JPH08295450A - Image forming system - Google Patents

Abstract

PURPOSE: To prevent the increase of the size of a staple device and to improve copy productivity by a method wherein a staple spot in a paper bundle is selected to either a tip part or a rear end part in a conveyance direction. CONSTITUTION: A staple unit 441 has a conveyance part 465 slightly longer than the length in a conveyance direction of a small paper sheet and is provided at the inlet of a conveyance part with a needle drive part and a needle receiving part. When a paper sheet is small in size, a paper bundle is conveyed out from an accumulation tray 411 to a conveyance part 465 to staple a rear end part. Since, during staple processing, a paper bundle is conveyed out from the accumulation tray 411, a subsequent set of copy papers are immediately contained in the accumulation tray without waiting and copy productivity is improved. Meanwhile, a paper sheet is large in size, a tip part is stapled. In this case, since large size paper sheets remain on the accumulation tray during staple processing, copy productivity is reduced but the increase of the length of the conveyance part 465 and the increase of the size of the staple unit 441 are prevented from occurring.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image forming system, particularly an image forming apparatus main body such as an electrophotographic copying machine or a laser printer, and a finisher for performing post-processing for sorting and binding sheets discharged from the main body. The present invention relates to an image forming system in which

[0002]

2. Description of the Related Art In general, various finishers have been provided for sorting image-formed sheets discharged from a copying machine into a desired number of copies and stapling. In a finisher that does not have multiple trays for stapling, after stacking only one end where the stapler is installed on the stacking tray for temporarily stacking / accommodating sheets, the stack of paper is provided at the bottom of the stacking tray. It has been proposed to move it to another storage tray.

[0003]

However, when the stapling process is performed on the stacking tray, the next set of sheets is sent to the stacking tray only during the time required for the stapling process and the time for discharging the sheet bundle from the tray. It is necessary to wait for the copy processing of the set, which deteriorates the copy productivity as a whole. In order to solve this, the sheet bundle stored in the stacking tray may be carried out to the stapling conveyance section and the stapling process may be performed. That is, the sheet bundle may be taken out from the stacking tray to the staple transport unit, and the rear end portion of the sheet bundle in the transport direction may be bound.

However, in the structure in which sheets of all sizes are bound at the rear end, the conveying section becomes longer than necessary, and the stapling apparatus itself also has a large structure for connecting the staple striking section and the staple receiving section. On the contrary, it is inconvenient. Therefore,
An object of the present invention is to provide an image forming system capable of improving copy productivity without increasing the size of a stapling device.

[0005]

In order to achieve the above object, the image forming system according to the present invention comprises:
The finisher is provided with an electrophotographic image forming apparatus main body and a stapling means for driving a staple into a bundle of sheets. The main body of the image forming apparatus has image processing means for storing image information and inverting the top and bottom of the stored image. The stapling means has a transport section slightly longer than the length of the small-size sheet in the transport direction, and has a stapling section and a staple receiving section at the entrance of this transport section, and the staple portion for the sheet bundle is located at the front or rear end in the transport direction. It is possible to select either part or part.

If the size of the paper is small, the paper stack is unloaded from the stacking tray to the transport unit and the rear end is stapled.
Since the sheet bundle is carried out from the stacking tray during the stapling process, the next set of copy sheets can be immediately stored in the stacking tray without waiting, and the copy productivity is improved. On the other hand, if the paper is a large size, the leading end is stapled. In this case, since the large size sheet remains on the stacking tray during the stapling process, it is inferior in terms of copy productivity, but it is possible to prevent the transport section from becoming large and the stapling means from becoming large.

On the other hand, in either the leading edge binding mode or the trailing edge binding mode, the image processing means inverts the original image. By this image inversion process, the image on the paper and the staple position can be normally maintained in both the leading edge binding mode and the trailing edge binding mode.

[0008]

Embodiments of the image forming system according to the present invention will be described below with reference to the accompanying drawings. (Copying System) FIG. 1 shows a copying system which is an embodiment of the present invention, and comprises a copying machine 10 and a finisher 40. The copying machine 10 forms an image on a sheet by a well-known electrophotographic method, and ejects the copied sheets one by one with the image forming surface facing upward from the sheet ejection unit 11. An automatic document feeder 20 (hereinafter referred to as ADF) is provided on the upper part of the copying machine 10.
It is installed). The ADF 20 feeds the originals set on the tray 21 one by one onto the platen glass (not shown) of the copying machine 10, and after the image reading is completed, the originals are discharged / loaded onto the tray 22. A document set on the platen glass automatically by the ADF 20 or manually by an operator has its image read by an image reader (not shown) built in the copying machine 10 and converted into digital data to be controlled by the control unit. Stored in memory. The copy operation is executed by reading out this image data and adding necessary edits.
In particular, in this control unit, a process for changing the page order of the original document, an image inversion process for rotating the original image by 180 ° for copying, or a process for arranging two original images side by side on one sheet, It is possible to do double-sided copying, etc.

(Schematic Configuration of Finisher) As shown in FIG. 1, the finisher 40 includes a non-sort tray 401 for stacking / accommodating sheets ejected from the copying machine 10 and a processing section 41 for stapling after accumulating the sheets. A storage unit 46 for storing the stapled sheet bundle, and the copying machine 1
The paper transport unit 4 that selectively transports the paper discharged from 0 to the non-sort tray 401, the processing unit 41, or the storage unit 46.
7 and 7. A paper folding mechanism 30 described in detail below is attached to the paper transport unit 47.

(Paper Conveying Section) As shown in FIG. 2, the paper conveying section 47 has a conveying path 48 for receiving a sheet from the sheet ejecting section 11 of the copying machine 10 and conveying it downward, and a front / back / front / back side of the sheet. A switchback transport path 49, a transport path 50 for transporting a sheet to the non-sort tray 401, and a transport path 50.
A conveyance path 51 for branching from the sheet and conveying the sheet to the processing section 41
And a transport path 52 that branches from the transport path 50 and transports the sheet to the storage section 46.

As shown in FIG. 3, the conveying path 48 has a pair of conveying rollers 481 and 481 that normally rotate in the sheet conveying direction (arrow c).
2, a guide plate 483, 484, and a sheet detection sensor SE1. Switchback transport path 49
Is a conveyance roller 49 that can rotate in the forward / reverse direction of the arrow a / b.
1, a driven roller 492 which rotates in contact with the roller 491, a pair of transport rollers 493 which transports the switched-back sheet in the direction indicated by the arrow d, and a guide plate 49.
4 and a sheet detection sensor SE2.
A flexible resin sheet 497 is provided on the bent portion of the guide plate 483.
Is affixed.

The sheet conveyed along the conveying path 48 in the direction of arrow c passes through the resin sheet 497 and is guided to the switchback conveying path 49. The rear end of the paper is the sensor SE
When a predetermined time elapses after being detected in step 2, that is, when the trailing edge of the paper leaves the resin sheet 497, the roller 491 is switched to the reverse rotation and the paper is conveyed in the direction of arrow d. At this time, the resin sheet 497 functions so that the paper does not return to the transport path 48.

As shown in FIG. 4, the conveying path 50 is a pair of conveying rollers 501 and 50 for conveying the paper in the direction indicated by arrow e.
2, 503 and 504, a pair of discharge rollers 505, guide plates 506 and 507, and sensors SE3 and SE for sheet detection.
4. A punch mechanism 90 for forming punch holes at the leading end or the trailing end of the sheet is installed in the transport path 50 during the sheet transport. The punch mechanism 90
Is omitted.

The transport path 51 includes a switching claw 511 for switching the transport destination of the paper, a transport roller pair 512 and a discharge roller pair 513 for transporting the paper in the direction of the arrow f, guide plates 514 and 515, and a paper detecting member. Sensor SE5. The transport path 52 includes a switching claw 521 for switching the transport destination of the paper, transport roller pairs 522 and 523 for transporting the paper in the direction of arrow g, and a discharge roller pair 524.
And a guide plate 525, 526, 527, and a sensor SE6 for sheet detection.

The switching claws 511 and 521 are respectively provided on the support shaft 5.
The switchback conveyance path 49 is rotatable by a solenoid (not shown) with 11a and 521a as fulcrums.
The sheet conveyed from is guided by the switching claw 521 to one of the conveyance paths 50 and 52. The sheet conveyed through the conveyance path 50 is conveyed along the conveyance path 50 as it is by the switching claw 511 or introduced into the conveyance path 51 in the middle thereof. The paper is discharged from the discharge roller pair 505 to the non-sort tray 401, and from the discharge roller pair 513 to the processing unit 4.
1 is sent from the discharge roller pair 524 to the accommodating portion 46. The rotation speed of each discharge roller pair 505, 513, 524 is reduced immediately after the trailing edge of the sheet is detected by each of the sensors SE4, SE5, SE6, and the sheet is discharged while being decelerated so as not to disturb the stacked state of the sheet. .

As shown in FIG. 2, the accommodating section 46 includes an accommodating tray 475, a drive mechanism 476 for raising and lowering the tray 475, a sensor SE7 for detecting the accommodating amount of the sheet, and a tray. And a sensor SE8 for detecting the lower limit position of 475. Tray 475
When a large number of sheets are copied, the sheets are fed one by one, or the sheet bundle stapled by the processing unit 41 is fed from the conveyance path 52 as described in detail below. The tray 475 is moved down by a constant amount by the drive mechanism 476 every time the sheet stored / loaded on the tray 475 is detected by the sensor SE7. When the sensor SE8 detects that the tray 475 is lowered to the lower limit, the tray 475 is full at this time, and the subsequent copying operation is interrupted.

The structure of the drive mechanism 476 for lowering the tray 475 by a fixed amount for accommodating a large capacity is well known and its detailed description is omitted.

(Paper Folding Mechanism) The paper folding mechanism 30 is provided immediately below the conveying section 47, and has a function of folding an image-formed sheet in half at the central portion in the conveying direction, and opening the folded sheet again. A function to make a crease in the center and Z paper
It has a folding function. As shown in FIG. 18, the Z-fold is a form in which a sheet is bent twice with the image forming surface facing upward.

More specifically, as shown in FIG. 2, the paper folding mechanism 30 receives a sheet from the switchback conveying path 49 and conveys the sheet downward to perform the first folding, and a first conveying path 31. A second transport path 32 for folding two,
A paper folding unit 35 for executing several types of paper folding, and a third conveyance path 33 for conveying the paper after the paper folding further downstream.
And a fourth conveyance path 34 which feeds the paper to the conveyance path 50 by inverting (switching back) the sheet back and forth / front and back.

The paper folding unit 35 includes three folding rollers 351.
The main folding roller 35 is composed of 352 and 353.
2 can be driven to rotate in the forward and reverse directions, and is an auxiliary folding roller 35.
1, 353 are in pressure contact with the folding roller 352 and are driven to rotate. The paper folding operation by the folding rollers 351, 352, 353 will be described below. The first conveyance path 31 is located on the right side of the paper folding section 35, and has a pair of conveyance rollers 311 that can be driven to rotate in the forward and reverse directions, a sheet passing direction switching claw 312, and a sheet regulation plate 3.
13 and guide plates 314, 315, 316, 317. The regulation plate 313 is the first for folding the paper.
This is for determining the first sheet folding position by regulating the leading edge of the paper fed into the transport path 31, and the lower part of the first transport path 31 can be raised and lowered by a stepping motor (not shown). The position (height) of the regulation plate 313 is changed according to the folding mode (two-folding or Z-folding) and the sheet size. The switching claw 312 is driven by a solenoid (not shown), and switches whether the sheet fed into the first transport path 31 is directly transported to the paper folding section 35 or once below the first transport path 31.

The second conveying path 32 is located right above the paper folding section 35, and has a paper passing direction switching claw 321 and a paper regulating plate 322.
And guide plates 323 and 324. The regulation plate 322 is for regulating the leading edge of the paper fed into the second transport path 32 to determine the second paper folding position, and in the upper portion of the second transport path 32, a solenoid (not shown) is used to transport the paper in the paper transport direction. It is possible to switch between two positions. The switching claw 321 is driven by a solenoid (not shown) to feed the sheet passing between the folding rollers 351 and 352 to the second transport path 32, or to pass directly through the second transport path 32 and between the folding rollers 352 and 353. Or switch.

The third transport path 33 has guide plates 331, 33.
The sheet that is configured by No. 2 and is sent from the folding rollers 352 and 353 is conveyed to the fourth conveying path 34. 4th transport path 3
4 is located on the left side of the paper folding unit 35 and is capable of forward / reverse rotation driving, a conveying roller pair 341, vertical portions of the guide plates 331 and 332, and a guide plate 345, and a conveying roller pair 342 for conveying the sheet upward. 343 and 344. The upper end of the fourth transport path 34 is connected to the transport path 50. A flexible resin sheet 333 is attached to the bent portion of the guide plate 332 on the exit side of the third transport path 33. The sheet conveyed through the third conveying path 33 passes through the resin sheet 333, and is conveyed downward through the fourth conveying path 34 by the reverse rotation of the conveying roller pair 341. When the trailing edge of this sheet passes through the resin sheet 333, the pair of conveying rollers 341 is switched to the normal rotation, and the sheet is conveyed to the fourth conveying path 3.
4 is conveyed upward. The resin sheet 333 functions so that the sheet does not return to the third transport path 33 during this switchback.

On the other hand, as shown in FIG. 5, the paper folding mechanism 30 is integrally housed in a casing 36 to be unitized, and can be pulled out to the front side of the finisher 40. This drawer has a finisher 4
This is performed by rolling a roller provided in the casing 36 on a rail (not shown) provided in 0. Paper folding mechanism 3
By making 0 removable from the finisher 40, maintenance, inspection, and paper jam processing of the paper folding mechanism 30 are facilitated.

(Paper Folding Operation) The operation of the paper folding mechanism 30 will now be described. The paper folding mechanism 30 has four modes of Z-folding as the first mode, bi-folding as the second mode, creasing as the third mode, and simply passing the sheet without folding the paper as the fourth mode. Have These modes are selected by the operator on the operation panel (not shown) of the copying machine.

The first mode, Z-folding, is a process for folding large size sheets (A3, B4) into the Z shape shown in FIG. As shown in FIG. 6, the paper P is sent from the transport path 49 to the first transport path 31 by the transport rollers 491 and 492, and is transported downward by the transport roller pair 311 toward the regulation plate 313. The regulation plate 313 is set at a position corresponding to the Z-folding mode according to the size of the paper P. When the leading edge of the paper P contacts the regulation plate 313, the paper P
Is curved toward the nip portion of the folding rollers 351 and 352 by the conveying force applied from the conveying roller pair 311. Then, the curved portion of the sheet P is caught in the nip portion of the folding rollers 351 and 352, and the first folding is performed. Folding roller 35
1, 352 and 353 are driven in the normal direction in the direction of arrow a when the sensor SE2 detects the leading edge of the sheet P.

The sheet P for which the first folding is completed as described above
Is guided by the switching claw 321 first to the first fold Pa and is transported to the second transport path 32. The regulation plate 322 located on the second transport path 32 is set at a position corresponding to the second folding in the Z-folding mode according to the size of the paper P. As shown in FIG. 7, when the first fold Pa of the paper P comes into contact with the regulation plate 322, the paper P is folded by the folding rollers 351 and 351.
Folding rollers 352, 35 by the conveying force applied from 352
3 is curved toward the nip portion side, and this curved portion is bent by the folding roller 35.
The second folding is performed by being bitten by the nip portions of 2,353.

The sheet P, which has been Z-folded as described above, passes through the third conveyance path 33 and the fourth conveyance path 34 as shown in FIG.
And is conveyed downward by the reverse rotation of the conveying roller pair 341 in the direction of arrow b. When the trailing edge of the paper P passes through the resin sheet 333, the pair of transport rollers 341 is switched to the normal rotation. The paper P is switched back here,
As shown in, the conveyance roller pairs 341, 342, 343,
It is conveyed upward in the fourth conveyance path 34 by 344 and is sent to the conveyance path 50.

The reason why the Z-folded sheet is switched back in the fourth transport path 34 is that the sheet does not disturb the alignment when it is discharged onto the tray 401, 411 or 475. When the Z-folded sheet P without being switched back in the fourth transport path 34 is discharged onto the non-sort tray 401 (same for the other trays 411 and 475), the fold Pb is upward as shown in FIG. 18B. Is placed facing to. When the next sheet is ejected on top of it, the leading edge of the next sheet also slips under the second fold Pb of the sheet P. In order to prevent such misalignment, the paper P is fed in the fourth transport path 34.
Switch back. Now, the paper P is shown in FIG.
As shown in (c), the tray 40 with the fold line Pb facing downward.
The next sheet is ejected onto the first sheet P and is correctly aligned and accommodated on the previous sheet P.

The second mode, half-folding, is a process of folding a sheet at the center in the transport direction. In this case, as shown in FIG. 10, the regulation plate 313 of the first transport path 31 is set at a position where the sheet P is bent at the center according to the size of the sheet P. As described with reference to FIG. 6, the leading end of the paper P conveyed through the first conveyance path 31 comes into contact with the regulation plate 313, the center portion thereof is curved and is caught in the nip portion of the folding rollers 351 and 352. Is. The sheet P folded in the central portion is guided by the switching claw 321 first to the fold Pc and fed into the nip portion of the folding rollers 352 and 353 (see FIG. 11). Then, the paper P is sent to the fourth transport path 34 through the third transport path 33, and is switched back by switching the transport roller pair 341 from the reverse rotation in the direction of arrow b to the normal rotation as described in FIG. The sheet is conveyed upward through the fourth conveying path 34 (see FIG. 12), and the conveying path 50
Sent to.

The third mode, creasing, is a process in which a staple unit 441, which will be described below, creases the central portion of the paper in advance in order to bind the central portion of the paper. Paper P that has been transported through the first transport path 31
On the other hand, the regulation plate 313 regulates the tip of the regulation plate 313 so that the center portion is engaged with the nip portions of the folding rollers 351 and 352, as described with reference to FIG. As shown in FIG. 13, when the central portion of the sheet P is bitten into the nip portion of the folding rollers 351 and 352 by a predetermined amount, the conveying roller pair 311 is formed.
The folding rollers 351 and 352 are driven in the reverse direction in the direction of arrow b. The timing for switching to this reverse rotation is when the timer that starts when the sensor SE2 detects the trailing edge of the paper P counts for a predetermined time. Due to this reverse rotation, the folded portion of the paper P is extended and the first conveyance path 31
Is conveyed upward and is conveyed back to the conveyance path 49. On the other hand, the transport rollers 491 and 492 are also switched to the reverse rotation at substantially the same timing as the transport roller pair 311 and the sheet P is guided from the transport path 49 to the transport path 50 by being guided by the resin sheet 497. This crease mode is executed only when the saddle-stitching staple processing is performed on the paper, and the paper P
Is discharged from the transport path 51 onto the processing tray 411 of the processing section 41.

In the paper passing mode which is the fourth mode, the paper folding mechanism 30 is simply used without performing the paper folding process on the paper.
Is a process of passing. The paper P is conveyed from the conveyance path 49 to the first
When the sheet P is conveyed to the conveying path 31, the switching claw 312 causes the sheet P to be folded by the folding rollers 351 and 35, as shown in FIG.
The switching claw 321 is set to a position for guiding the sheet P to the folding rollers 352 and 353. Therefore, the paper P passes through the nip portion between the folding rollers 351 and 352, the nip portion between the folding rollers 352 and 353, and is conveyed to the third conveying path 33 (see FIG. 16). After that, as described in FIGS. 8 and 12, the sheet P is switched back by switching the reverse direction of the conveying roller pair 341 in the direction of the arrow b to the forward direction, and is conveyed upward in the fourth conveying path 34 (FIG. 17), and is sent to the transport path 50.

(Staple Processing Section) Next, the staple processing section 41 will be described. The staple processing unit 41 is
As shown in FIGS. 19 and 20, the sheet stacking unit 410 and the staple unit 440 are used. Paper stacking unit 410
Is a stacking tray 411 installed at an inclination, a leading end stopper 412 installed at the leading end of the tray 411, a side aligning plate 413 of the sheet, and a first and second unit capable of gripping / releasing the side of the sheet. The second chuck means 415 and 416.

The stacking tray 411 temporarily stacks / stores the sheets discharged from the conveying path 51 with the image forming surface facing downward for the stapling process. Tip stopper 41
2 is the leading edge of the sheet discharged onto the tray 411 (tray 4
The sheet is aligned in the conveying direction (arrow h) to the staple unit 440 by receiving the rear end when viewed from the ejecting direction to 11. The side aligning plate 413 is capable of reciprocating in a direction (arrow i) orthogonal to the transport direction, and the paper is transferred to the tray 411.
Align laterally above. The first chuck means 415 is installed on the front side of the tray 411, and the second chuck means 416 is provided.
Are installed on the back side of the tray 411, and alternately hold the side portions of the sheets, respectively, and prevent the sheets from floating. Also,
The first chucking unit 415 also has a function of gripping a sheet bundle and sending it to the staple unit 440.

(Side Side Alignment Plate) As shown in FIGS. 20 and 21, the side alignment plate 413 has a height L ₁ higher than the maximum height of the stack of sheets that can be stored on the stacking tray 411. It is provided at a position facing the alignment reference plate 414 attached to the first chuck means 415. The alignment plate 413 is installed on the spiral shaft 530 located on the back side of the tray 411 so as to be capable of reciprocating in the direction of arrow i based on its rotation, and the spiral shaft 530 is driven to rotate in the forward and reverse directions by the stepping motor M1. The aligning plate 413 stands by at the position shown by the solid line in FIG. 20, and advances to the aligning position (shown by the chain double-dashed line in FIG. 20) corresponding to the size of the paper P by the forward rotation of the motor M1. At this time, the other side portion of the paper P is the reference plate 41.
4 and are aligned. The fact that the matching plate 413 is at the home position means that the light shielding plate 53 fixed to the matching plate 413 is fixed.
1 is detected by entering the optical axis of the sensor SE9 provided on the back side of the tray 411. The distance L _{2 for} advancing to the alignment position is determined by controlling the number of pulses for driving the stepping motor M1 according to the size of the paper P.

The sheet is conveyed in the conveying section 47 with the center as a reference, and is conveyed from the discharge roller pair 513 in the conveying path 51 to the accumulating tray 4.
It is discharged onto 11 (see the chain double-dashed line in FIG. 20). After a lapse of a predetermined time until the rear end of the sheet is detected by the sensor SE5 and the sheet is completely stored on the tray 411, the stepping motor M1 is driven to rotate normally. When one sheet is aligned between the aligning plate 413 and the reference plate 414, the motor M1 is rotated in the reverse direction, and the aligning plate 413 retracts to the home position. That is, the aligning plate 413 advances in the direction of the arrow i every time one sheet of paper is stored on the tray 411, abuts the sheet on the reference plate 414, and aligns the sheet on the tray 411 with one side reference.

(First Chuck Means) As shown in FIGS. 22 and 23, the first chuck means 415 includes friction plates 417a and 418a made of an elastic material and a support plate 4 for supporting the friction plates.
19a and 420a, a solenoid SL1a for moving the friction plate 417a up and down, and a support plate 422 that holds these members. The solenoid SL1a has a plunger 433a and a spring member 421a and a lever 4a.
23a, the friction plate 417a moves downward together with the support plate 419a when the solenoid SL1a is turned on, so that the side of the stack of sheets on the stacking tray 411 is elastic with the friction plate 418a. To grasp the target.

The friction plates 417a and 418a are retracted from the chucking position shown in FIG. 22 in the direction of the arrow i, that is, at the positions outside the side portions of the sheets P aligned on the stacking tray 411 shown in FIG. It is set. In order to move the friction plates 417a and 418a and the support plates 419a and 420a to the chucking position in the direction opposite to the arrow i, the solenoid SL2 is installed on the bracket 424. The plunger 434 of the solenoid SL2 has a pin 43.
It is connected to a link 436 rotatable about 7 as a fulcrum, and the tip of the link 436 is connected to the support plates 419a and 420a. The link 436 is biased clockwise in FIG. 22 by a spring 435 wound around the pin 437. When the solenoid SL2 is off, the plunger 43
4 is retracted, and the friction plates 417a and 418a are supported by the support plate 419.
It is retracted to the outside of the sheet P together with a and 420a. This withdrawal is to prevent the friction plate 417a and the support plate 419a from interfering with the sheet when the sheet is stored on the tray 411. On the other hand, when the solenoid SL2 is turned on, the plunger 434 moves forward, the link 436 rotates counterclockwise, and the friction plates 417a and 418a move in the opposite direction to the arrow i together with the support plates 419a and 420a. It is set to the chucking position.

Further, the first chuck means 415 grips the side portions of the sheet bundle to staple the sheet bundle 44.
It can be moved back and forth in the direction of arrow h in order to convey it to 0.
For this movement, the nut member 425 fixed to the bracket 424 is screwed to the spiral shaft 426.
The spiral shaft 426 is rotatably mounted on the frame 427, and is normally / reversely rotated by the motor M2 via a drive transmission unit 428 including a gear and a belt. That is, the motor M
The forward rotation of 2 causes the spiral shaft 426 to forwardly rotate, the first chuck means 415 moves forward in the transport direction h, and the reverse rotation of the motor M2 causes the spiral chuck 415 to move backward. The fact that the first chuck means 415 is at the home position H ₁ means that the light shielding plate 430 fixed to the bracket 424 is provided on the frame S427.
It is detected by entering the optical axis of E10.

Further, a disc 431 having a large number of small holes regulated in the peripheral portion is fixed to the output shaft of the motor M2, and the sensor SE11 detects the small holes based on the rotation of the disc 431. Then, a pulse signal is generated. The movement amount of the first chuck means 415 can be detected by counting the number of pulses output from the sensor SE11, and the motor M2 is turned off at the time when a predetermined number of pulses are counted, so that the first chuck means 415 operates. The amount of movement can be controlled accurately. On the other hand, stacking tray 4
An elongated hole 411a is formed in 11 (see FIG. 20), and the friction plates 417a and 418a can hold the sheet bundle and can move in the transport direction h.

As shown in FIG. 24, the spiral shaft 426.
Has a tip extending to a position Y near the staple portion 440, and the first chuck means 415 moves to this position Y. At this time, the leading ends of the sheet bundle gripped by the friction plates 417a and 418a are sandwiched by the transport rollers 469 and 470 in the staple unit 440, and the sheet bundle is subsequently transported by the transport rollers 469 and 470. Therefore, the distance L ₃ from the position Y to the nip portion of the rollers 469 and 470 is set shorter than the minimum size sheet (B5Y).

(End Stopper) As shown in FIG. 25, the front end stopper 412 is rotatably attached to the back side of the front end of the stacking tray 411 with a pin 711 as a fulcrum, and a cam 712 fixed integrally with the stopper 412 is a spring. 710
It is rotated in the counterclockwise direction by being urged by, and the leading end projects onto the tray 411 to regulate the leading end of the paper. The stopper 412 has a comb-teeth shape, and as shown in FIG. 20, protrudes upward from the recess 411c at the tip of the tray 411.
A lever 713 fixed to the bracket 424 of the first chuck means 415 is attached to the upper end inclined surface of the cam 712.
The tip of is in contact.

As described above, the set of sheets stacked on the stacking tray 411 is gripped by the first chuck means 415 and conveyed in the direction of arrow h by the forward rotation of the motor M2 (spiral shaft 426). At this time, the lever 71
3 also moves in the direction of arrow h integrally with the first chuck means 415, and as shown in FIG. 26, rotates the cam 712 in the clockwise direction. At the same time, the tip stopper 412 is also pin 711.
Is rotated in the clockwise direction with the fulcrum as a fulcrum, and retracted to the back side of the tray 411. While the sheet bundle is being conveyed, that is, while the first chuck means 415 is in the forward position from the home position H ₁ , the tip stopper 412 has the cam 712 and the lever 712.
By being pressed by 13, the sheet is held on the back surface side of the tray 411, and the sheet can be conveyed. Stopper 41
When the stopper 412 is in the retracted state, the second leading end portion 412a is located on substantially the same surface as the tray 411 and guides the lower side of the conveyed sheet bundle. This facilitates the delivery of the sheet bundle from the tray 411 to the staple unit 440.

When the sheet bundle is delivered to the stapling section 440, the solenoid SL1a is turned off and the friction plate 417 is turned off.
a and 418a release the sheet bundle, and at the same time, the motor M
2 is reversed and the first chuck means 415 retracts to the home position H ₁ . When the first chuck means 415 returns to the home position H ₁ , the lever 713 moves to the cam 71.
The pressure on 2 is released, and the leading end stopper 412 rotates upward to prepare for accommodation of the next set of sheets.

(Second Chuck Means) As shown in FIGS. 27 and 28, the second chuck means 416 includes friction plates 417b and 418b made of an elastic material and a support plate 4 for supporting the friction plates.
19b and 420b, a solenoid SL1b for moving the friction plate 417b up and down, and a support plate 724 that holds these members. The solenoid SL1a has a plunger 433b whose spring 421b and lever 423b.
Is connected to the support plate 419b via the solenoid SL1.
By turning on b, the friction plate 417b is moved to the support plate 419.
b together with the friction plate 418b, the tray 4
The side portion of the sheet stack on 11 is elastically gripped. It should be noted that this configuration is the same as the first chuck means 415.

Further, the second chuck means 416 moves from the home position H ₂ shown by the solid line in FIG.
It is possible to reciprocate in a direction orthogonal to (arrow i) to a position where the side portion of the paper P can be gripped. For this movement, a nut member 725 fixed to the support plate 724 is screwed to the spiral shaft 726. The spiral shaft 726 is rotatably mounted on the frame 727, and is normally / reversely rotated by the motor M3 via a drive transmission unit 728 composed of a gear and a belt. That is, the spiral shaft 726 also rotates normally by the normal rotation of the motor M3, the second chuck means 416 moves forward in the direction of the arrow i, and moves backward by the reverse rotation of the motor M3. Second
The fact that the chuck means 416 is at the home position H ₂ means that the light shield plate 730 fixed to the support plate 724 is the frame 7
It is detected by entering the optical axis of the sensor SE12 provided at 27.

Further, a disk 731 having a large number of small holes regularly formed in the peripheral portion is fixed to the output shaft of the motor M3, and the sensor SE13 detects the small holes based on the rotation of the disk 731. Then, a pulse signal is generated. The movement amount of the second chuck means 416 can be detected by counting the number of pulses output from the sensor SE13, and the motor M3 is turned off at the time when a predetermined number of pulses are counted, so that the second chuck means 416 can be operated. The amount of movement can be controlled accurately. On the other hand, stacking tray 4
An elongated hole 411b is formed in 11 (see FIG. 20), and the friction plates 417b and 418b can hold the sheet bundle and can move in the arrow i direction.

The size of the paper stored in the stacking tray 411 varies from the minimum B5Y to the maximum A3T. Like the side aligning plate 413, the second chucking means 416 uses the aligning plate 413 and the reference plate 414 in accordance with the size of the sheet sent from the control unit of the copying machine 10 to the control unit of the finisher 40. Advance the side of the aligned sheet to a position where it can be gripped.

(Chuck Operation) In this embodiment, the first
The chucking means 415 operates in the three modes described below. In the first mode, the side portions of the sheets accommodated / aligned on the stacking tray 411 are transferred side by side to the second chuck means 4 one by one.
Grasp with 16 alternately. This alternate chuck operation is executed when the paper folding mode is selected. When stapling a sheet that is not folded, the first chuck means 415 stands by at the home position H ₁ . In the case of the alternate chucking operation, the first chucking means 415, regardless of the size of the paper size, moves from the home position H ₁ to the position Q facing the second chucking means 416 as shown in FIG.
It moves by rotating the motor M2 forward. At this position Q, the solenoids SL1a and SL2 are turned off, and the friction plates 417a and 418a are retracted to the outside of the alignment reference line A of the reference plate 414 while being opened vertically. The second chuck means 416 is also at the home position H ₂
Waiting at

The paper P is fed from the conveying path 51 to the accumulating tray 4
When ejected to 11, the aligning plate 413 advances from the home position in the direction of arrow i by a predetermined amount based on the sheet trailing edge detection signal from the sensor SE5, and aligns the sheet P with the reference plate 414. Next, the solenoid SL2 is turned on based on the forward movement completion signal of the matching plate 413, and the friction plates 417a,
418a advances to a position where the side portion of the aligned sheet P is sandwiched. At this time, the solenoid SL1a is turned on, and the friction plates 417a and 418a grip the side portion of the paper P. The alignment plate 413 returns to the home position when the chuck operation is completed.

When the next sheet is discharged to the tray 411,
Similarly to the above, the aligning plate 413 moves forward by a predetermined amount, and in synchronization with this, the second chuck means 416 also moves forward by a predetermined amount in the direction of arrow i from the home position H ₂ . Next, the solenoid SL1b is turned on based on the forward movement completion signal of the matching plate 413,
Friction plates 417b and 418b grip the sides of the paper. Almost at the same time, the alignment plate 413 returns to the home position and the solenoid S of the first chuck means 415 is moved.
L1a is turned off and the friction plates 417a and 418a release the paper. After that, the solenoid SL2 is turned off, and the friction plates 417a and 418a retract to the outside of the paper. Further, when the next sheet is stored, the second chucking means 416 releases the sheet bundle and retracts, so that the first chucking means 4 moves.
15 holds the sheet bundle.

The chuck means 415, 416 alternately repeats forward / backward movement to the chucking position every time one sheet of paper is thus fed onto the tray 411, and holds the sheet bundle. By the operation in the first mode, it is possible to prevent the sheets from floating and it is possible to set the stacking amount of the stacking tray 411 to be large. In particular, it is effective when accommodating a folded or Z-folded sheet as described above.

In the second mode, the first chuck means 415 moves the stack of sheets on the stacking tray 411 to the home position H ₁
Then, the sheet bundle is conveyed by L _{4 in the} direction of arrow h (see FIG. 20). This is to set the leading end of the sheet bundle to the staple position X (X indicates the staple position in the transport direction, see FIG. 24) in order to staple the leading end of the sheet bundle.

In this second mode, when one set of paper is aligned on the tray 411, the second chuck means 41
In the state where 6 is waiting at the home position H ₂ , the first chuck means 415 grips the sheet bundle at the home position H _{1 and} advances the distance L _{4 by the} forward rotation of the motor M2. At this time, the leading edge stopper 412 is rotated downward to release the leading edge regulation, as described above. After the leading edge of the sheet bundle is detected by the sensor SE18 (see FIG. 33) of the stapling section 440, a predetermined time has passed. After a lapse of time, the normal rotation of the motor M2 is turned off. A staple is driven into the leading end of the sheet bundle conveyed by the distance L ₄ .

After the stapling process is completed, the first chuck means 415, while holding the sheet bundle, further moves in the direction of arrow h by rotating the motor M2 in the forward direction to transfer the sheet bundle to the conveying rollers 469, 470. Add The first here
Stopping of the chuck means 415 is controlled based on the pulse signal from the sensor SE11. After that, the first chuck means 415 and the solenoids SL1a and SL2 are turned off, and the motor M2 is rotated in the reverse direction to return to the home position H ₁ .

In the third mode, the first chuck means 415 moves the stack of sheets on the stacking tray 411 to the home position H ₁
Grip the sheet bundle with the leading edge of the transport rollers 469, 4
The sheet is conveyed by the distance L _{3 in the} direction of arrow h until it is sandwiched by 70 (see FIG. 20). This is to staple the central portion of the sheet bundle or to staple the rear end portion of the sheet bundle.

In this third mode, when one set of paper is aligned on the tray 411, the second chuck means 416 is used.
In the state of waiting at the home position H ₂ , the first chuck means 415 grips the sheet bundle at the home position H _{1 and} advances the distance L _{3 by the} forward rotation of the motor M 2.
At this time, the tip stopper 412 rotates downward to release the tip regulation, as described above. The stop of the first chuck means 415 at the distance L ₃ is controlled based on the pulse signal from the sensor SE11. Thereafter, the first chucking means 415 returns to the position H ₁ by turning off the solenoids SL1a and SL2 and reversing the motor M2. Paper bundles are conveyed by rollers 469, 4
The sheet 70 is further conveyed in the direction of the arrow h and the stapling process is performed, which will be described later.

(Stapling Section) As shown in FIGS. 24 and 29, the stapling section 440 is the staple unit 44.
1, a unit moving unit 454, and a sheet bundle conveying unit 465.

(Stapling Unit) As shown in FIGS. 29, 30, and 31, the staple unit 441 includes a staple cartridge 442, a staple striking portion 443, and a staple receiving portion 4.
44, and a connecting portion 445 that connects the needle striking portion 443 and the needle receiving portion 444.

The staple cartridge 442 is detachable from the staple striking portion 443, and is a well-known staple cartridge that accommodates the staple 603. The staples 603 are formed by arranging wires one by one and adhering them in a plate shape with an adhesive, and are accommodated in a state of being wound in a needle cartridge 442. The needle striking portion 443 includes a needle feed member 535, a needle cutting member 536, and a needle bending member 537 on the bracket 450, and the support shaft 44.
It can be rotated about 6 as a fulcrum. By rotating the staple striking portion 443 in the clockwise direction in FIG. 29 about the spindle 446 as a fulcrum, the staples 603 are cut / separated one by one, bent into a U-shape, and hammered into a sheet bundle. The needle feed member 535 rotates intermittently in conjunction with this needle striking operation,
The staples 603 are fed one pitch at a time. The staple striking portion 443 has a sensor (not shown) for detecting the presence or absence of the staple 603 in the staple cartridge 442.

Further, the staple striking portion 443 is provided with the paper pressing members 479 on both sides, and in synchronization with the staple striking operation, and at a timing slightly earlier than the time when the staple needle 603 comes into contact with the sheet bundle, The sheet bundle inserted between 443 and the staple receiving portion 444 is pressed to prevent the sheet bundle from being displaced. The paper pressing member 479 is a support shaft 552.
It is rotatable about a fulcrum and is pressed against a cam 551 rotated by a needle driving motor (not shown) by a spring 553. Based on the rotation of the cam 551, the bundle of sheets is pinched between the staple receiving portion 444 and the sheet bundle. After the needle is hit and the needle is hit, the needle moves backward in synchronization with the needle hit part 443. In addition, the needle striking portion 443
The drive function of is well known and its detailed description is omitted.

The staple receiving portion 444 includes a staple receiving member 448 for bending the staple staple 603 punched out of the sheet bundle inward, and a support plate 449 for reducing the impact of the staple driving portion 443 during the staple driving operation. It is configured.

(Connecting part) The connecting part 445 is composed of first and second support plates 451 and 453. First support plate 4
Reference numeral 51 is installed integrally with the bracket 450 of the needle striking portion 443. The second support plate 453 has the needle receiving portion 444 attached to the front end, and the rear end is connected to the first support plate 451 via the support shaft 452.

Further, as shown in FIG. 32, in the connecting portion 445, the connecting portion 452a by the support shaft 452, the stapling portion 443 and the staple receiving portion 444 are arranged in a direction orthogonal to the sheet bundle conveying direction (arrow h). They are arranged in a staggered manner. FIG.
The position H indicated by the solid line is the home position of the staple unit 441. In this home position H, the connecting portion 452a is located outside the sheet passing path, and the staple striking portion 443 and the staple receiving portion 444 are the corner portions of the sheet bundle. It is set at the position to bind.

As shown in FIG. 24, the distance L ₅ between the support shaft 452 and the staple position X is set to be slightly longer than 1/2 of the maximum sheet passing length (corresponding to A3T size), and is conveyed to the staple unit 440. Not only the process of binding the leading end of the sheet bundle but also the process of binding the central portion of the sheet bundle is possible. Further, if the sheet bundle has a length that is ½ or less of the maximum sheet-passing size, the process of binding the rear end of this sheet bundle is possible. In the case of the trailing edge binding mode, since the stacking tray 411 is empty during the stapling process, it is possible to immediately start accommodating the next set of sheets in the tray 411, and efficiently execute the copy / stapling process as a whole. It becomes possible.

The distance L ₆ between the staple position X and the leading end stopper 412 is set longer than the distance L ₇ between the staple position X and the trailing edge of the sheet fed to the staple portion 440 at this time. This prevents the stopper 412 from interfering with the trailing edge of the sheet when binding the trailing edge of the sheet.

(Movement Unit of Staple Unit) The unit movement unit 454 reciprocates the staple unit 441 in the direction (arrow i) orthogonal to the sheet bundle conveyance direction h in order to drive the staples into the sheet bundle at a plurality of positions. It is for. This moving unit 454 is shown in FIGS.
As shown in FIG. 5, a spiral shaft 455 provided orthogonal to the transport direction h, and a forward / reverse rotatable motor M that is a drive source.
4 and a drive transmission unit (not shown) that transmits the rotation of the motor M4 to the spiral shaft 455. The bracket 450 of the staple unit 441 is screwed to the spiral shaft 455, and moves in the arrow i direction and the opposite direction based on the forward / reverse rotation of the spiral shaft 455. The spiral shaft 455 extends over the maximum width of sheet passing (corresponding to A3T and A4Y), and the front side (left side in FIG. 32) extends to the vicinity of the exterior frame 458.
Sensors SE15 and SE16 are installed on a frame 460 that supports the spiral shaft 455, and a light shielding plate 463 attached to the bracket 450 of the staple unit 441 can move forward and backward along the optical axes of the sensors SE15 and SE16. The fact that the staple unit 441 is at the home position H shown by the solid line in FIG. 32 is detected by the light shielding plate 463 entering the optical axis of the sensor SE15. Further, the staple unit 441 is further on the front side (left side).
When moved to, the light shielding plate 463 enters the optical axis of the sensor SE16. This position is the staple needle replacement position, and the operator can replace the staple cartridge 442 by opening the small door 459 of the exterior frame 458.

Further, a disc 464 having a large number of notches regularly formed in the peripheral portion is fixed to the output shaft of the motor M4, and the sensor SE17 detects the notches based on the rotation of the disc 464. Then, a pulse signal is generated. The movement amount of the staple unit 441 can be detected by counting the number of pulses output from the sensor SE17, and the motor M4 is turned off at the time when the predetermined number of pulses are counted, so that the staple unit 44 is
It is possible to accurately control the movement amount of 1, that is, the staple position. The stapling position (stop position) will be described later. The return of the staple unit 441 to the home position H and the movement to the staple replacement position are detected by the detection signals from the sensors SE15 and SE16,
The drive of the motor M4 is turned off by this detection signal.

(Staple Mode) Basically, three kinds of staple modes can be set. The first mode is a process of binding the leading end of the sheet bundle in the transport direction, and is further divided into a mode of binding the corner and a mode of binding a plurality of positions of the leading end. The second mode is a process of binding the rear end portion of the sheet bundle in the transport direction, and is further divided into a mode of binding the corner portion and a mode of binding multiple portions of the rear end portion. The third mode is a process of binding the central portion of the sheet bundle at a plurality of places.

The movement of the staple unit 441 during the staple mode processing will be described later.

(Sheet Bundle Conveying Section) As shown in FIG. 33, the conveying section 465 includes a guide plate 466 fixed to the inside of the supporting plate 451 and a support shaft 452 inside the supporting plate 453.
Guide plate 468 rotatably mounted about the fulcrum
And a conveying roller 46 that is driven to rotate in the sheet bundle conveying direction.
9, 470 and a sensor SE18 for detecting a sheet,
It consists of SE19. The conveying roller 469 can be brought into contact with and separated from the conveying roller 470 by a solenoid (not shown). When the sheet bundle is carried in by the first chuck means 415, the conveying roller 469 is separated from the conveying roller 470 and receives the sheet bundle, and thereafter. The sheet bundle is pinched with the transport roller 470 and transported.

The bundle of sheets conveyed by the conveying section 465 is
The paper is sent to the above-described carrying path 52, and is sent out to the storage tray 475 while being decelerated from the discharging roller pair 524 through the carrying roller pair 474.

(Leading Edge Binding Mode) This is a mode for binding the leading edge of the sheet bundle. When binding the corner portion, as shown by the chain double-dashed line in FIG. 34, the staple unit 441 moves to the staple position R ₀ before the sheet bundle reaches the staple portion 440. At this time, the staple unit 4
41 slightly passes the staple position R _0, and then stop the staple position R ₀ by returning to the stapling position R _0.

After the binding operation for the bundle of sheets is completed, the staple unit 441 returns to the home position H. The sheet bundle is maintained in a state of being gripped by the first chucking unit 415, is transported in the direction of arrow h by the first chucking unit 415, and is delivered to the transport rollers 469 and 470. By the way, the staple unit 440 has the following configuration so that the connecting unit 445 does not interfere with the leading end P _{L of the} sheet bundle.

L ₁₁ / V ₁ <L ₁₂ / V ₂ V ₁ : moving speed of stapling unit V ₂ : conveying speed of sheet bundle L ₁₁ : distance from R ₀ to H L ₁₂ : from tip of sheet bundle to connecting portion On the other hand, when binding at multiple locations, as shown in FIG.
First, the stapling unit 441 measures the staple position R ₁ before the leading edge P _{L of the} sheet bundle reaches the stapling section 440.
Move to. At this time, the staple unit 441 starts moving from the home position H, after passing through the position R ₁ slightly returns to the position R _1. After the stapling operation at the position R ₁ , the stapling unit 441 temporarily stops at the stapling positions R ₂ and R _n , executes the stapling operation, and returns to the home position H. The conveyance of the sheet bundle after the stapling process is the same as in the corner stapling mode.

The stapling section 440 has the following structure so that the connecting section 445 does not interfere with the leading edge P _{L of} the sheet bundle. L ₁₃ / V ₁ <L ₁₂ / V ₂ L ₁₃ : Distance from R _n to H By the way, in this embodiment, the sheet bundle is configured to pass through the inside of the staple unit 441, and the stapling unit 4
If 43 and the needle receiving portion 444 are completely separated, it becomes extremely difficult to align the needle striking portion 443 and the needle receiving portion 444. Therefore, in the present embodiment, both of them are connected and integrated by the support plates 451 and 453 along the conveyance path of the sheet bundle,
The position can be surely aligned to prevent needle-punching mistakes. Then, in the leading edge binding mode, the staple unit 441 is moved to the furthest staple position R ₀ or R ₁ from the home position H before the arrival of the sheet bundle, and the staple unit R 441 is moved from a position far from the home position H to a position close to the home position H. By performing the stapling operation, the time required for the stapling process can be shortened. Further, since the connecting portion 445 of the staple unit 441 is detached outward from the side portion of the sheet bundle, the timing of disclosing the conveyance of the sheet bundle can be advanced. Moreover, even at the home position H, the binding operation can be executed without moving the staple unit 441, and the conveyance of the sheet bundle can be started immediately after the binding operation.

(Rear end binding mode) This is a mode for binding the rear end of the sheet bundle. The sheet bundle is the first chuck means 415.
It is carried to the carrying rollers 469, 470 by the carrying rollers 469, 470. The rotation of the transport rollers 469 and 470 is stopped when the trailing edge of the sheet bundle reaches the staple position X after the leading edge of the sheet bundle is detected by the sensor SE19.

When binding the corner portion, as shown in FIG. 36, the staple unit 441 performs the binding operation without moving from the home position H. On the other hand, when binding at a plurality of positions, as shown in FIG. 37, the staple unit 441 first moves to the staple position R ₁ (movement mode is the same as the leading edge binding mode), performs the binding operation, and then staples the position R. _{At 2} , R _n , the binding operation is performed while temporarily stopping, and the home position H is restored.

After the stapling process, when the waiting time T corresponding to the size of the sheet bundle elapses, the conveying rollers 469,
By restarting the rotation of 470, the staple portion 44
It is sent out from 0. The waiting time is calculated by the control unit such that (L ₁₂ / V ₂ ) + T> L ₁₃ / V ₁ . Note that the distance L
See FIG. 37 for ₁₂ and L ₁₃ .

(Saddle stitching mode) This is a mode in which the central portion of the sheet bundle is bound at a plurality of locations. The sheet bundle is conveyed to the conveying rollers 469 and 470 by the first chuck means 415, and further conveyed by the conveying rollers 469 and 470. The rotation of the conveying rollers 469 and 470 is stopped when the central portion reaches the staple position X in accordance with the sheet size after the leading edge of the sheet bundle is detected by the sensor SE19.

The movement of the staple unit 441 is shown in FIG.
Is the same as the movement mode shown in FIGS. 35 and 37. Further, the waiting time T until the conveyance of the bundle of sheets by the conveyance rollers 469 and 470 is restarted after the stapling process is also calculated by the control unit so that (L ₁₂ / V ₂ ) + T> L ₁₃ / V ₁ is satisfied. . (Staple Position and Shape of Guide Plate) In the stapling process described above, the staple position orthogonal to the transport direction can be arbitrarily set by controlling the on / off of the motor M4. However, normally, the staple position is preset in accordance with the staple mode and the paper size.

FIG. 39 shows the stapling positions for the laterally-passing sheets when the stapling process is performed on one-sided basis for sheets of all sizes. Or binding the corner portion of the x ₁ or x ₄ is at the tip stapling mode, binding the two places x _2, x _3. Or binding the corner portion of the x ₅ or x ₈ in the rear end binding mode, binding the two places x _6, x _7. X in saddle stitch mode
Binding the two places of _9, x _10.

The guide plates 466 and 468 have a large number of recesses 466a and 468a, as shown in FIG.
The recesses 466a, 468a correspond to the stapling position x ₁ ~x ₁₀ shown in FIG. 39, the staple in transporting the sheet bundle stapled guide plates 466, 468
To prevent contact with. This is because if the staples come into contact with the guide plates 466 and 468, conveyance defects / impossible such as skew of the sheet bundle and paper jam will occur.

On the other hand, in FIG. 41, the sheets are aligned on the stacking tray 411 with the central reference and sent to the staple section 440.
The stapling position when performing the stapling process is shown. Corresponding to this, recesses 466a and 468a are formed in the guide plates 466 and 468 as shown in FIG. Further, the transport rollers 469 and 470 are also at the staple position x.
_It goes without saying that they are arranged off the conveyance locus of _{1 to} x ₁₀ (see FIG. 37).

(Paper-Passing Form in Various Processing Modes) Next, the paper-passing forms in various processing modes (non-sort mode, paper folding mode, staple mode) by the finisher 40 will be described.

(Paper-Passing Form in Non-Sort Mode) In the non-sort mode, paper is discharged / stacked on the non-sort tray 401. In the non-sort mode, the switching claws 511 and 521 are set so that the paper advances along the transport path 50. Paper P ₁ discharged from the copying machine 10
(The image forming surface is directed upward) is guided to the conveyance path 48 (see FIG. 43), and after being conveyed to the conveyance path 49, the rollers 491 and 492 are switched back by rotating the conveyance path 50. (See FIGS. 44 and 45).
Next, the second sheet P ₂ discharged from the copying machine 10 is also guided to the transport path 48 (see FIG. 45). First sheet P ₁
Is conveyed upward in the conveying path 50 as it is, and the second sheet P ₂ is switched back in the conveying path 49 and sent to the conveying path 50 (see FIG. 46). Next, the paper P ₁ is discharged from the discharge roller pair 505 onto the non-sort tray 401 with the image forming surface facing downward while being decelerated (FIGS. 47 and 4).
8). Furthermore, the paper P _{2 is} also discharged from the discharge roller pair 505 onto the non-sort tray 401 with the image forming surface facing downward while being decelerated (see FIGS. 49 and 50).

(Non-sort mode, sheet-passing mode for large-volume sheet discharge) There is a limit to the amount of sheets that can be stacked on the non-sort tray 401. Therefore, in this embodiment, when the non-sort tray 401 becomes full, the subsequent sheets are accommodated in the tray 475 of the storage section 46.
To be discharged. That is, as shown in FIG. 51, the sheets P _{1 to} P _n-1 are discharged onto the non-sort tray 401,
The next paper P _n is conveyed through the conveyance path 50, and further paper P _{n + 1}
Is on the transport path 49. The non-sort tray 401 becomes full when the paper P _n is discharged. Whether it is full or not is determined by reading the count value of the copy number counter in the control unit of the copying machine 10. In this case, when the trailing edge of the sheet P _n passes through the branch point of the transport paths 50 and 52 (detection of the trailing edge of the sheet by the sensor SE3), the switching claw 521 is driven to transport the sheet to the transport path 52. Switch the route.

The sheet P _n is conveyed through the conveying path 50 and discharged onto the non-sort tray 401, and the sheet P _{n + 1} is sent to the conveying path 52 by the switching claw 521, and the image is discharged from the pair of discharging rollers 524 onto the tray 475. The sheet is discharged with the forming surface facing downward (see FIGS. 52 and 53). The next paper P _{n + 2} is also sent from the transport path 48 to the transport path 52 via the transport path 49, and is discharged / stacked on the tray 475 (FIGS. 53 to 5).
6). As described above, the tray 475 is lowered step by step as the stacking amount of sheets increases.

(Non-sort Mode, Sheet-Passing Form in Different Size Paper Mixed Loading) Next, a case will be described in which sheets of different sizes are discharged to the non-sort tray 401. Here, the copy original is A4Y size (Y means the case where the short side of the original or paper is parallel to the transport direction) and A3T.
A case where each size (T means the case where the long side of the original or paper is parallel to the transport direction) and the number of copies is 1 will be described.

An image inversion process is performed on the _first sheet of A4Y size paper P ₁ by the control unit of the copying machine 10, and the paper passing form is the same as the paper P ₁ shown in FIGS. 43 to 48. Copying machine 1 for the _second A3T size paper P ₂
The image reversal process is performed by the control unit of 0, and the sheet is discharged onto the non-sort tray 401 through the same conveyance path as the sheet P ₁ . The state where the two sheets of paper P ₁ and P ₂ are accommodated on the tray 401 is as shown in FIG. 57. By performing the image inversion process, images of different sizes are aligned in the stacked state on the tray 401. Like

(Paper Passing State in Non-Sort / Z-Fold Mode) The process of Z-folding the sheet carried into the finisher 40 is as shown in FIGS. 6 to 9, and the Z-folded sheet P is The image forming surface is faced down and discharged onto the non-sort tray 401 and stacked (see FIG. 58).

(Paper-passing Form in Non-Sort / Half-Fold Mode) The process of bi-folding the sheet carried into the finisher 40 is as shown in FIGS. 10, 11 and 12, and the non-sort tray 401 The sheet P folded in half above is discharged and stacked with the fold line facing the upstream side in the discharge direction (see FIG. 59).

(Paper passing form in the leading edge binding mode)
Creates two sets of copies from two originals
A case of performing the same will be described. First set of paper P₁, P₂But
43 to 4 are conveyed on the conveying paths 48, 49 and 50.
6 and the paper P₁, P₂Is the switching claw 52
1 is guided to the conveyance path 51, and the discharge roller pair 513
Is discharged onto the stacking tray 411 while being decelerated by
(See FIGS. 60-63). Second set of first sheet
P₁'Is the final sheet P of the first set₂Followed by paper P₁,
P₂Copy processing is performed at the same interval as and is sent to the transport path 48.
(See FIG. 60). This paper P₁'Is the transport path 49
Be conveyed to the paper folding mechanism 30 and not folded.
Paper (see FIGS. 61, 62, 15 to 17)
See). In addition, the second sheet P of the second set₂’The above paper
P₁, P ₂, P₁’The copy process is performed at the same interval as
48 (see FIG. 61). Paper P₁'Is the third
Switch back on the fourth transport path 34 through the transport path 33.
And conveyed upward, and the paper P₂'Switches on the transport path 49
It is backed up and moves toward the transport path 50 (see FIG. 62).

[0093] As described above, the reference fourth transport path 34 'P ₂ conveyed through the conveyance path 50 and' conveyed sheet P ₁ has a tip is superimposed confluence of the two conveying paths (FIG. 63 ). At this time, the image forming surfaces of the sheets P ₁ ′ and P ₂ ′ are both facing the left side in FIG. 63. After that, the sheets P ₁ ′ and P ₂ ′ are overlapped with each other and are conveyed to the conveyance paths 50 and 51.
Are transported (see FIG. 64).

On the other hand, the first set of sheets P ₁ and P _{2 that} have already been discharged / aligned on the stacking tray 411 are sent to the stapling section 440 by the first chuck means 415, and stapled by the stapling unit 441. Is performed (see FIG. 65). At this time, the second set of sheets P ₁ ′ and P ₂ ′ also reach the discharge roller pair 513. After the stapling process is completed, the sheets P ₁ and P ₂ are fed to the first chuck means 4
15 and the transport rollers 469 and 470.
5 is conveyed and sent to the storage tray 475 through the conveyance path 52 (see FIGS. 66 to 68).

The second set of papers P ₁ ′ and P ₂ ′ are discharged / aligned on the stacking tray 411 while the previous papers P ₁ and P ₂ are being conveyed by the conveying section 465 (see FIG. 66), and the first chuck Means 4
It is sent to the staple unit 440 by 15 (see FIG. 67).
(See FIG. 68), the stapling unit 441 performs stapling processing (see FIG. 68). After that, the paper P ₁ ',
P ₂ ′ is transported through the transport unit 465 (see FIG. 69) and sent to the storage tray 475 through the transport path 52 (see FIG. 7).
0, see FIG. 71).

As described above, when a plurality of copies are processed in the leading edge binding mode, the first sheet of each set after the second set is diverted from the sheet folding mechanism 30 and the second sheet is set in the middle of the conveyance path 50. Since the sheets are merged / overlapped with the sheet of No. 3, even if the sheet bundle of the previous set is positioned on the stacking tray 411 during the stapling process, it is not necessary to wait for the copying process by the copying machine 10 and the entire copy is performed. / The staple processing time can be shortened.

(Paper-Passing Form in Rear End Stitching Mode) Similar to the front end stapling mode, a case will be described in which two sets of copies are made from two originals and rear end binding is performed. The mode in which the first set of papers P ₁ and P ₂ are conveyed in the finisher 40 is the same as in the leading edge binding mode, and the second set of papers P ₁ ′ and P ₂ ′ are overlapped and conveyed in the conveyance path 50. This is also the case (see FIGS. 60 to 64).

The first set of papers P ₁ and P ₂ previously discharged / aligned on the stacking tray 411 are the first chuck means 415.
Is fed to the stapling section 440 by the conveying rollers 469 and 470, and is temporarily stopped when the trailing ends of the sheets P ₁ and P ₂ reach the stapling position, and the stapling unit 441 performs stapling processing (see FIG. 72). ). At this time, since the stacking tray 411 is empty, the second set of sheets P ₁ ′ and P ₂ ′ are discharged / aligned on the tray 411. After stapling,
The papers P ₁ and P ₂ are transported by the transport rollers 469 and 470 in the transport unit 465 (see FIG. 73) and are sent to the storage tray 475 through the transport path 52 (see FIG. 74).

When the _first set of papers P ₁ and P ₂ are carried out from the carrying section 465, the trailing ends of the second set of papers P ₁ ′ and P ₂ ′ are moved by the first chuck means 415 and the carrying rollers 469 and 470. The sheets are conveyed until they reach the staple position, and staple processing is performed by the staple unit 441 (see FIG. 74). After the stapling process is completed, the papers P ₁ ′ and P ₂ ′ are transported by the transport rollers 469 and 470 in the transport unit 465 (see FIG. 75) and are sent to the storage tray 475 through the transport path 52 (see FIG. 76).

(Sheet passing mode in Z-folding / trailing edge binding mode)
The paper passing form when Z-folding the paper is as shown in FIGS. 6 to 9, and after the Z-folding process, the paper is discharged from the conveying path 51 onto the stacking tray 411, and the predetermined number of papers P ₁ to P _n
Are accommodated / aligned on the tray 411 (see FIG. 77).
The Z-folded sheets P _{1 to} P _n are sent to the stapling section 440 by the first chucking means 415, further conveyed by the conveying rollers 469 and 470, and temporarily stopped when the trailing edge of the sheet reaches the stapling position. Staple processing is performed by the staple unit 441 (see FIG. 78). After the stapling process is completed, the paper sheets P _{1 to} P _n
Is transported through the transport unit 465 and the transport path 52 by the transport rollers 469 and 470 and the transport roller pair 474 (see FIG. 79).
(See FIG. 80), and is sent to the storage tray 475 (see FIG. 80).

(Paper-passing Mode in Half-Fold Mode / Tail-End Stitching Mode) The sheet-passing mode when folding a sheet in two is shown in FIG.
As shown in FIGS. 11 and 12, after the folding process, the sheet is discharged from the transport path 51 onto the stacking tray 411, and a predetermined number of sheets P _{1 to} P _n are accommodated in the tray 411.
Aligned (see Figure 81). Half-folded paper P ₁ ~
P _n is supplied to the staple unit 4 by the first chuck means 415.
When the trailing edge of the sheet reaches the stapling position, the sheet is temporarily stopped, and the stapling unit 441 performs stapling processing (see FIG. 82). After the stapling process is completed, the sheets P _{1 to} P _n are conveyed by the transport rollers 469, 4
The conveyance tray 465 and the conveyance roller pair 474 convey the conveyance section 465 and the conveyance path 52 (see FIG. 83).
5 (see FIG. 84).

(Rear-End Binding Mode, Paper-Passing Form with Different Size Papers Mixed) Here, the case where the copy originals are A4Y and A3T each and the number of copies is one will be described. In this case, A
The 3T paper is Z-folded to match the size of A4Y. The first sheet (A4Y) P ₁ is the transport path 4
It is switched back at 9 and conveyed along the conveyance path 50 (see FIG. 8).
5, FIG. 86, FIG. 87), and is discharged onto the stacking tray 411 from the transport path 51 (see FIGS. 88, 89). The second sheet (A3T) P ₂ is carried into the conveyance path 48 after the sheet P ₁ , and is Z-folded by the sheet folding mechanism 30 (see FIGS. 85 to 88).
(Refer to FIG. 89). After that, the Z-folded paper P ₂ is ejected from the transport path 51 onto the stacking tray 411 and is aligned with the paper P ₁ (FIG. 9).
0, see FIG. 91). Next, the sheets P ₁ and P ₂ are sent to the stapling section 440 by the first chuck means 415,
Further, the sheet is conveyed by the conveying rollers 469 and 470, and is temporarily stopped when the trailing edge of the sheet reaches the staple position (see FIG. 92). Here, the stapling process is performed on the rear end portions of the sheets P ₁ and P ₂ . After the stapling process is completed, the sheets P ₁ and P ₂ are transported by the transport rollers 469 and 470 and the transport roller pair 474 through the transport unit 465 and the transport path 52 (see FIG. 93) and are sent to the storage tray 475 (see FIG. 94). .

(Saddle Stitching Mode) The sheet carried into the finisher 40 is scored by the sheet folding mechanism 30. The creasing process is as shown in FIGS. 13 and 14, and the first sheet of paper P ₁ is discharged / aligned on the stacking tray 411 in a state where the center part is creased (FIG. 9).
5). At this time, the second sheet of paper P ₂ also has the paper folding mechanism 3
A crease is made at 0, and the sheet reaches the conveyance path 50. Further, the paper P ₂ is discharged / aligned on the stacking tray 411 through the transport path 51 (see FIGS. 96 and 97).

Next, the sheets P ₁ and P ₂ are transferred to the first chuck means 4
The sheet 15 is fed to the staple unit 440, further conveyed by the conveying rollers 469 and 470, and temporarily stopped when the central portion of the sheet reaches the staple position (see FIG. 98). Here, the stapling process is performed on the creases of the sheets P ₁ and P ₂ . After the stapling process is completed, the sheets P ₁ and P ₂ are transported by the transport rollers 469 and 470 and the transport roller pair 474 through the transport unit 465 and the transport path 52 (see FIG. 99) and are sent to the storage tray 475 (see FIG. 100). .

(Finishing of Copy) Next, the finished state of copy according to the present embodiment will be described. First, AD
With respect to F20, as shown in FIG. 101, the document D is set on the paper feed tray 21 with the image facing upward and the staple position on the left side. In the case of corner binding, the operator selects which of the corner portions v and w of the document D is to be bound. The document D is set by the ADF 20 on the platen glass of the copying machine 10 with the image facing downward as shown in FIG. At this time, the leading edge of the document D is scale 1
By touching 01, the exposure position is set.

The copy finish in the paper size and processing mode is as follows. When a small-sized document is placed horizontally on the platen glass with respect to the scale 101 (a state in which the short side of the document is orthogonal to the scale 101), the state when the copying machine 10 ejects the stacking tray 41.
1 and the state when the sheets are stapled and stored in the storage tray 475 as shown in FIG.
The state shown in 03 is obtained. At this time, the control unit of the copying machine 10 forms an image on the sheet without performing the image inversion process, and binds the rear end of the sheet bundle stored on the stacking tray 411. It should be noted that FIG. 103A shows the case where the document is written vertically, and FIG. 103B shows the case where the document is written horizontally.

A small-sized original is placed vertically on the platen glass with respect to the scale 101 (the long side of the original is the scale 10).
1 (orthogonal to 1), each process step and finish are in the state shown in FIG. 104 (a). Also,
Each step and finish of processing a large-sized document (in this case, vertically placed) are in the state shown in FIG. 104 (b). In both cases, the control unit of the copying machine 10 reverses the image and binds the leading end of the sheet bundle stored on the stacking tray 411.

Each step and finish in the case of Z-folding a sheet are as shown in FIG. 104 (c). At this time, the image inversion process is not performed, and the rear end of the sheet bundle is bound. For saddle stitch mode, when there are n sheets of documents, as shown in FIG. 105, the image D _n is the first sheet of the surface of the sheet P _1, D ₁ are formed, the image D _n on the back _-1 , D ₂ is formed. Further, images D _n-2 and D ₃ are formed on the front surface of the _second sheet of paper P ₂ , and image D _n is formed on the back surface.
_n-3 and D ₄ are formed. Hereinafter, an image is formed by the same procedure.

The sheets P ₁ and P ₂ on which the images have been combined and which have been copied on both sides are folded at the central portion by the sheet folding mechanism 30 and discharged / aligned on the accumulating tray 411, and the stapling process is performed on the folds. (See FIGS. 95 to 100). When the number of originals is 8, the finished product is in the state shown in FIG. In the case of the bag binding mode, as shown in FIG.
Images D ₁ and D ₂ are on the _first sheet P ₁ , images D ₃ and D ₄ are on the _second sheet P _2, and similarly, two images are on the sheet in page order from the copying machine 10. It is formed with the top and bottom reversed during the discharge of. The sheets P ₁ and P ₂ are folded in _two by the sheet folding mechanism 30, discharged / aligned on the stacking tray 411, and stapled at the rear end (see FIGS. 77 to 80). If the number of originals is four, the document will be finished in the state shown in FIG.

(Control Unit) FIG. 109 shows a control unit of the copying system, which is mainly composed of a CPU 201 for controlling the copying machine 10 and a CPU 202 for controlling the finisher 40. CPU 202 is a ROM 2 storing control information
03, the control signal is output to loads such as various motors and solenoids, while the detection signal from a detection unit such as a sheet detection sensor is input.

110 and 111 show the memory unit section 250 and the image signal processing section 2 in the control section of the copying machine 10.
The structure of 65 is shown. In the memory mode copy in which the image read by scanning the original is temporarily stored, the binarization processing unit 252 of the memory unit unit 250 includes an 8-bit image from the image signal processing unit 265 via the bus switching unit 251. The data D2 is input. The binarization processing unit 252 performs a process of converting the multicolor image data D2 into binary image data within a recoverable range by, for example, the dither method. The binarized image data is once written in the image memory 253. The image signal processing unit 265 converts the document image read by the image sensor (CCD) into a digital signal and transfers the digital signal to the memory unit unit 250.

The code processing unit 254 reads the image data written in the image memory 253 and compresses it to generate code data (compressed data).
Write to 58. Further, the code processing unit 254 reads the code data to be printed from the code memory 258 and decompresses it, and writes the obtained image data in the image memory 253. The compressor 256 and the decompressor 257 forming the code processing unit 254 are configured to be operable independently of each other and in parallel in order to improve the copy speed, and between them and the code memory 258. Data is DMA-transferred by a DMA controller (not shown).

When the image data for one page is reproduced by decompression, the data is read from the image memory 253, subjected to the image inversion processing by the inversion processing unit 259 as necessary, and then subjected to the multi-valued processing. The unit 260 restores the multivalued image data. Then, the multi-valued image data is transferred to the print processing unit as exposure control data. When temporarily storing such a document image, the code memory 258 is a RAM 262 of the CPU 261 dedicated to the memory unit section 250.
It is managed by a management table MT1 provided therein.

FIG. 112 shows the relationship between the management table MT1 and the code memory 258. The code memory 258 is 32K
The memory area is divided into byte units, and in consideration of enabling simultaneous control of writing (reading) and reading (printing), code data for each page is stored in each area. . In the management table MT1, a number indicating an area of the code memory 258, a page number (original image number) PN of image data given in a writing order (original scanning order), a number of a concatenated area, and a compression method. Also, various additional information necessary for compression / expansion processing such as data length is stored, and the code memory 258 is dynamically managed based on these information.

[0115] "Pre-concatenation" in Fig. 112 (a) shows the connection in the forward direction of the area of every 32 Kbytes in each page. When this is "00", the data for one page is shown. Indicates that it is the first storage area, and if it is other than "00", it indicates the number of the area that is connected to it. Similarly, "post-connection" indicates the last area when it is "FF", and indicates the number of the area which is connected later when it is other than "FF".

When the CPU 261 reads out the image data from the image memory 253 and compresses it, the management table MT
While creating the information of 1, the compressor 256 is controlled and stored in the code memory 258. Further, when outputting the image data, the code data is read from the code memory 258 by the reverse operation. The information in the management table MT1 is erased when the information of the corresponding page is normally read and copying of the number of copies designated by the operator is completed.

(Judgment of Image Reversal) In this embodiment, the image reversal process is performed in correspondence with the processing mode and the direction of the paper in order to align the copy image and the staple position when the staple mode is executed. FIG. 113 shows a control procedure for determining whether or not to perform the image inversion process. Here, first, step S1
When it is confirmed that the bag binding mode or the Z-folding mode is selected, the rear end binding is performed in this case, so an instruction not to invert the image is issued in step S2. If the mode is other than the bag binding or folding mode, it is determined in step S3 whether or not the paper is vertically passed. If the paper is passed vertically, the leading end is bound, and therefore, an instruction to invert the image is issued in step S4. Since the trailing edge is bound if the paper is passed horizontally, an instruction not to invert the image is issued in step S5.

In the present embodiment, the maximum paper passing size is set to A3T, and the A4Y size can be carried in the stapling section 440. In the present invention, the large size and the small size are the sheet lengths in the sheet passing direction, and if explained in connection with the embodiment, A4Y and B5Y are the small sizes, and sheets of this size (when folded) (Including) is not necessary when the trailing edge is bound. On the other hand, A4
Except for Y and B5Y, the sizes are large (including mixed sizes), and it is necessary to invert the image when binding the leading edge.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a copying system including a finisher according to the present invention.

FIG. 2 is a schematic configuration diagram showing the finisher.

FIG. 3 is an elevational view showing a conveyance path in the finisher.

FIG. 4 is an elevation view showing another transport path in the finisher.

FIG. 5 is a perspective view showing an appearance of the finisher.

FIG. 6 is an elevation view illustrating an operation of a paper folding mechanism (Z-folding mode).

FIG. 7 is an elevation view illustrating the operation of a paper folding mechanism (Z-folding mode).

FIG. 8 is an elevation view illustrating the operation of the paper folding mechanism (Z-folding mode).

FIG. 9 is an elevation view illustrating the operation of the paper folding mechanism (half-fold mode).

FIG. 10 is an elevation view for explaining the operation of the paper folding mechanism (half-fold mode).

FIG. 11 is an elevation view for explaining the operation of the paper folding mechanism (half-fold mode).

FIG. 12 is an elevational view for explaining the operation of the paper folding mechanism (half-fold mode).

FIG. 13 is an elevational view for explaining the operation of the paper folding mechanism (crease mode).

FIG. 14 is an elevation view for explaining the operation of the paper folding mechanism (crease mode).

FIG. 15 is an elevation view for explaining the operation of the paper folding mechanism (paper passing mode).

FIG. 16 is an elevation view for explaining the operation of the paper folding mechanism (paper passing mode).

FIG. 17 is an elevation view illustrating the operation of the paper folding mechanism (paper passing mode).

FIG. 18 is an explanatory diagram showing a Z-folded sheet and a discharge state onto a tray.

FIG. 19 is a front view showing a staple processing unit.

FIG. 20 is a plan view showing a stacking tray.

FIG. 21 is a sectional view showing a stacking tray.

FIG. 22 is a front view showing the first chuck means.

FIG. 23 is a side view showing the first chuck means.

FIG. 24 is a partial cross-sectional view showing a staple processing unit.

FIG. 25 is a partial cross-sectional view showing the operation (during regulation) of the tip stopper.

FIG. 26 is a partial cross-sectional view showing the operation of the tip stopper (when the regulation is released).

FIG. 27 is a front view showing second chuck means.

FIG. 28 is a side view showing the second chuck means.

FIG. 29 is a front view showing a staple unit.

FIG. 30 is a front view showing the internal structure of the staple unit.

FIG. 31 is a view on arrow Y of FIG. 29.

FIG. 32 is an explanatory diagram showing a moving state of the staple unit.

FIG. 33 is a partial cross-sectional view showing a sheet bundle transport unit.

FIG. 34 is an explanatory diagram showing leading edge corner binding processing.

FIG. 35 is an explanatory diagram showing leading edge multiple binding processing.

FIG. 36 is an explanatory diagram showing a trailing edge corner binding process.

FIG. 37 is an explanatory diagram showing a trailing edge multiple binding process.

FIG. 38 is an explanatory diagram showing saddle stitching processing.

FIG. 39 is an explanatory view showing stapling points for various types of paper, showing a case of one-side reference paper passing.

FIG. 40 is an explanatory diagram of a guide plate of the sheet bundle conveying unit, showing a case of one-side reference sheet passing.

FIG. 41 is an explanatory view showing stapling points for various sheets, showing a case of central reference sheet passing.

FIG. 42 is an explanatory view of a guide plate of the sheet bundle transporting section, showing a case of central reference sheet passing.

FIG. 43 is an explanatory diagram showing a sheet passing form in a non-sort mode.

FIG. 44 is an explanatory diagram showing a sheet passing form in the non-sort mode, continued from FIG. 43.

FIG. 45 is an explanatory diagram showing a sheet passing form in a non-sort mode, continued from FIG. 44.

FIG. 46 is an explanatory diagram showing the sheet passing form in the non-sort mode, continued from FIG. 45.

FIG. 47 is an explanatory diagram showing a sheet passing form in the non-sort mode, continued from FIG. 46.

FIG. 48 is an explanatory diagram showing a sheet passing form in a non-sort mode, continued from FIG. 47.

FIG. 49 is an explanatory diagram showing a sheet passing form in the non-sort mode, continued from FIG. 48.

FIG. 50 is an explanatory diagram showing the sheet passing form in the non-sort mode, continued from FIG. 49.

FIG. 51 is an explanatory diagram showing a sheet passing form in a non-sort mode and a large amount of paper.

52 is an explanatory diagram showing a sheet passing mode in a non-sort mode and a large amount of sheets, continued from FIG. 51.

FIG. 53 is an explanatory diagram showing a sheet passing mode in a non-sort mode and a large amount of sheets, continued from FIG. 52.

FIG. 54 is an explanatory diagram showing a sheet passing mode in non-sort mode and large-volume sheet discharging, following FIG. 53.

FIG. 55 is an explanatory diagram showing a sheet passing mode in non-sort mode and large-volume sheet discharging, continued from FIG. 54.

FIG. 56 is an explanatory diagram showing a sheet passing mode in non-sort mode and large-volume sheet discharging, continued from FIG. 55.

FIG. 57 is an explanatory diagram showing a sheet passing form in a non-sort mode and mixed size sheets.

FIG. 58 is an explanatory diagram showing a sheet passing form in a non-sort / Z-fold mode.

FIG. 59 is an explanatory diagram showing a sheet passing form in a non-sort / half-fold mode.

FIG. 60 is an explanatory diagram showing a sheet passing form in the leading edge binding mode.

FIG. 61 is an explanatory diagram showing a sheet passing form in the leading edge binding mode;
Continuation of FIG. 60.

FIG. 62 is an explanatory view showing a sheet passing form in the leading edge binding mode,
Continuation of FIG. 61.

FIG. 63 is an explanatory diagram showing a sheet passing form in a leading edge binding mode,
The continuation of FIG. 62.

FIG. 64 is an explanatory diagram showing a sheet passing form in the leading edge binding mode;
Continuation of FIG. 63.

FIG. 65 is an explanatory diagram showing a sheet passing form in the leading edge binding mode;
Continuation of FIG. 64.

FIG. 66 is an explanatory diagram showing a sheet passing form in the leading edge binding mode,
Continuation of FIG. 65.

FIG. 67 is an explanatory diagram showing a sheet passing form in the leading edge binding mode;
Continuation of FIG. 66.

FIG. 68 is an explanatory diagram showing a sheet passing form in the leading edge binding mode;
Continuation of FIG. 67.

FIG. 69 is an explanatory diagram showing a sheet passing form in the leading edge binding mode;
Continuation of FIG. 68.

FIG. 70 is an explanatory diagram showing a sheet passing form in the leading edge binding mode;
Continuation of FIG. 69.

FIG. 71 is an explanatory diagram showing a sheet passing form in the leading edge binding mode;
Continuation of FIG. 70.

FIG. 72 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode.

FIG. 73 is an explanatory diagram showing a sheet passing form in a trailing edge binding mode,
Continuation of FIG. 72.

FIG. 74 is an explanatory diagram showing a sheet passing form in a trailing edge binding mode,
Continuation of FIG. 73.

FIG. 75 is an explanatory view showing a sheet passing form in the trailing edge binding mode,
Continuation of FIG. 74.

FIG. 76 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode;
Continuation of FIG. 75.

FIG. 77 is an explanatory diagram showing a sheet passing form in a Z-folding / rear end binding mode.

FIG. 78 is an explanatory diagram showing a sheet passing form in the Z-folding / rear edge binding mode, continued from FIG. 77;

79 is an explanatory diagram showing a sheet passing form in the Z-folding / rear end binding mode, continued from FIG. 78;

FIG. 80 is an explanatory diagram showing a sheet passing form in the Z-folding / rear end binding mode, continued from FIG. 79;

FIG. 81 is an explanatory diagram showing a sheet passing form in a half-folding / trailing end binding mode.

82 is an explanatory view showing a sheet passing form in the half-folding / trailing end binding mode, continued from FIG. 81.

FIG. 83 is an explanatory diagram showing the sheet passing form in the half-folding / trailing end binding mode, continued from FIG. 82;

FIG. 84 is an explanatory diagram showing the sheet passing form in the half-folding / trailing end binding mode, continued from FIG. 83.

FIG. 85 is an explanatory diagram showing a sheet passing form in a trailing edge binding mode and a mixed size sheet stacking mode.

FIG. 86 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode and different-size sheet mixed loading, and a continuation of FIG. 85;

FIG. 87 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode and mixedly loaded different sizes of paper, continued from FIG. 86.

88 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode and different-size sheet mixed loading, and a continuation of FIG. 87. FIG.

89 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode and mixed loading of different size sheets, continued from FIG. 88. FIG.

FIG. 90 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode and different-size paper mixed loading, and a continuation of FIG. 89;

FIG. 91 is an explanatory diagram showing a sheet passing form in a trailing edge binding mode and different-size sheet mixed loading, and a continuation of FIG. 90;

FIG. 92 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode and mixed size sheets mixed with each other, continued from FIG. 91;

FIG. 93 is an explanatory diagram showing the sheet passing form in the trailing edge binding mode and mixed loading of different-size sheets, continued from FIG. 92;

FIG. 94 is an explanatory diagram showing a sheet passing form in the trailing edge binding mode and mixed loading of different-size sheets, continued from FIG. 93;

FIG. 95 is an explanatory diagram showing a sheet passing form in the saddle stitching mode.

FIG. 96 is an explanatory diagram showing a sheet passing form in the saddle stitching mode, continued from FIG. 95.

FIG. 97 is an explanatory diagram showing the form of sheet passing in the saddle stitch mode, continued from FIG. 96.

FIG. 98 is an explanatory diagram showing a sheet passing form in the saddle stitching mode, continued from FIG. 97;

FIG. 99 is an explanatory diagram showing a sheet passing form in the saddle stitching mode, continued from FIG. 98.

FIG. 100 is an explanatory diagram showing a sheet passing form in a saddle stitching mode,
Continuation of FIG. 99.

101 is a perspective view showing a state where a document is set on the ADF. FIG.

FIG. 102 is a plan view showing a document set state on the platen glass of the copying machine.

FIG. 103 is an explanatory diagram showing a copy process and a finished state.

FIG. 104 is an explanatory diagram showing a copy process and a finished state.

FIG. 105 is an explanatory diagram showing a copy state in the saddle stitching mode.

FIG. 106 is a perspective view showing a finished state in the saddle stitching mode.

FIG. 107 is an explanatory diagram showing a copy state in the bag binding mode.

FIG. 108 is a perspective view showing a finished state in the bag binding mode.

FIG. 109 is a block diagram showing a control unit.

FIG. 110 is a block diagram showing a memory unit section.

FIG. 111 is a block diagram showing an image signal processing unit.

FIG. 112 is an explanatory diagram showing a relationship between a management table and a code memory.

FIG. 113 is a flowchart showing a control procedure of image inversion judgment.

[Explanation of Codes] 10 ... Copying machine 40 ... Finisher 41 ... Staple processing unit 201, 202 ... CPU 250 ... Memory unit unit 259 ... Inversion processing unit 411 ... Stacking tray 415 ... First chuck means 443 ... Needle hitting unit 444 ... Needle Receiving unit 440 ... Staple unit 441 ... Staple unit 465 ... Sheet bundle conveying unit

Claims (1)

[Claims] 1. An image forming system having the following structure: an image forming apparatus main body by electrophotography; an image processing means for storing image information and inverting the top and bottom of the stored image; Paper stacking means for receiving and stacking the paper discharged from the forming apparatus main body;
Unloading means for unloading the sheet bundle from the sheet stacking means; staple means for driving a staple needle to the sheet bundle carried out from the sheet stacking means, and the stapler means a transport section slightly longer than the transport direction length of small size sheets. Have,
The entrance portion of the transport unit has a staple driving unit and a staple receiving unit, and the staple position for the sheet bundle can be selected to be either the front end or the rear end in the transport direction; if the paper is a small size, the rear end Staple control means for controlling the stapling means so as to staple the portion and, if the size is large, staple the tip portion.