JPH10324451A - Sheets post-processing device and image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sheets post-processing device and an image forming device, which can be manufactured at a low cost without providing a special drive type aligning means for aligning the sheets stored on a storage means after the post-processing and in which a low-output driving source can be used. SOLUTION: Sheets S, which are recorded with image and which are carried from a copying machine, are temporarily piled for storage on a processing tray in the inclined condition, and a bundle of the sheets S, which are piled for storage on the processing tray 4, is stapled by a stapler, and the bundle of the sheets S, which is stapled by the stapler, is transferred by a second holding means 10 in a direction crossing the carrying direction at the time of carrying the sheets S from the copying machine, and the bundle of the sheets S, which is transferred by the second holding means 10, is stored for housing in a storage tray 9, which is inclined nearly the same as the processing tray 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to an apparatus for post-processing a sheet conveyed from image forming means such as a copying machine or a printer, or a sheet post-processing apparatus and an image forming apparatus for performing post-processing offline.

[0002]

2. Description of the Related Art Conventionally, for example, a copying machine as an image forming means is known which is equipped with a sheet post-processing device for performing post-processing such as stapling a sheet bundle on which images have been formed and punching holes. I have. An image forming apparatus in which such a sheet post-processing apparatus is unitized with an image forming means such as a copying machine is also known.

In such a sheet post-processing apparatus,
After that, when the processing is performed in a bundle of sheets, the sheets conveyed from the copier are temporarily stocked on a stacking means such as a processing tray in order to bundle the sheets into a predetermined number, and then the bundle is stacked. The sheet is post-processed and discharged to an accumulation tray or the like separate from the accumulation means.

[0004]

By the way, in the sheet post-processing apparatus configured as described above, the post-processed sheet bundle on the accumulation means is transferred to an accumulation tray.
A plurality of sheet bundles can be stacked on this stacking tray.

However, in such a conventional sheet post-processing apparatus, from the viewpoint that the accumulation / accumulation means performs post-processing on one edge of the sheet bundle, basically, the edge on which the post-processing is performed is lower. Although they are arranged so as to be inclined, the stacking tray is provided horizontally or from the viewpoint that it only needs to be stacked. It was such a slope.

Therefore, in the stacking on the horizontal tray, the sheet bundle inclined along the inclination of the accumulation means is discontinuously deflected in the horizontal direction, so that there is a problem that the alignment property in the stacking tray is not good. Had occurred.

In addition, when the sheet is discharged against the inclination of the stacking tray to shift from the accumulation means to the stacking tray, the lineability is poor.

[0008] Even if the angle is inclined, not only does the alignment problem occur as in the case described above, but also the driving force of the transfer means for transferring the sheet bundle from the accumulation means to the accumulation tray is maintained high. Therefore, there is a problem that it is necessary to install a large-sized, high-output driving source which is expensive and large in cost.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and it is possible to inexpensively secure the alignment of sheets after post-processing that has been accumulated on an accumulation means without providing a special driving type alignment means. It is an object of the present invention to provide a sheet post-processing apparatus and an image forming apparatus which can use a low-power driving source.

[0010]

According to a first aspect of the present invention, an image-recorded sheet conveyed from an image forming means is temporarily accumulated and accumulated in an inclined state. Stacking means, post-processing means for performing post-processing on sheets or sheet bundles accumulated on the accumulation means, and transporting the sheets or sheet bundles post-processed by the post-processing means from the image forming means Transfer means for transferring the sheet or sheet bundle transferred by the transfer means in a direction intersecting the conveying direction when the sheet is stacked, and stacking means for stacking and storing the sheets or sheet bundles in the substantially same inclined state as the accumulation means. The point is that

According to a second aspect of the present invention, there is provided a processing tray for temporarily storing and accumulating sheets in an inclined state, a post-processing means for processing the sheets stored and accumulated on the processing tray, and A stacking tray for stacking and storing the processed sheets in a tilted state, wherein the processing tray and the stacking tray are provided side by side in a direction intersecting the tilt direction, and each tilt thereof is substantially the same. That is the gist.

Further, according to a sixth aspect of the present invention, the stacking means includes a vertical wall for supporting one edge of the stacked sheets at a downstream end of the stacking tray in the inclined direction, and a boundary between the post-processing means. And a vertical wall for supporting the other edge of the stacked sheets, and at least one of the stacking trays so that the sheets transferred from the post-processing means by the transfer means are diversified in the transport direction. The gist of the present invention is that a slope or a protrusion is provided in a part.

With such a configuration, when a large number of sheets (for example, about 2000 sheets) are stacked on the stacking tray, the stacking height is considerable.
It is possible to protect the stacking tray from the moment applied to the center of gravity.

According to a seventh aspect of the present invention, there is provided a conveying means for conveying a sheet from an image forming section, a processing tray for temporarily accumulating the sheets conveyed by the conveying means in an inclined state, and Post-processing means for performing post-processing on the sheets or sheet bundles stacked on the tray in the vicinity of the inclined downstream, transfer means for transferring the post-processed sheets or sheet bundles in a direction intersecting the inclination direction of the processing tray,
The invention is characterized in that it comprises a stacking means for stacking and storing the sheets or sheet bundles transferred by the transfer means in substantially the same inclined state as the processing tray.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment of a sheet post-processing apparatus according to the present invention will be described with reference to a copying machine as an image forming means.
The present invention is applied to a stapler as a sheet post-processing apparatus, and will be described with reference to the drawings.

1 to 4, a sheet post-processing apparatus 1 includes a post-processing apparatus main body 20 having independent housings.
And an integrated processing apparatus main body 50.

The post-processing apparatus main body 20 stores the image-formed sheets S sequentially discharged from the copying machine 2 on the first stacking tray 3 when no post-processing is performed, and on the processing tray 4 when post-processing is performed. Pre-conveyance means 5 which conveys so that it can be distributed to
Aligning means 6 for aligning the plurality of sheets S received on the processing tray 4, first gripping means 7 for gripping and transporting the aligned sheet bundle S ', and held by the first gripping means 7. Stapler 8 for stapling the folded sheet bundle S '
And an auxiliary tray 13 that is located above the processing tray 4 and below the pre-stage transport unit 5.

The post-processing apparatus main body 20 includes a vertical wall 20a serving as a reference surface for storing the sheet S with respect to the processing tray 4,
An opening 20b through which the sheet S is discharged, and a rail groove 20 for allowing movement of an alignment member 30 and a holding member 34 described later.
c, 20d, a rail groove 20e that allows the movement of the first gripping means 7, and a sheet bundle S 'gripped by the first gripping means 7 after the staple binding from the processing tray 4 to the second stacking tray 9. An opening 20f that allows cooperative movement is formed.

The opening 20f is parallel to the processing tray 4 and also to the second stacking tray 9, as shown in FIG. Accordingly, the sheet bundle S ′ moves in parallel from the processing tray 4 to the second stacking tray 9, whereby the sheet bundle S ′ stacked on the second stacking tray 9.
Satisfactorily maintained.

The stacking apparatus main body 50 includes a second stacking tray 9 for stacking the stack of sheets S 'bound by the stapler 8 and a second stacking tray 9 held by the first holding means 7. 9 conveyed toward the sheet bundle S
′, A second gripping means 10 for gripping while inheriting and transporting to a predetermined position on the second stacking tray 9, and a sheet height detecting means for detecting the height of the sheet bundle S ′ stacked on the second stacking tray 9 11, an elevating means 12 for raising and lowering the second stacking tray 9, and a shutter 15 interlocking with the raising and lowering of the second stacking tray 9.

The stacking apparatus main body 50 has a vertical wall 50a for positioning and alignment with which one side of the sheet bundle S 'conveyed to the second stacking tray 9 abuts, and a horizontal direction of the second gripping means 10 in the horizontal direction. A horizontal opening 50b allowing movement, a vertical recess 50c communicating with the horizontal opening 50b and allowing vertical rotation of the second gripping means 10, and a vertical opening allowing vertical movement of the second stacking tray 9; A pair of extended guide grooves 5
0d is formed.

The first stacking tray 3 includes a post-processing apparatus main body 20.
The upper part of the outer frame is inclined, and its upstream side is located below and its downstream side is located above. Also, a vertical wall 3a is formed from the upstream end of the first stacking tray 3,
An opening 3b for emission is provided in the upper part of the vertical wall 3a.

As shown in FIG. 2, the pre-stage conveying means 5 has a conveying port 21 opened on one side of the post-processing apparatus main body 20 on the rear side, and the conveying port 21 is an outlet of the copying machine 2 (not shown). Z)
Is matched to. A flapper 23 for switching the transport path of the sheet S between the upper first stacking tray 3 side and the lower processing tray 4 side is provided downstream of the transport opening 21 following the transport roller pair 22. Each transport path is formed by a guide plate 24 and a transport roller pair 25.

The processing tray 4 is located below the first stacking tray 3 and is inclined in parallel with the first stacking tray 3.
A series of sheets S are sequentially conveyed to the processing tray 4 in the discharge direction A from the pair of conveying rollers 22 by the pair of discharge rollers 26 at the end of a substantially linear path for binding by the stapler 8. The processing tray 4 is formed such that an inclined lower end rises in a direction perpendicular to the tray surface, and an inner surface thereof is a vertical wall 20a with which one side of a sheet S extending in the front-rear direction perpendicular to the discharge direction A abuts.

The aligning means 6 aligns the plurality of sheet bundles S 'stored on the processing tray 4 by abutting the reference surface 4a of the processing tray 4 before and after the sheet is discharged. The left and right directions are aligned by an alignment member 30 positioned at both widths of the processing tray 4 and a shutter-type reference plate 31 that can be moved up and down.

The mechanism for moving the alignment member 30 is the processing tray 4
A rail 32 extending in the width direction is provided at a lower portion of the pulley. A holding member 34 that supports the alignment member 30 so as to be able to travel by a conical roller 33 is disposed inside the rail 32, and a belt 36 is hung between pulleys 35. A part of the holding member 34 is fixed in the middle of the belt 36. Then, one pulley 35 is driven by the alignment motor 37 (see FIG. 15), and the alignment member 30 moves.

As a result, while the sheets S are sequentially conveyed in the discharge direction A, the alignment member 30 is in the retreated open position, receives a predetermined number of sheets S, advances and presses against the reference plate 31. To align.

The reference plate 31 is, as shown in FIG. 12, a fixed plate 311 fixed to the inner wall of the post-processing apparatus main body 20.
A shutter solenoid 312 held by a fixed plate 311; a connection plate 313 provided at the tip of the shutter solenoid 312; a pair of arms 314 having one end connected to the connection plate 313;
A shutter plate 318 is connected to the other end of the arm 314 via connection pins 316 and 317 for converting the rotational movement of the arm 314 into a linear movement by a guide groove 315 formed in the arm 314. The shutter solenoid 31
2 indicates that the next sheet bundle S ′ is being transported in the process of transporting one sheet bundle S ′ from the processing tray 4 to the second stacking tray 9.
When the base sheet S is discharged onto the processing tray 4, the shutter plate 318 is moved to the sheet bundle S in the conveying process to enable the base sheet S to be aligned.
The arm 314 is rotated so as to contact the upper surface of the '.

The first gripping means 7 grips the rear end of the sheet bundle S 'arranged on the processing tray 4 from above and below, and transports the sheet bundle S' in the transport direction B orthogonal to the discharge direction A. Also, the first
As shown in FIG. 6, the gripping means 7 is provided with upper and lower holding levers 41 which open and close the moving frame 40, and a detailed mechanism is not shown, but the sheet bundle S 'is operated with the operation of the bundle holding solenoid 43. Of one side. The holding lever 41
Is performed by driving the holding lever motor 42.

A flat auxiliary tray 13 as shown in FIGS. 2 and 9 is disposed above the processing tray 4 and between a discharge roller pair 26 rotated by the drive of the transport motor 19. The auxiliary tray 13 has a shorter length and a smaller width than the processing tray 4, and is provided to be able to move forward and backward on the reference position side of the processing tray 4. That is, both ends of the auxiliary tray 13 are slidably supported by the upper and lower guide rollers 45, the pinion gear 47 is meshed with the rack 46 at the center, and the auxiliary tray 13 is slid and driven by the driving of the pinion gear 47 in conjunction with the driving of the auxiliary tray motor 48. You. The illustrated state is a state in which the auxiliary tray 13 is moving forward.

The auxiliary tray 13 conveys the next series of sheets S while the sheet bundle S 'is being aligned while the series of sheet bundles S' are being discharged onto the processing tray 4. When the sheet advances to the previous state and receives the next sheet S, it is separated from the sheet bundle S ′ being conveyed (during stapling).

As shown in FIG. 10, the auxiliary tray 13 has a return function of transporting the sheet S in the return direction C opposite to the discharge direction A when the sheet S is placed on the auxiliary tray 13. Having. This return function is based on the discharge roller pair 2
6 and a lower roller 26 a which is in elastic contact with the discharge roller pair 26. The diameter of the lower roller 26a is equal to the discharge roller pair 26.
The sheet S is made of a softer material, and the outer peripheral surface thereof comes into light contact with the sheet S on the auxiliary tray 13 so that the leading end of the sheet S is sent out in the return direction C in which the sheet S comes into contact with the backing plate 20a.

Since only about one or two sheets S are placed on the auxiliary tray 13, a mechanism for changing the thickness of the sheets S is unnecessary. In addition, auxiliary tray 1
The timing of the advance and retreat of the sheet 3 is such that the leading end of the sheet that is disposed by the discharge roller pair 26 serving as the discharge means in the discharge direction of the sheet S and discharged by the discharge roller pair 26 is positioned on the processing tray 13 or the processing tray 13. The detection is performed based on the detection result of the detection sensor 17 that detects that the sheet S reaches the preceding stacked sheet S.

That is, the processing tray 4 has a plurality of rail grooves 20c, 20d, and 20e extending in a direction perpendicular to the sheet S conveying direction. Accordingly, when the sheets S are not stacked on the processing tray 4 and the first sheet S is directly discharged to the processing tray 4, the buckling of the leading end of the sheet S due to the height of the processing tray 4, Alternatively, there is a possibility that the above-described catching on the rail grooves 20c, 20d, and 20e may occur. Further, even when the sheets S are stacked on the processing tray 4, there is a possibility that the leading end of the next sheet S abuts on the preceding sheet S and buckles. Furthermore, the above-mentioned sheet bundle S ′ and the next sheet S must be separated.

Then, the sheet S is detected by the detection sensor 17.
By detecting the leading end of the sheet S, the auxiliary tray 13 is advanced, and by detecting the trailing end of the sheet S by the detection sensor 17, the auxiliary tray 13 is retracted, thereby solving the above-described problem.

At this time, the sheet S is a set of a sheet bundle S '.
It is conceivable that a plurality of sheet sizes are mixed. Therefore, the retreat timing of the auxiliary tray 13 by the auxiliary tray motor 48 based on the sheet size information output from the copying machine 2 and the sheet detection result by the detection sensor 17 determines whether the sheet size information output from the copying machine 2 is larger. Buckling according to the sheet size can be prevented by setting the size faster as the size becomes larger. Even when the sheet sizes are not mixed, the evacuation timing may be set earlier as the sheet size becomes larger than an arbitrary sheet size (for example, A4 landscape).

When the sheet bundle S ′ on the lower processing tray 4 is being conveyed to the second stacking tray 9,
At about the same time as the completion of the conveyance to the second stacking tray 9, the auxiliary tray 13 is immersed and the sheet S on the auxiliary tray 13 is dropped onto the processing tray 4.

FIG. 9 shows a state in which a sheet S having a relatively large size is being conveyed to the processing tray 4. In this case, the sheet S on the auxiliary tray 13 is
3 is supported so as to hang down on the processing tray 4.
When a small-sized sheet S is conveyed,
It can be placed only by the auxiliary tray 13.

FIG. 11 shows another embodiment of the return function. In this example, a return roller 27 is provided at a portion extending obliquely downward of the discharge roller pair 26. The return roller 27 is formed of a soft material, and its outer peripheral portion comes into light contact with the sheet S on the auxiliary tray 13 to return the sheet S to the abutment plate 20a at the leading end in the same manner as in FIG. C is provided.

The stapler 8 binds the vicinity of the edge of the sheet bundle S 'with staples (binding needles), and is disposed near the front end of the vertical wall 20a of the processing tray 4 on the side of the second stacking tray 9. I have.

The sheet bundle S 'to be bound by the stapler 8
The binding position and the number of bindings are performed as the first gripper 7 and the second gripper 10 convey. That is, when binding is performed at one location, the document is held by the first gripping means 7 and stopped while the sheet is conveyed at a predetermined position in accordance with the stapler 8 to perform binding. In the case of binding at two places, after binding and transporting by the first gripping means 7 and binding the first position to the stapler 8,
After switching to the second gripping means 10, the second position is bound to the stapler 8 and bound. Note that the stapler 8 may be provided so as to be movable in the discharge direction A so that the stapling position can be changed.

The second stacking tray 9 is arranged in front of the processing tray 4, that is, parallel to the processing tray 4, that is, shifted in a direction orthogonal to the discharge direction A, and has a concave portion 9a for taking out at the edge measuring portion on the upper surface.

As shown in FIGS. 5 and 6, the second stacking tray 9 is provided so as to move up and down in the stacking apparatus main body 50, and the vertical wall 50a of the stacking processing apparatus main body 50 is connected to the stacking reference plane. Has become. The position of the accumulation reference plane is set to be shifted from the position of the vertical wall 4a in the processing tray 4 in the discharge direction A by a distance d (see FIG. 5).

The main body 50 of the stacking device of the second stacking tray 9
The front and rear ends are fixedly supported by an elevating frame 52 protruding from a cover of the main body 50 of the integrated processing apparatus, and the elevating frame 52 is guided by rollers 53 on both sides to be able to move up and down along a vertical groove 54 of the inner frame. ing.

A pulley 56 is fixed to each of upper and lower shafts 55 extending in the front-rear direction, a belt 57 is hung between the upper and lower pulleys 56, and a driven gear 58 fixed to an end of the upper shaft 55 is a collecting tray. The upper pulley 56 is driven to rotate by meshing with the drive gear 59 of the motor 60. The elevating frame 52 is fixed in the middle of the belt 57 by a fixture 52a, and moves up and down as the belt 57 runs.

A roller 63 of an auxiliary elevating frame 62 is engaged with the vertical groove 54 below the elevating frame 52 and is guided so as to be able to move up and down. 65 are attached. When the sheet bundle S ′ is sequentially stacked on the second stacking tray 9 and the processing tray 4 is moved down, the lower end of the lifting frame 52 abuts on the auxiliary lifting frame 62. And a reduction mechanism that obtains an upward holding force by the urging force of the spring 65 and prevents the weight of the sheet bundle S ′ on the processing tray 4 from excessively acting on the accumulation tray motor 60. Has become.

As shown in FIGS. 7 and 8, the second gripping means 10 is held by the first gripping means 7 and transported so as to be pushed out of the processing tray 4 onto the second stacking tray 9. Further, the second gripping means 10 includes upper and lower gripping levers 71 and 72 for pressing the upper surface and the lower surface of the sheet bundle S ′ in a planar manner to clamp the sheet bundle S ′.
The opening / closing mechanism holds and releases the sheet bundle S ′, and transports the held sheet bundle S ′ in the transport direction B orthogonal to the discharge direction A by the transport mechanism. Further, the gripping portion of the sheet bundle S ′ gripped in the inclined state is swung to the horizontal state by the swing mechanism, and at the same time, the second stacking tray 9 is rotated.
It is configured to move slightly to the side.

First, the upper holding lever 71 is pivotally supported at its base end by a first shaft 74 with respect to a swing frame 73, and the lower holding lever 72 is connected to the swing frame 73 by a second shaft 75. It is pivotally supported. A first arm 76 is pivotally supported on the first shaft 74 so as to rotate integrally with the partial gear 77, and a tip pin 76 a of the first arm 76 engages with a groove 71 a of the upper holding lever 71 to open and close. . Similarly, a second arm 78 is pivotally supported on the second shaft 75, and a tip pin 78a of the second arm 78 engages with a groove 72a of the lower holding lever 72 to open and close. 7
9, the gear portion 79 meshes with the partial gear 77 of the first arm 76, and the upper and lower holding levers 71 and 72 are rotated as the arms 76 and 78 rotate in conjunction with each other.
Is provided to rotate.

The other part of the partial gear 77 includes the swing frame 7
The drive gear 8 of the opening / closing motor 83 having the swing frame 73 mounted on the intermediate gear 81 which rotates with the pinion gear 80 supported by the pinion gear 80
2 mesh with each other to form an opening / closing drive mechanism. In addition,
The open / close state of the upper and lower holding levers 71 and 72 is detected by a sensor (not shown) of the operating piece 84 that rotates integrally with the upper holding lever 71.

At the time of opening and closing operation of the second gripping means 10, since the diameter of the partial gear 77 of the upper gripping lever 71 is large and the diameter of the gear portion 79 of the lower gripping lever 72 is small, their opening angles are different. 71 opens about 30 °, whereas the lower holding lever 72 opens about 90 ° downward (see FIG. 8).

The swing frame 73 has a swing shaft 85 at the lower end.
Accordingly, the movable frame 87 is pivotally supported by the movable frame 87. A rotating gear 89 is supported on a moving frame 87 by a shaft 88 parallel to a swing shaft 85, and an eccentric position of the rotating gear 89 and a rear portion of the swing frame 73 above the swing shaft 85 are connected by a link 90. With the rotation of the rotary gear 89, the swing frame 73 is moved through the link 90 to the retreat position shown in FIG.
It is swung to the projecting position in FIG.

A pinion gear 91 pivotally supported by the moving frame 87 in a direction orthogonal to the swing shaft 85 meshes with the outer peripheral gear portion of the rotary gear 89, and the moving frame 87 is engaged with an intermediate gear 92 integral with the pinion gear 91. The drive gear 93 of the swing motor 94 attached to the gears meshes to form a swing mechanism.

The transport mechanism of the moving frame 87 is such that a running member 95 protruding left and right in front of and behind the moving frame 87 is provided in a guide groove (not shown) extending in the front-rear direction formed in a guide frame 100 fixed to the main body. The moving frame 87 is supported so as to be movable in the front-rear direction (transport direction B).

A pulley 102 is provided inside and behind the guide frame 100 with a pulley shaft 101 (one is not shown).
And the belt 103 is hung. A moving frame 87 is fixed to a part of the belt 103 by a clamp member 104, a driven pulley 105 is fixed to an end of one pulley shaft 101, and a driving shaft of a transport motor 108 attached to a lower portion of the guide frame 100 is driven. A drive belt 106 is hung between the pulley 107 and the pulley 107.

Then, the moving frame 87 moves forward or backward in the conveying direction B together with the second gripping means 10 by the forward or reverse driving of the conveying motor 108. The initial position (home position) of the second gripping means 10 is a receiving position close to the processing tray 4 side.
Is moved to the intermediate stop position for binding and the most advanced discharge position. The opening and closing operation of the second gripping means 10 is performed at the initial position and the release position, and swinging is performed at the release position.

Further, such a transport mechanism, an opening / closing mechanism of the second gripping means 10 and a swing mechanism are arranged in the cover of the main body 50 of the stacking apparatus, the moving range is covered, and a slit-shaped horizontal The opening 50b is opened, the second gripping means 10 moves while holding the sheet bundle S 'along the horizontal opening 50b, and the upper and lower holding levers 71, 72 which swing at the discharge end protrude. .

As shown in FIGS. 3 and 4, the seat height detecting means 11 pivotally supports a rotation detector 110 having an arc-shaped tip on the frame of the fixed portion. 110 is provided so as to be able to move in and out via a spring 111 with the operation of the actuator 112. The tip of the rotation detector 110 can contact the upper surface of the sheet bundle S ′ on the second stacking tray 9, and detects the position of the upper surface of the sheet bundle S ′ on the processing tray 4 based on the amount of rotation.
To control the vertical movement of

The operation of each mechanism is coordinated and controlled by a control unit, and the number of sheets, the number of sets, the presence or absence of staples, the staple position, and the like are set by an operator on the control panel, and the driving of each unit is controlled based on these settings. You.

The shutter 15 prevents the sheet bundle S 'on the second stacking tray 9 from being caught in the horizontal opening 50b due to the inclination of the second stacking tray 9 when the second stacking tray 9 is raised. A shutter plate 15a for closing the horizontal opening 50b;
and a drive unit 15b for raising and lowering a.

By the way, as shown in FIGS. 13 and 14, the post-processing apparatus main body 50 and the integrated processing apparatus main body 50 can be reversed in arrangement. In other words, the post-processing apparatus main body 20 may be common, but the mode of accumulation of the accumulation processing apparatus main body 50 and further post-processing (for example, punching) may be followed, or as in the present embodiment, the processing tray 4 Unlike the case where the conveyed sheets S are stacked and stapled, and the sheet bundle S ′ is discharged to the second stacking tray 9 (if the stacking amount of the second stacking tray 9 is about 1,000 to 2,000 sheets), The above-mentioned lifting type second stacking tray 9 is convenient), and processing is performed by a multi-stage tray that can be moved not only vertically but also horizontally so as to enable further processing (or like a belt conveyor). In consideration of various applications such as cases, the fact that the storage mode can be switched is very convenient in applications where the usage mode may be changed after installation.

Therefore, if the post-processing apparatus main body 20 and the integrated processing apparatus main body 50 are configured to be separable and drivable, and the transfer part of both of them can be switched in a plurality of directions, the layout of the installation place is reduced. A model in which the post-processing apparatus main body 20 is to be placed on the front side (on the operation unit side of the copying machine 2) or when it is desired to place the post-processing apparatus main body 20 in a horizontal direction, or the sheet bundle S 'is discharged from the post-processing apparatus main body 20 in reverse. It is also possible to realize a flexible layout, such as responding to the problem.

In FIG. 14, reference numeral 120 denotes a connecting shaft for connecting the post-processing device main body 20 and the integrated processing device main body 50, and 121 denotes a cable for electrically connecting the post-processing device main body 20 and the integrated processing device main body 50. , 122 and 123 are connectors for connecting the cable 121.

Incidentally, the various driving systems described above are similar to those shown in FIG.
As shown in the figure, the parallel I / O 1 is controlled by input / output signals from the CPU 150 and storage means 151 such as a ROM and a RAM.
52 controls the drive.

Next, a post-processing step of the sheet S will be described with reference to FIGS. In the flowcharts of FIGS. 16 and 17 showing a series of post-processing steps and the timing chart of FIG. 18, two sheets S (of the same size) are staple-bound as a sheet bundle S ′ and then stacked. In addition, the numbers attached to the reference character M in the drawing indicate the operation divisions of each unit or the operation time.

In the flowchart, as an initial setting, the number of sheets N conveyed from the image forming apparatus 2 is conveyed.
= 0, and the sheet alignment flag is set to F0 = 0 assuming that the previously conveyed sheet has been aligned.
(Alignment completed) (S1, S2). The sheet S is sequentially discharged from the image forming apparatus 2 (S3), and at this time, the auxiliary tray 13 is protruded and conveyed to increase the N,
A series of plural (two) sheets S are stacked (S4, S
5, S6), N = 0 is set for the next transport (S7). Assuming that the sheets have been aligned (S8), the auxiliary tray 13 sinks and the sheet bundle S 'falls onto the processing tray 4 and is accommodated (S9, S10). (M1: operation of a paper ejection sensor and a transport motor (not shown)). Subsequently, the alignment member 30 moves to push the rear side of the sheet S and press the front side against the reference plate 31 to align (align) the sheet S in the front-rear direction (S11, M2: alignment). When the auxiliary tray 13 is aligning the sheet S (F0 = 1),
When the next series of sheets S is carried in, the sheet is protruded (M
3) The sheet S is held below to be separated from the sheet S being aligned and conveyed below (S11 to S14).
The description of the paddle in the timing chart is omitted.

FIG. 19 shows a state in which the sheet bundle S ′ when the sheet bundle S ′ is transferred from the processing tray 4 toward the stacking tray 9 (leftward in FIG. 19) is moved from the first gripping unit 7 to the second gripping unit 10.
The process up to the succession is shown. FIGS. 7A, 7B and 7C show states in which the conveyance of the sheet bundle S 'proceeds sequentially, and the second gripping means 10 and the stapler 8 move during the moving stroke. In a fixed position.

When the alignment is performed, the first gripping means 7 moves to the initial position (shown by a solid line in FIG. 5) (S15, M
Four). At this time, the second gripping means 10 is at the initial position (shown by a solid line in FIG. 5) (S16). Here, a flag indicating whether or not the sheet bundle S 'is being transferred is set to F1 = 0 (not being transferred) (S17). The sheet bundle S 'in the above-mentioned alignment state
Is gripped (nip) by the first gripping means 7 (S
18, S19, M5, shown by the dashed line in FIG. 14 (a)).

The reference plate 31 (shutter) is raised (S20, M6), and a new transfer of the sheet bundle S 'is waited (F1 = 1, S21).
Then, the first gripping means 7 is driven forward to move forward by a predetermined amount, and the sheet bundle S ′ is discharged in the discharge direction A.
Is moved to the first staple position in the direction of the stacking tray 9 that intersects with the staple (S22, M7, shown by a solid line in FIG. 19A), and the first staple is bound by the stapler 8 (S23, M8). When the reference plate 31 rises, it immediately descends after waiting for the sheet bundle S 'to enter. In this lowered state, the sheet bundle S' is lightly pressed to allow passage.

Subsequently, the first gripping means 7 moves further forward and stops at the second stapling position (S24,
M9, (b) in FIG. 19, and the state of the solid line in FIG. 1). At this time, the second gripping means 10 is at the initial position on the processing tray 4 side (FIG. 5,
(The solid line position in FIG. 6), and swings to the retracted position in FIG. 7, and waits for the first gripping means 7 to stop. One side on the position side is handed over and held in the stopped state (S25, M10).

After the above gripping by the second gripping means 10, the gripping of the first gripping means 7 is released (S26,
M11, (c) in FIG. 19), the first gripping means 7 moves to the holding position (indicated by the solid line in FIG. 2) to hold the next sheet bundle S '(S27), and the next sheet bundle S 'Can be transferred (S28). Then, the second position is bound by the stapler 8 (S29, M12). The transfer amount of each of the staple positions is set for the first gripping means 7 based on an instruction from the operator.

Subsequently, the second gripping means 10 moves to the front release position (the position indicated by the dashed line in FIGS. 5 and 6), ends the transfer to the transfer B, and stops (S30, M13). At this release position, the second gripping means 10 is swung from the retracted swinging position shown in FIG. 7 to the protruding position shown in FIG. 8, so that the gripping state of the second gripping means 10 becomes a horizontal state and the conveying direction. It is moved in a direction orthogonal to B (S31, M14).

That is, the end position corresponding to the reference position on the processing tray 4 is gripped and conveyed by the second gripping means 10 as shown in FIG. 7, and is swung to the state shown in FIG. Is moved to the collecting tray 9 side. The moved position corresponds to the reference surface 50a of the stacking tray 9.
Approximately. With this movement, the end of the sheet gripped becomes horizontal (M14), and the upper and lower holding levers 71,
72 is opened as shown by the chain line (S32, M1
5) The gripped sheet bundle S 'falls downward and is discharged as it is, and is stacked on the sheet bundle S' already accumulated on the accumulation tray 9.

At this time, the end of the sheet bundle S 'which falls is not greatly shifted from the end of the sheet bundle S' which is stacked below, and the end of the sheet bundle S 'which falls is not shifted.
Stack without being locked at the staple position.

In the state where the second gripping means 10 is released, the swing frame 73 is moved backward (S33, M16), and then the transporting direction B is set so that the second gripping means 10 returns to the initial state.
(S34, M17).
At this time, even if the next sheet bundle S ′ is sent out, the sheet bundle S ′ does not interfere with the upper sheet holding levers 71 and 72 because the upper sheet holding levers 71 and 72 are sufficiently opened.
Subsequently, in the initial position, the closing operation is performed and the next sheet bundle S
'Can be gripped.

As described above, when the second gripping means 10 is swung horizontally (M14), the actuator (bundle holding solenoid) 112 operates, and the rotation detecting body 110 enters the sheet bundle holding state ( S35) The seat height is detected (S36), the operation of the actuator 112 is subsequently released, and the holding state is released (S37, M1).
8). If it is higher than the predetermined position, the stacking tray 9 is lowered to a predetermined level by the operation of the elevating means 12 (S3).
8, M19). Further, when the sheet bundle S ′ accumulated in the middle is taken out by the operator, the sheet bundle S ′ is moved up in accordance with the detection.

The second gripping means 10 is moved within the cover when transported in the front-rear direction.
And the transport mechanism does not interfere with the operator who tries to take out the sheet bundle S ′ on the stacking tray 9. Further, since the sheet bundle S 'is conveyed while being held, the alignment state of the sheet bundle S' is not disturbed during the conveyance.

In the above-described embodiment, the first gripping means 7 and the second gripping means 10 are constituted by holding levers which are pressed and held in a planar shape. You may make it hold | maintain. The transport mechanism of each part can be changed, and the actuator can also be changed to a known mechanism.

When moving the sheet bundle S ', the end of the stacking tray 9 is shifted to the left as in this embodiment, and the second gripping means 10 and the transport mechanism are arranged outside the stacking tray 9. Therefore, a structure in which the transport mechanism is covered with a cover can be achieved, and safety is ensured.

In the above embodiment, an example in which the present invention is applied to the copying machine 2 as an image forming means has been described, but the copying machine 2 can be applied to both a digital system and an analog system. Needless to say, the present invention can be applied to various image forming units (image recording apparatuses) such as a laser printer and a facsimile.

[0080]

As described above, in the sheet post-processing apparatus of the present invention, the accumulating means for accumulating and temporarily accumulating the image-recorded sheet conveyed from the image forming means in an inclined state. Post-processing means for performing post-processing on sheets or sheet bundles accumulated on the accumulation means, and sheets or sheet bundles post-processed by the post-processing means are conveyed from the image forming means. Transfer means for transferring the sheet or sheet bundle transferred by the transfer means in a direction intersecting the conveying direction at the time of the transfer, and accumulating means for accumulating and storing the sheet or sheet bundle conveyed by the accumulating means in substantially the same inclined state as the accumulation accumulating means. Thus, the alignment of the sheets after post-processing accumulated on the accumulation means can be ensured at low cost without providing a special driving type alignment means, and a low-power driving source can be used.

[0081]

[Brief description of the drawings]

FIG. 1 is an external perspective view showing a sheet post-processing apparatus according to the present invention, in which a part of the sheet post-processing apparatus is cut away.

FIG. 2 is a side view in which a part of a post-processing apparatus body is similarly cut away.

FIG. 3 is a longitudinal sectional view of the integrated processing apparatus main body.

FIG. 4 is a perspective view showing the internal structure of the integrated processing apparatus body.

FIG. 5 is a cross-sectional view of the sheet post-processing apparatus viewed from the plane.

FIG. 6 is a schematic front view of the sheet post-processing apparatus.

FIG. 7 is an enlarged sectional view of a main part of the second gripper in an initial state.

FIG. 8 is an enlarged cross-sectional view of a main part of the second gripping unit in a state where a sheet bundle is dropped.

FIG. 9 is a perspective view of the auxiliary tray.

FIG. 10 is an explanatory view showing the operation of the auxiliary tray.

FIG. 11 is an explanatory view showing another operation of the auxiliary tray.

FIG. 12 is an enlarged front view of the reference plate.

13A is a perspective view showing a state in which the post-processing apparatus main body and the integrated processing apparatus main body are separated from each other, and FIG. 13B is a perspective view of a sheet post-processing apparatus having a combination different from that shown in FIG. It is.

FIG. 14 is an exploded perspective view of the sheet post-processing apparatus.

FIG. 15 is a block diagram of a control system of the sheet post-processing apparatus.

FIG. 16 is a first half flowchart illustrating a post-processing step of the sheet post-processing apparatus.

FIG. 17 is a second half flowchart showing a post-processing step of the sheet post-processing apparatus.

FIG. 18 is a timing chart showing a post-processing step of the sheet post-processing apparatus.

FIGS. 19A to 19C are explanatory diagrams showing, in a time series, steps of transferring a sheet bundle from a processing tray to a collecting tray in a post-processing step of the sheet post-processing apparatus.

[Explanation of symbols]

 S: Sheet 1: Sheet post-processing device 2: Copy machine (image forming unit) 4: Processing tray 17: Detection sensor (detection unit) 26: Discharge roller pair (discharge unit) 48: Auxiliary tray motor (drive unit)

Claims (8)

[Claims] 1. An accumulating means for temporarily accumulating an image-recorded sheet conveyed from an image forming means in an inclined state, and a sheet or a sheet bundle accumulated and accumulated on the accumulating means. Post-processing means for performing post-processing on the sheet, a transfer means for transferring a sheet or a sheet bundle post-processed by the post-processing means in a direction intersecting a conveyance direction when conveyed from the image forming means, and the transfer means And a stacking means for stacking and storing the sheets or sheet bundles transferred by the stacking means in substantially the same inclined state as the accumulation means. 2. A processing tray for temporarily accumulating and accumulating sheets in an inclined state, a post-processing means for processing the sheets accumulated and accumulated on the processing tray, and accumulating the post-processed sheets in an inclined state. A sheet post-processing apparatus, comprising: a stacking tray for storing therein, wherein the processing tray and the stacking tray are provided side by side in a direction intersecting the inclination direction thereof, and each inclination thereof is substantially the same. . 3. The accumulation device according to claim 1, wherein the accumulation means comprises a tray, a wire,
The sheet post-processing device according to claim 1, wherein the device is a belt. 4. The stacking means has a stacking tray for stacking and storing sheets transferred from the post-processing means by the transfer means, wherein the stacking tray is tilted substantially in the same manner as the accumulation means. The sheet post-processing apparatus according to claim 1 or 2, wherein 5. The sheet post-processing apparatus according to claim 4, wherein the stacking unit includes a driving unit that raises and lowers the stacking tray according to an amount of sheets transferred from the post-processing unit. . 6. The stacking means includes: a vertical wall supporting one edge of the stacked sheets at the downstream end of the stacking tray in the inclined direction; A vertical wall supporting the edge, and at least a part of the stacking tray is provided with an inclined portion or a projecting portion so that the sheets transferred from the post-processing means by the transfer means are diversified in the transport direction. The sheet post-processing device according to claim 4, wherein the sheet post-processing device is provided. 7. A conveying means for conveying a sheet from an image forming unit, a processing tray for temporarily accumulating the sheets conveyed by the conveying means in an inclined state, and a sheet or a sheet bundle accumulated on the processing tray Post-processing means for performing post-processing in the vicinity of the inclined downstream, transfer means for transferring the post-processed sheets or sheet bundle in a direction intersecting the tilt direction of the processing tray, and sheets or sheets transferred by the transfer means. An image forming apparatus, comprising: stacking means for stacking and storing the sheet bundle in substantially the same inclined state as the processing tray. 8. The sheet post-processing apparatus and the image forming apparatus according to claim 1, wherein substantially the same inclined state has an error within 10 degrees.