position 1ld to the position 1le, the transport gripper 12 immediately enters the holding position 12a from the standby position 12b. Then, the transport gripper 12 holds the sheet bundle, while the first-out gripper 10
Releases the sheet bundle. The stapler performs the second stapling operation at the position of 1le and then moves to the retracted position 1lb on the back side.

When the trailing end of the first bundle of sheets passes through the stapler moving region, the stapler 11 moves from the retracted position 1lb to the staple position 1le on the inner side and receives the second bundle of sheets. This time, after hitting the back side of the two places first, it moves to the position ld in front. The transport gripper 12
Like the first bundle, hit the first place and staple the second place.
It waits at the position 12b until 1 is moved, then moves to 12a, waits for the retracting operation of the stapler 111 to the near side, and the bundle of sheets is conveyed. As mentioned above, 2
At the time of stapling, the processing time is shortened by alternating the retracted position of the stapler between the front side and the back side.

(C)-(iii) In the case of binding in one place in the back In this case, binding is performed only in the back side of the paper size center. Therefore, the stapler is placed in the back side in the reverse order of (C)-(i) described above. The retreat position 11b and the binding position are reciprocated.

(D) Folding Mode In the folding mode as well, a sheet that is relatively long in the transport direction is subjected to a folding operation inside the folding device 204 shown in FIG. The sheet is discharged to the upper side, selectively post-processed, and stacked on the stack unit 13.

The schematic construction has been shown above, but the detailed construction of the other parts will be described below for reference.

First, the bin modules B ₁ and B ₂ will be described.

FIG. 3 is a perspective view of the bin module.
Hereinafter will be described bin module B _1, but the same configuration applies to B _2. The 4-bin module B ₁ mainly includes bins B _{11 to} B _1n, two reference rods 14a and 14b, an alignment wall 15, and lead cams 16a to 16c for moving the bin up and down.
Also, it is composed of these drive units. Standard rod 14
Reference characters a and 14b are members that determine a reference line for post-processing such as stapling with respect to the sheet discharged onto the bin, and are usually set slightly retracted from the end position at the time of sheet discharging. ing. The aligning wall 15 widths the sheets discharged onto the bin one by one or a plurality of sheets in the direction perpendicular to the sheet conveying direction (the direction of arrow A in the drawing), and the opposite ends are set to the reference rods 14a and 14b. Point and align.

FIG. 4 is a top view of the bin module. The lead cams 16a, 16b and 16c are shown in FIGS.
As shown in FIG. 1, one bottle is arranged on the front side of the bottle and two bottles are arranged on the rear side thereof, and a spiral lead cam is provided on the outer circumference. Rollers Ba, Bb, Bc protruding from the bin are engaged with the lead cam, and the bin is raised and lowered by a predetermined pitch each time each lead cam makes one rotation in synchronization.

As shown in FIG. 4, the bin is provided with a notch Bd corresponding to the reference rod and a hole Be corresponding to the matching wall, as well as a notch Bf for a gripper, which will be described later, and a bin standing. Notch Bg for drive mechanism and notch B required for operation
h is formed.

FIG. 5 is a front view of the bin module.
As shown in FIG. 5, the bins are arranged parallel to each other at a certain angle with respect to the horizontal. On the other hand, Binkoro part B
All of a, Bb, and Bc are configured to have the same height when the bottle is inclined. That is, the position of the bin roller Bb near the right side of the bin is near the reference surface of the bin, while the position of the bin roller Bc near the left side of the bin is
Well below the reference plane of the bin, the bin roller Bc is connected to the bin by a V-shaped fixed arm.

As a result, even when adjacent bins such as B ₁₅ and B ₁₆ shown in FIG. 5 approach each other, the interference of the arm portions can be avoided. Further, since the bin roller portions Ba, Bb, Bc are all at the same height, the positions of the lead cams 16a to 16c in the height direction can be set at the same height, and the overall size can be reduced. That is, compared to the case where rollers Ba, Bb, and Bc are provided near the thick portion of each bottle as shown in FIG. 5 (b),
The size l ₁₆ minutes shown in Fig. 5 (b) can be configured to reduce the overall size of the device.

Next, the bin interval will be described with reference to FIG. FIG. 5 shows the upper bin module B _{1. In} the figure, the second bin B ₁₂ from the top is located at a position corresponding to the pair of ejection rollers 8 g and receives the sheet to be ejected. On the other hand, the fourth bin B ₁₄ from the top is at the bundle discharge position, and when the sheet discharge to the bin is completed, the bins are sequentially shifted to this position and the bundle discharge is performed from each bin. In Figure 5, the bin B ₁₁ ~
Until B ₁₅ is as large as bin spacing l _17, but smaller and l ₁₈ only during the B _15, B _16, between bins varies depending on the situation. Figure 6
Is in a state where the bin B ₁₆ is at the sheet receiving position and the bin is shifted to the uppermost position. At this time, the bin intervals are B _{11 to} B ₁₅
It is small with l ₁₈ up to and is large with l ₁₇ only between B ₁₅ and B ₁₆ .

Further, in FIG. 7, the bin B ₁₁ is in the bundle discharging position, and the bin is shifted to the bottom. At this time, the bin interval is large at l ₁₇ only between B ₁₁ and B ₁₂ , and l _{18 at} other positions. And small. That is, the interval between the bottles in the sheet receiving position and the bottle thereon is greater about l _17, also above and below the bin and the bin in the bundle discharging position should have as large as l ₁₇ intervals. In FIG. 5, B ₁₁ and B ₁₂ , B ₁₃ and B
₁₄ , B ₁₄ and B ₁₅ . In FIG. 5, the distance between B ₁₂ and B ₁₃ is also large, but this may be as small as about ₁₈ functionally,
The size of the interval is determined by the relationship between the upper half space of the stapler 11 and the bin interval.

On the other hand, in the case of the lower bin module, as can be seen from FIGS. 1 and 2, the sheet receiving position and the bundle discharging position are upside down from those in the upper bin module.
Therefore, in the same way, in FIG. 2, the distance between the bin B _{24 at the} sheet receiving position and the upper bin B ₂₃ is l.
Greater to about _17, although the interval between the bin B ₂₂ in the bundle discharging position and the upper and lower bin B _21, B ₂₃ needs large as l _17, between B ₂₄ and B ₂₅ are not large enough l ₁₇ May be.

However, by increasing the distance between B ₂₄ and B ₂₅ to about l ₁₇ , the sheet receiving position and the bundle discharging position are reversed, and the upper and lower module bins have the same interval configuration. That is, the pitch of the lead cams that determine the bin interval may be the same, and there is an advantage that the upper and lower lead cams are commonly used. In addition, the fact that the sheet receiving position and the bundle discharging position are reversed in the upper and lower bin modules has another advantage that the grid / stapler unit 9 and the stack unit 13 can be shared when taking out the sheet.

Next, driving of the bin shift will be described (FIGS. 4 and 5).

The bin shift motor M1 is a motor pulley 1
8 and the belt 19 and the lead cam pulleys 20a to 20c synchronously transmit the drive to the lead cams 16a to 16c, rotate the motor forward and backward, and rotate the lead cam once, thereby raising and lowering the bin by the cam pitch. Each of the lead cams 16a to 16c has a shaft rotatably supported by a bearing, and the drive is transmitted from a pulley 20 attached to one side thereof. Bin shift motor 17
Has an encoder 21 on the side opposite to the pulley 18, and the sensor S1 detects one rotation.

Further, the bin modules B ₁ and B ₂ are
There is a home position detection sensor S2 (not shown) for the bins, which detects that the respective top bins B ₁₁ and B ₂₁ are in their respective sheet receiving positions. Each of the bin modules B ₁ and B ₂ has a penetration sensor S3 (FIG. 2) for detecting the sheet on the bin, and detects the presence or absence of the sheet on the bin to determine the timing for switching the modules. ing.

Next, the alignment wall 1 for aligning the sheets on the bin
The drive configuration of No. 5 will be described (FIGS. 8 and 9). FIG.
[FIG. 9] is a top view of the matching wall drive unit, and FIG. 9 is a front view.

A shaft 22 is caulked on the matching wall 15, and the caulking shaft 22 is stopped by penetrating a U-shaped support plate 23. On the other hand, the U-shaped support plate 23
A compression spring 24 is installed in the inside of the plate while being slightly biased in the compression direction. One side of the compression spring 24 is abutted against the inner wall of the plate 23 and the other side is abutted against a stopper 25 provided on the caulking shaft. The caulking shaft 22 and the matching wall 15 are urged downward in FIG. 8 by the force of the compression spring.

The lower side of the U-shaped support plate 23 is fixed to the moving side of the accuride 27 via the slide plate 26, and the fixed side of the accuride 27 is an accuride rail plate 28 extending in the sliding direction of the alignment wall. It is fixed to. On the accurride rail plate 28, caulking shafts 29 and 30 stand on the front side and the back side, and the pulley gear 3 is attached to each of them.
1. A pulley 32 is rotatably attached. A timing belt 33 is passed between the pulleys 31 and 32,
The slide plate 26 is fixed to the belt 33. on the other hand,
The motor gear 34 of the matching wall drive motor M2 is the pulley gear 3
The driving force is transmitted by engaging with the first gear portion.

The home position of the matching wall 15 is
It is detected by the sensor S4. U-shaped support plate 23
A slide member 35 is attached to the upper part of the above and is guided by engaging with a concave portion of a fixed rail 36. In FIG. 9, the drive is entered from below the alignment wall 15 and the upper part is guided by the rail, but it may be configured upside down.
Further, the configuration of the matching wall and the way of driving may be reversed between the upper bin module and the lower bin module.

Next, the drive configuration of the bin standing portion forming the alignment surface in the transport direction on the bin will be described (FIGS. 10 and 11).

This is to move the bin standing when the sheet bundle stacked on the bin is conveyed from the bin in the bin standing direction for post-processing and stacking. FIG.
0 is a top view and FIG. 11 is a front view.

The bin B includes a sheet stacking section Bi and a matching section B.
The rotating shaft on the aligning portion Bj side is fitted into the rotating hole on the stacking portion Bi side to form the aligning portion B.
j is rotatable. The rotation angle of the matching portion Bj is
As shown in FIG. 11, the aligning surface, which stands at a right angle with respect to the fixed loading surface, can be rotated at approximately 90 ° until it becomes substantially flush with the loading surface. Normally, a spring or the like is urged so that the alignment surface is perpendicular to the loading surface (solid line in FIG. 11). This spring has a strength such that the aligning portion Bj does not fall down even with the weight of the sheet bundle on the bin. A drive arm 45 is attached to the back side of the matching portion Bj. A pin 45 is attached to the tip of the drive arm.
a is set up.

The bin stand-up drive solenoid SL1 has a base 4
6 is supported on. A link 47 is rotatably supported on the base 46, and one end of an arm 48 is engaged with a pin 47a on the link. The other end of the arm 48 is attached to the solenoid SL1 and the solenoid 47 operates to move the link 47 from the solid line portion to the two-dot chain line portion. A pin contact member 47b is attached to the tip of the link 47, but in a normal state, the pin 47b and the pin 45a are separated from each other, and do not interfere with the lifting operation of the bin B. When sheets are discharged onto the bin and the sheet bundle in the bin is post-processed and stacked, the corresponding bin is
Shifting to the 1 position, the solenoid SLl is operated. The pin abutting member 47b abuts the pin 45a, and the link 47 is further rotated to move the aligning portion Bj to the position indicated by the chain double-dashed line in FIG. Solenoid SLl is O
When FF is performed, the link 47 returns to the original solid line position by the action of the spring 49, and correspondingly, the aligning portion Bj also returns to the position orthogonal to the loading surface.

Next, the forward / backward drive of the stapler 11 will be described (FIGS. 19 and 20). FIG. 19 is a left view of the stapler driving unit, and FIG. 20 is a top view.

In FIG. 19, the stapler 11 is a base 9
It is fixed on 4. A slider 95 is attached above the base 94. 2 for slider 95
Bearings for passing the shafts of the book are provided at four places. By fixing the two shafts of the shafts 96 and 97 between the front and rear side plates 50 and 51 of the unit, the stapler 11 is suspended and supported by the two shafts. Has been done. A motor base 98 is attached to the unit rear side plate 51 side, and a stapler forward / backward motor M10 is fixed. Motor gear 99, motor pulley 100,
The driven pulley 101 and the belt 10 passed between the pulleys.
2, the drive of the motor M10 is transmitted, and this drive is transmitted to the unit of the stapler 11 via the slider 95 to which the belt 102 is fixed by the regulating member 103. This allows the staple unit to move in the direction of arrow J in FIG. The stapler 11 can be stopped at any position between the retracted position 1la on the front side and the retracted position 1lb on the back side. The position of the stapler 11 is set by the front position sensor Sll or the back position sensor Sl2.
It is determined by reading the encoder 104 of the motor M10 with the sensor S13 from the detection by.

Next, the structure of the stack unit 13 will be described (FIGS. 21, 23 and 24). 21 is a top view of the stack unit 13, FIG. 23 is a front view of the stack frame portion, and FIG. 24 is a left view.

First, in FIG. 21, the stack frame 105, which is the outer frame of the stack unit 13, is composed of four parts, namely a rear side plate 105a, then a left side plate 105b, a right side plate 105c, and a bottom plate 105d. Two elevating rollers 106 are attached to each of the outer surfaces of the left and right side plates 105b and 105c of the outer frame 105, a total of four, which are guided by rails 107 fixed to the main body. The rail 107 may be the same member as the rail 56 of the grip / staple unit 9 shown in FIG.

21 and 24, the left and right side plates 105
A chain 109 is fixed to a bent portion on the inner side of b and 105c by a fixing plate, and the left and right chains 109 are passed between upper and lower sprockets 110 and 111, respectively. The lower sprocket is connected by a penetrating shaft 112, and the drive of a stack frame lifting motor Mll fixed to the main body is transmitted to the penetrating shaft 112 by gears 113 and 114 to lift and lower the stack frame 105.

Normally, the stopping position of the frame 105 is set to 2 in the grip / stapling unit 9 shown in FIG.
In addition to two stop positions corresponding to one stop position (upper dashed line part and lower solid line part), a plurality of positions are set, such as a stacker tray pull-out position and a stacker limit number of sheets change described later. Normally, the home position of the stack frame 105 is a position corresponding to the upper bin module. Returning to FIG. 21, the encoder 11 of the motor Mll
By reading 5 with the sensor Sl4, it is possible to stop at the various set positions described above.

On the left side plate 105b of the stacker frame,
A stacker reference wall 117, which serves as a reference wall for the sheet bundle on the stack tray 116, is supported so as to be able to move up and down, and a pressing member 118 that presses the sheet bundle on the stack tray 116 from above is also supported.

The stacker reference wall 117 is normally located at the lower side, and moves upward to correspond to the change of the stacker limit number which will be described later.

As shown in FIG. 21, the stacker reference wall 105 is lifted up and down by a total of four on the reference wall side and two on the back side.
A roller 119 is provided on the left side plate 105 of the stacker frame.
It is guided by rails 120 and 121 fixed to b and can move up and down, and is driven by a lifting motor M12 not shown. Further, as shown in FIGS. 21 and 23, a guide roller 117a is rotatably supported on the reference wall 117, and the rear end of the sheet bundle has an upper inclined surface 11 of the reference wall 117.
It does not remain in 7b.

Further, a proximity prevention sensor Sl6 is attached to the upper end of the reference wall, detects the distance between the stack unit 13 and the upper gripper / stapling unit 9, and when the distance is less than a certain distance, , To prevent interference by controlling the driving in the direction of approaching each other. A stack height detection sensor Sl7 is attached to the side surface of the reference wall, and the stack top sheet is detected by Sl7,
The height of the stack tray 116 is controlled.

Next, the pressing member 118 will be described with reference to FIG.

The pressing member 118 is the stack tray 116.
By pressing the upper sheet bundle S, in addition to the function of preventing the disturbance of the already stacked sheets due to the bundle to be stacked next on the stack tray, the stack to be stacked next on the stack tray is dropped and stacked. It has two functions of preventing misalignment within the bundle.

Next, the stack tray 116 will be described (FIGS. 21 and 22). FIG. 22 is a front view of the stack tray portion.

The stack tray 116 is gradually lowered inside the above-mentioned stack frame 105 so that the upper surface of the stack is always maintained.

In FIGS. 21 and 22, 128 is a rail fixed to both side plates of the stack frame 105.
The stack tray 116 is configured so that it can be pulled out from the stack tray base 129 by means of the accurride 130. U-shaped roller receiving plates 131 are attached to both end surfaces of the stack tray base 129, and two rollers 132 are respectively crimped and guided by rails 128. A rack is formed at one end of the rail 128 in the vertical direction, and a shaft 1 that penetrates the base 129 in the lateral direction is formed.
It is meshed with pinion gears 134 attached to both ends of 33. The stack tray lifting motor M13 is attached to the stack tray base 129 by the motor base 135, and the drive is input to the penetrating shaft 133 by the gears 136 and 137. An encoder 138 is attached to the other end of the motor M13 and is read by the sensor S15 to control the descending amount of the stack tray.

Next, the drive configuration of the transport system will be described (FIG. 26). FIG. 26 is a schematic diagram of the drive configuration, in which the hatched side of each roller pair is the drive input shaft, and the other side is the driven side. The drive system is roughly divided into three systems.

First, the transport motor M14 takes the drive on the side closer to the copying machine main body and transmits it to the vertical bin module and the non-sort path after branching to the upper and lower bin modules. Corresponding roller pairs are 7 pairs of 8a to 8c and 8h to 8k.

Next, the carry motor M15 takes charge of the horizontal path of the upper bin module path and supplies the drive to the four roller pairs 8d to 8g.

Next, the control of the apparatus when taking out the sheet bundle in the stack unit 13 while the sheet post-processing apparatus 203 is in operation will be described with reference to FIGS. 2, 36 and 37.

In FIG. 2, a grip / stapling unit 9 as a bundle processing unit is lowered to correspond to the lower bin module B ₂ on which the sheet bundle is stacked and aligned, and the stacked sheet bundle is The sheets are stacked on the stack tray 116 in the stack unit 13 by pulling out by the first-out gripper 10 in the grip / staple unit 9, selective binding processing by the stapler 11, and conveyance by the conveyance gripper 12.

FIG. 36 shows an outline of the apparatus main body of the sheet post-processing apparatus 203. In this apparatus main body, an upper cover 306 for covering the upper part of the stapling / stacking apparatus 205 of the apparatus main body and a front part for covering the front portion are shown. A cover 301, a bin cover 307 that covers the sheet sorting devices B ₁ and B _2, and a take-out cover 303 provided on the front cover 301 are provided so as to be openable and closable.

FIG. 37 is a block diagram showing the opening / closing operation of each cover and the control of each drive means of the sheet post-processing device 203.

When the front cover 301 is opened / closed, the front cover switch 301a operates (for example, OFF operation). When the takeout cover 303 is opened / closed, the takeout cover switch 303a is opened and when the upper cover 306 is opened / closed, the upper cover switch 306a is opened. When the bin cover 307 is opened / closed, the bin cover switch 307a is operated Q. Each of these switches is connected to the control device 270 via the interface 311.

Further, the following driving means is connected to the control device 270 via the interface 312.

That is, the transport motor (M14, M15, M1) of the transport means for transporting the sheet output to the sheet post-processing device 203 to the upper and lower bin modules B ₁ B _2.
6), a bundle processing elevating motor M4 for elevating the grip / staple unit (bundle processing unit) 9, motors in the bundle processing unit (M7, M8, M9, M10, etc.), and a stack unit elevating unit for elevating the stack unit 13 The motor M11 and the motor in the stack unit (M13,
M14) ,. Bin module bin B _1, B ₂ of the bin shift motor M1 to shift the bin, the bin module bin B _1, aligning wall to align the sheet stacked on the B ₂ 1
Matching motors M2 and the like for driving 5 are respectively connected.

The motor M7 in the bundle processing unit is a motor for driving the first-out gripper 10 in a direction orthogonal to the sheet bundle direction, M8 is a motor for driving the sheet bundle direction, and M9 is a direction for orthogonally conveying the transport gripper 12 in the sheet bundle direction. To M10
Indicates motors that are driven in the sheet bundle direction. Further, M13 of the motor in the stack unit is a motor for moving the stack tray 116 up and down, and M12 is a reference wall 117 for regulating the sheet bundle on the stack tray 116.
The motors for raising and lowering (FIG. 23) are shown.

Here, the transport motors (M14, M1)
5, M16), the bin shift motor M1, and the alignment motor M2 as the first driving means, and the bundle processing lifting motor M4 and the bundle processing unit motors (M7, M8, M).
9, M10, etc.) and stack unit lifting motor M11
And a motor (M13, M14) in the stack unit,
Is the characteristic of the second driving means.

When a user takes out the sheet bundle stored in the stack unit 13, the stack unit 13 is operated by operating an operation button (not shown).
Is stopped at a take-out position (FIG. 36) intermediate between the upper and lower stop positions. Next, as shown in FIG. 36, the stack tray 116 is pulled out through the slide rail 130 with the take-out cover 303 opened in the direction of the arrow 302. Then, the sheet bundle on the stack tray 116 is selectively taken out by the user.

When the take-out cover 303 is opened as described above to take out the sheet bundle, the take-out cover switch 303a is turned off by this opening operation.
By the OFF operation of the take-out cover switch 303a, the operation of the first drive means is continued as it is, but the operation of the second drive means is interrupted.

That is, by opening the take-out cover 303, the lifting and lowering operations of the bundle processing unit 9 and the stack unit 13, the first feeding of the sheet bundle by the first feeding gripper 10 in the bundle processing unit 9, the binding processing by the stapler 11, the sheets by the transport gripper 12 are performed. The stack tray 1 at the stop position in the stack transfer operation and the stack unit 13
The lifting and lowering operations of 16, the lifting and lowering operations of the wall 117, and the like are stopped so that there is no hindrance in taking out the sheet bundle.

On the other hand, regardless of whether the take-out cover 303 is opened, the first driving means continues to drive the sheets, so that the sheets are conveyed to the bin module bins B ₁ / B ₂ as the stacking means and the bin module bin B ₁ The shift operation for shifting a plurality of / B ₂ bin trays, the aligning operation for aligning the stacked sheets to the reference position, and the like are continuously performed.

As described above, by opening the take-out cover 303, the driving operation of the second driving means is stopped and the driving operation of the first driving means is continued, so that the stack of sheet stacks is formed. Although the related operations of the bundle processing unit and the stack unit are stopped, the sorting operation of the sheet sorting apparatus, which is not directly related to the stacking of sheet bundles, is continuously performed, so that the operation efficiency of the sheet sorting apparatus is maintained. You can Further, the sheet sorting apparatus continues the sorting operation, so that the image forming apparatus main body 201 (FIG. 1) as an output device that outputs the sheets to the sheet post-processing apparatus is not affected by the sheet bundle removal. It is possible to continuously operate and output the image-formed sheet to the sheet post-processing device.

After the stack of sheets is taken out, the stack tray 116 is returned to the original position, and the take-out cover 303 is closed. Then, the take-out cover switch 303a is closed, and the bundle processing unit 9 binds the sheet bundle, transfers it, and so on. ,
The stacking of the sheet bundle by the stack unit 13 is resumed.

When the front cover 301, the upper cover 306, the bin cover 307, etc. other than the take-out cover 303 used for taking out the sheet bundle are opened during the operation of the apparatus, the first drive means and All the driving means of the second driving means are stopped, and the operation of the entire sheet post-processing apparatus is stopped.

[0143]

As described above, according to the present invention,
Sheet bundles loaded and stored in the stack unit
When the take-out cover is opened for taking out by the user, the bundle processing unit relating to the stack of sheet bundles and the associated driving means of the stack unit are stopped respectively, and the operation of the sheet sorting apparatus for sorting sheets is continued. Since it was done, by taking out the sheet bundle,
It is possible to prevent the operation of the sheet sorting apparatus from being lowered, and maintain the operating efficiency of the sheet sorting apparatus.

Further, since the sheet sorting apparatus continues to operate, it is not necessary to stop the operation of the image forming apparatus main body for outputting the sheet to the sheet post-processing apparatus. It is possible to prevent a decrease in operating efficiency of the forming apparatus.

[Brief description of drawings]

FIG. 1 is a vertical sectional front view of a sheet post-processing apparatus of the present invention and an image forming apparatus main body to which the sheet post-processing apparatus is connected.

FIG. 2 is a vertical sectional front view of the sheet post-processing apparatus.

FIG. 3 is a perspective view of the bin module.

FIG. 4 is a plan view of the bin module.

FIG. 5 is a side view of the bin module.

FIG. 6 is an operation diagram of the same bottle.

FIG. 7 is an operation diagram of the same bottle.

FIG. 8 is a plan view of the matching wall driving unit.

FIG. 9 is a side view of the matching wall driving unit.

FIG. 10 is a plan view of the bin standing portion drive unit.

FIG. 11 is a side view of the bin standing portion drive unit.

FIG. 12 is a plan view of the grip / staple unit.

FIG. 13 is a side view of the grip / staple unit.

FIG. 14 is a side view of the gripper portion.

FIG. 15 is a plan view of the first-out gripper driving unit.

FIG. 16 is a side view of the first-out gripper driving unit.

FIG. 17 is a plan view of the transport gripper driving unit.

FIG. 18 is a side view of the transport gripper driving unit.

FIG. 19 is a left side view of the staple unit driving portion in FIG.

FIG. 20 is a plan view of the staple unit driving portion.

FIG. 21 is a plan view of the stack unit.

FIG. 22 is a front view of a stack tray of the same.

FIG. 23 is a front view of the stack unit.

FIG. 24 is a left side view of the drive unit of the stack unit in FIG.

FIG. 25 is a front view of the stack pressing member.

FIG. 26 is a schematic diagram of a drive system of the transport system.

FIG. 27 is a side view showing the operation of the bottle in the same manner.

FIG. 28 is a side view showing the same operation of the bottle.

FIG. 29 is a side view showing the same operation of the bottle.

FIG. 30 is a side view showing the same operation of the bottle.

FIG. 31 is an operation diagram which similarly shows the effect of the stack pressing member.

FIG. 32 is an operation diagram which similarly shows the effect of the stack pressing member.

FIG. 33 is a front view of the folding device.

FIG. 34 is a side view of the folding device similarly showing the operation in the C-folding mode.

FIG. 35 is a side view of the folding device similarly showing the operation in the Z-folding mode.

FIG. 36 is a schematic perspective view of the image forming apparatus showing a take-out portion of the stacked sheet bundle.

FIG. 37 is a block diagram relating to the opening / closing operation of each cover of the sheet post-processing apparatus and the control of each drive unit of the sheet post-processing apparatus.

[Explanation of symbols]

S sheet B ₁ (B _{11 to} B _1n ) First bin module (loading means) B ₂ (B _{21 to} B _2n ) Second bin module (loading means) B _{11 to} B _1n , B _{21 to} B _2n bins (Sheet tray) 13 Stack unit (stacking means) 201 Copier main body (image forming apparatus main body) 203 Sheet post-processing device 204 Folding device (folding means) 205 Staple / stack device 270 CPU (control means) 271 Ejection of copy machine main body Roller (discharging means) 301 Front cover 3 301a Front cover switch 303 Take-out cover 303a Take-out cover switch 306 Top cover 306a Top cover switch 307 Bin cover 307a Bin cover switch M1 Bin shift motor (first driving means) M2 Matching motor (first) Driving means) M4 bundle processing lifting motor (second drive) Moving means) M14, M15, M16 Conveying motor (first driving means) M7, M8, M9, M10 Motor in bundle processing unit (second driving means) M11 Stack unit lifting motor (second)
Driving means) M12, M13 Motor in stack unit (second driving means)

Claims (2)

[Claims] 1. A plurality of stacking means arranged vertically for sorting and stacking sheets conveyed by a conveying means, an aligning means for aligning the stacked sheet bundles, and a bundle for processing the aligned sheet bundles. A processing unit; a transfer unit provided in the bundle processing unit for transferring a sheet bundle; a binding unit for binding the sheet bundle; a stack unit for storing the sheet bundle transferred by the transfer unit; A first drive including a stack tray and a reference plate that are vertically movable inside, a unit that drives the transport unit, a unit that shifts a plurality of bin trays of the stacking unit, and a unit that drives the alignment unit. Means, means for raising and lowering the bundle processing unit to a vertical position corresponding to the stacking means, transfer means and binding in the bundle processing unit A second means including a means for driving a stack, a means for moving the stacking means up and down to a vertical position corresponding to the stacking means and a take-out position in the middle thereof, and means for driving a stack tray and a reference plate in the stacking unit. The drive means, a take-out cover that is opened and closed to operate the stack unit at the take-out position, a take-out cover switch that is turned on and off when the take-out cover is opened and closed, and a take-out cover switch that opens the take-out cover And a control means for controlling so that the drive operation of the first drive means is continued and the drive operation of the second drive means is stopped when the stack device is turned off. A sheet post-processing device provided. 2. The sheet post-processing apparatus according to claim 1, an image forming unit for forming an image on the sheet, and a sheet discharging unit for discharging the image-formed sheet to the sheet post-processing apparatus. Image forming apparatus.