Patent Grant
8141861
1. Field of the Invention
The present invention relates to a sheet processing apparatus which produces a sheet bundle of a folded booklet shape and an image forming apparatus which includes the sheet processing apparatus.
2. Description of the Related Art
In related art, there has been an image forming apparatus for forming an image on a sheet with a sheet processing apparatus which produces a booklet by binding and folding the bundled sheets on which images are formed by the apparatus main body, as disclosed in US20070060459, for example.
With such an image processing apparatus of the related art, the sheets conveyed to a stack tray are aligned after being received sequentially at a binding position where the center parts of the sheets are to be bound. Then, the sheet bundle is conveyed to a folding position which is located downstream the binding position to match the center part with a fold-line to be folded after or without being bound at the center parts of the sheets. Then, the sheet bundle is thrust at the center part by a thrusting member so as to be thrust into a nip of a pair of folding rollers. Accordingly, the sheet bundle is folded while being conveyed by the pair of folding rollers.
The top part of the folded portion is processes so that the fold-line is reinforced by a pair of press rollers which is different from the pair of folding rollers being moved along the fold-line of the sheet (in the direction orthogonal to the sheet conveying direction). Then, the sheet bundle subjected to the folding process is conveyed and discharged to a folded bundle discharging tray. In this manner, a booklet can be obtained as a product.
In the sheet processing apparatus in the related art, as described above, the stacked sheets or the stacked sheet bundle have been conveyed to the folding position at the downstream side of the conveying direction after being aligned at the binding position even when performing the folding process without the binding process (hereinafter, called non-binding folding). Therefore, there is a possibility that folding accuracy is declined by shifting of the sheets during the sheet bundle is conveyed. Further, since the sheet bundle conveyance takes time, productivity is decreased.
The present invention provides a sheet processing apparatus which has high folding accuracy and high productivity while suppressing poor conveyance stacking.
According to an aspect of the present invention, there is provided a sheet processing apparatus including: a conveying portion which conveys a sheet; a stacking portion on which the sheet conveyed by the conveying portion is stacked; a first processing unit which performs a process to the sheet at a first process position on the stacking portion; a second processing unit which performs a process to the sheet at a second process position on the stacking portion, the second process position being at the downstream side in the conveying direction of the first process position; and a controlling portion which performs positioning of the sheet at the first process position when the first processing unit performs the process to the sheet and positioning of the sheet at the second process position when the second processing unit performs the process to the sheet which is passed through the first process position without being positioned.
According to the present invention, folding accuracy and productivity can be improved while suppressing poor conveyance stacking.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
The sheet processing apparatus of the first embodiment according to the present invention is described with reference to the drawings.
(Image Forming Apparatus)
A scanner unit 104 reads an image of a document D which is set at a tray 1001 of the document feeding portion 100. The image data of the read document D is conveyed to an exposure controlling portion 110 after being subjected to a predetermined image process. The exposure controlling portion 110 outputs a laser beam corresponding to the image signal. The laser beam is irradiated on a photosensitive drum 111 while being scanned by a polygon mirror 110a. An electrostatic latent image corresponding to the scanned laser beam is formed on the photosensitive drum 111.
The electrostatic latent image formed on the photosensitive drum 111 is developed by a development device 113 so as to be visualized as a toner image. On the other hand, a sheet P is conveyed to a transfer portion 116 from any one of cassettes 114, 115, a manual feeding portion 125 and a duplex conveying path 124. Then, the visualized toner image is transferred onto the sheet P at the transfer portion 116. The toner image transferred onto the sheet P is fixed at a fixing portion 177. The photosensitive drum 111 and the development device 113 configure an image forming portion. The sheet P is discharged to the folding process portion 400 by a discharging roller 118 after passing through the fixing portion 177.
(Folding Process Portion 400)
Next, the configuration of the folding process portion 400 is described. In
(Finisher 500)
The configuration of the finisher 500 is described with reference to
As illustrated in
A punch unit 530 is provided between the pair of conveying rollers 502 and the pair of conveying rollers 503. The punch unit 530 operates as needed so as to punch the conveyed sheet P (i.e., performs a punch process) at the trailing end part thereof.
A switching member 513 provided at the end part of the conveying path 520 switches the path of the downstream side between an upper discharge path 521 and a lower discharge path 522. The upper discharge path 521 guides the sheet P to a sample tray 701 with an upper discharging roller 509. On the other hand, the pairs of conveying rollers 510, 511, 512 are provided at the lower discharge path 522. The pairs of conveying rollers 510, 511, 512 discharge the sheet P to a process tray 550.
The sheets P discharged to the process tray 550 are stacked in a bundle shape while being sequentially aligned and are subjected to the sorting process or the stapling process in accordance with settings of an operating portion 1 in
The stapling process is performed by a stapler 560. The stapler 560 moves in the width direction (i.e., the direction crossing to the conveying direction) of the sheet and binds the sheet bundle at an arbitrary position. The stack tray 700 and the sample tray 701 are lifted and lowered along a main body 500A of the finisher 500. The sample tray 701 at the upper side receives the sheets P from the upper discharge path 521 and the process tray 550. The stack tray 700 at the lower side receives the sheets P from the process tray 550. Accordingly, large amount of sheets are stacked onto the stack tray 700 and the sample tray 701. The stacked sheets are aligned by being received at the trailing ends thereof by a trailing end guide 710 which extends in the vertical direction.
(Saddle Stitch Binding Portion 800)
Next, the configuration of the saddle stitch binding portion 800 which is included in the finisher 500 is described. Here, in the following description, a “folding process” denotes a process to fold the sheet bundle with a pair of folding rollers 810 and a thrusting member 830 which configure a folding unit (i.e., a second processing unit). Further, a “creasing process” denotes a process to crease the sheet bundle subjected to the folding process with a pair of press rollers 861.
A switching member 514 arranged at some midpoint of the lower discharge path 522 switches the conveying direction of the sheet P to the right side so as to guide to a saddle discharge path 523 which guides to the saddle stitch binding portion 800.
A pair of saddle entrance rollers (i.e., a conveying portion) 801, a storing guide (i.e., a stacking portion) 803, a conveying roller 804 and a positioning member (i.e., a receiving member) 805 are arranged in order from the entrance of the saddle stitch binding portion 800. The storing guide 803 stores the sheets P while being configured to be approximately vertical (75° in the drawings) in order to downsize the finisher 500.
The pair of saddle entrance rollers 801 and the conveying roller 804 are rotated by a conveying motor M1. The conveying roller 804 is supported by a driving source (not illustrated) to be capable of contacting to and separating from the sheet. Accordingly, the conveying roller 804 can perform the operation of contacting and separating at predetermined timing. Further, a stapler 820 serving as a first processing unit is provided at some midpoint of the storing guide 803 as being opposed to sandwich the storing guide 803. The stapler 820 includes a driver 820a which projects a staple and an anvil 820b which folds the projected staple. The stapler 820 serving as the first processing unit performs the binding process serving as a first process to the sheet bundle at the binding position (i.e., a first process position).
A first sorting member (i.e., a guiding member) 802a and a second sorting member (i.e., a guiding member) 802b which are operated by solenoids SLa, SLb in accordance with the sheet size (i.e., the length in the conveying direction) stored in the storing guide 803 are illustrated in
In the state that the solenoids SLa, SLb are not powered, the sorting members 802 are rotated so that one end thereof projects from a guide plate so as to guide the top end of the sheet P to be inserted in the direction to a stack tray 15, as illustrated in
Specifically, the positioning member 805 is supported by a support frame 76 being free to slide, as illustrated in
As basic operation of the positioning member 805, the positioning member 805 can adjust the position by being lifted and lowered to receive the top end (i.e., the downstream end) of the sheet so that the center part of the sheet in the conveying direction is located at the binding position of the stapler 820 when the sheet is conveyed in the state that a saddle stitch binding process is specified. The positioning member 805 is lifted and lowered by the drive motor 74 (M2) and is stopped at a position in accordance with the sheet size (i.e., the length in the conveying direction). In the description of the present embodiment, the positioning member 805 is configured to receive the downstream end of the sheet in the conveying direction. However, the positioning member 805 may be configured to receive the upstream end of the sheet in the conveying direction depending on the sheet conveying direction to the storing guide 803 as switch-back conveyance, for example. In short, the present invention is applicable to the configuration that one end of the sheet in the conveying direction is received by the positioning member 805.
As illustrated in
The thrusting member 830 having a home position at a position retracting from the storing guide 803 is capable of being thrust by the motor M3. When the sheet bundle is stored in the storing guide 803, the thrusting member 830 thrusts toward the sheet bundle and pushes the sheet bundle into a nip between the pair of folding rollers 810a, 810b. Then, the thrusting member 830 returns to the home position again. A force F11 which is sufficient for the folding process to fold the sheet bundle is applied between the pair of folding rollers 810 by a spring (not illustrated).
The sheet bundle folded by the pair of folding rollers 810 is discharged onto a folded bundle discharging tray 840 via a pair of first fold conveying rollers 811a, 811b and a pair of second fold conveying rollers 812a, 812b.
Forces F12, F13 which are sufficient to convey and stop the folded sheet bundle are applied as well between the pair of first fold conveying rollers 811a, 811b and between the pair of second fold conveying rollers 812a, 812b.
A conveying guide 813 guides the sheet bundle between the pair of folding rollers 810 and the pair of first fold conveying rollers 811. A conveying guide 814 guides the sheet bundle between the pair of first fold conveying rollers 811 and the pair of second fold conveying rollers 812. Here, the pair of folding rollers 810, the pair of first fold conveying rollers 811 and the pair of second fold conveying rollers 812 are rotated at a constant speed by the single motor M4 (see
The sheet bundle which is specified to the saddle stitch binding is bound at the binding position by the stapler 820. Then, the sheet bundle is lowered by a predetermined distance from the position for the stapling process by the positioning member 805 so that the binding position of the sheet bundle is matched with the nip position (hereinafter, called the folding position) of the pair of folding rollers 810. Subsequently, the folding process is performed. As a result, the sheet bundle is folded at the position subjected to the stapling process (i.e., the bound position) as the center.
An alignment plate 815 performs aligning in the width direction of the sheet P which is stored in the storing guide 803. The alignment plate 815 moves the sheet P in the sandwiching direction with a motor M5 (see
A fold-line press unit 860 is provided serving as a fold portion processing unit at the downstream of the pair of second fold conveying rollers 812. The fold-line press unit 860 has a press holder 862 which supports a pair of press rollers 861. The fold-line is reinforced by moving the press holder 862 in the fold-line direction in the state that the folded part is nipped by the pair of press rollers 861. A first conveying belt 849 is arranged directly below the fold-line press unit 860. The sheet bundle is conveyed to a second conveying belt 842 from the first conveying belt 849, and then, stacked onto a discharging tray 843 from the second conveying belt 842.
(Inserter 900)
The inserter 900 is provided at the upper part of the finisher 500. The inserter 900 inserts an insert sheet at the top page, the last page or some middle page of the sheet P on which an image is formed by the printer portion 300. The inserter 900 feeds the sheet bundle stacked onto insert trays 901, 902 while sequentially separating one sheet by one sheet to the conveying path 520 of the finisher 500 at predetermined timing.
(Controlling Portion of the Copying Machine 1000)
Next, the configuration of the controlling portion of the copying machine 1000 which is the image forming apparatus main body is described with reference to
The document feeding controlling portion 101 controls the document feeding portion 100. The image reader controlling portion 201 controls the image reader portion 200. The printer controlling portion 301 controls the printer portion 300. The folding process controlling portion 401 controls the folding process portion 400. The finisher controlling portion 515 respectively controls the finisher 500, the saddle stitch binding portion 800 and the inserter 900.
The operating portion 1 includes a plurality of keys for setting various functions regarding the image forming and a display portion for displaying a setting state. The operating portion 1 outputs a key signal which corresponds to each key operation by the user to the CPU circuit portion 150 and displays the corresponding information at the display portion based on the signal from the CPU circuit portion 150.
A RAM 152 is used as an area for temporarily storing control data and as a work area for calculation relating to the control. The external I/F 203 is an interface between the copying machine 1000 and an external computer 204. The external I/F 203 develops print data from the computer 204 into a bit-mapped image and outputs the bit-mapped image to the image signal controlling portion 202 as image data. Further, the image of the document D which is read by an image sensor (not illustrated) is output to the image signal controlling portion 202 from the image reader controlling portion 201. The printer controlling portion 301 outputs the image data from the image signal controlling portion 202 to an exposure controlling portion (not illustrated).
Further, sheet conditions such as a sheet type (plain paper, coated paper or special paper) and a sheet size are input by the use's operation with an operation panel of the image forming apparatus main body. The CPU circuit portion 150 can acquire and recognize the sheet conditions. In addition to the abovementioned sheet size, the sheet conditions include stiffness, thickness, grammage (i.e., basis weight), property values (i.e., surface properties) such as resistance and smoothness, and sheet types such as punch paper and tab paper.
(Controlling Portion of the Finisher 500)
The control configuration of the finisher 500 serving as the sheet processing apparatus is described with reference to
Detection signals from an entrance detection sensor 62, a receiving member detection sensor 63 and a conveying roller position detection sensor 64 are input to the CPU 60 as the input data via an input interface circuit 57. A variety of control signals are output from the CPU 60 via an output interface circuit 58. The output signals are transmitted to control device such as a motor driver and operate the conveying motor M1, the flapper solenoids SLa, SLb, the positioning member moving motor M2 and the conveying roller separating motor M10 by controlling the control device. Further, data communication of sending and receiving is performed between the CPU circuit portion 150 which is provided at the copying machine 1000 side and the CPU 60.
Here, in the description of the present embodiment, the finisher controlling portion 515 which controls the finisher 500 is configured to be arranged at the finisher 500. However, it is also possible to arrange the finisher controlling portion 515 at the image forming apparatus main body side integrally with the CPU circuit portion 150.
(Sheet Conveyance Operation at the Saddle Stitch Binding Portion 800)
Next, the conveyance operation of the sheet at the saddle stitch binding portion 800 is described with reference to
As described in
In the case that the staple binding is performed (i.e., the saddle stitch binding mode), the positioning member 805 is moved (S2) so that the center of the sheet P is to be the binding position, as illustrated in
In the case that only folding process is performed without performing the staple binding (i.e., the non-binding folding mode) is specified (S1), the positioning member 805 is moved (S14) so that the center of the sheet P is to be the folding position, as illustrated in
With abovementioned configuration, at different aligning positions, jams caused by the interference between the trailing end of the stacked sheet P and the top end of the subsequent sheet P which is inserted to the storing guide 803 can be suppressed. Accordingly, the sheet can be conveyed from the pair of saddle entrance rollers 801 directly to the binding position and the folding position. Therefore, folding accuracy and productivity can be improved while suppressing poor conveyance stacking.
Here, with the abovementioned structure, there may be a case that the sheets may not be stacked at the folding position depending on the sheet size to be processed. In this case, the trailing end of the stacked sheet interferes with the top end of subsequent sheet depending on the positions where the first sorting member and the second sorting member (i.e., flappers) are located, namely, the sorting at the trailing end may not be performed. Provided that the positions of the first sorting member and the second sorting member (i.e., flappers) correspond to the sheet size to be processed, the sheets can be sorted so that the trailing end of the stacked sheet bundle is not to be into collision with the top end of the sheet P which is subsequently conveyed. In other words, the top end of the sheet P which is subsequently conveyed only needs to be contacted to the upper surface of the stacked sheet bundle at the downstream in the conveying direction of the trailing end of the sheet bundle which is previously stacked at the folding position.
In this case, the stack position is controlled to be changed depending on the sheet size, as described in
As described above, in the case that the non-binding folding mode is selected and the sheet size is the predetermined size, the stacking is performed at the folding position and the folding process and the creasing process are performed so that the job ends (S14 to S22 and S42).
In the case that the sheet size is not the predetermined size, for example, in the case of small size sheets (i.e., the trailing end of the stacked sheet interferes with the stapler), the positioning member 805 moves to the binding position as the binding mode (S32). While the flapper solenoids SLa, SLb remain non-powered (S33), the sheet P is inserted (S34) and is aligned (S35). Then, after all the sheets are stacked (S36), the whole sheet bundle is conveyed to the folding position (S37). Then, the folding process and the creasing process are performed and the job ends (S38 to S42).
In the case of a non-standardized sheet size, the positioning member 805 is moved to the position where the trailing end sorting can be performed (i.e., the position being matched to the sorting member, namely, the flapper). The sheets are stacked thereto and the whole sheet bundle is conveyed to the folding position after all the sheets are stacked. In this manner, the sheets of a size other than the predetermined size can be stacked as well.
Here, two units of the stapler (i.e., the first processing unit) 820 and the folding unit (i.e., the second processing unit) are described as examples of the sheet processing unit. However, it is also possible to configure to arrange the punch unit below the stapling unit and to arrange a cut unit below the punch unit. When stapling is performed in this case, the sheets are conveyed and stacked directly to the binding position and each sheet bundle is stapled and discharged. When punching is performed, the sheets are conveyed and stacked directly to a punch position and each sheet bundle is punched and discharged. When cutting is performed, the sheets are conveyed and stacked directly to a cut position and each sheet bundle is cut and discharged. Instead, the apparatus may be configured to discharge the bundle after all the processes are performed.
Next, the sheet processing apparatus of the second embodiment according to the present invention is described with reference to the drawings. The same numeral is given to the same part as the above-mentioned first embodiment and the redundant description is omitted.
A holding member rotating motor 43 is a motor which rotates the holding member 11 and the holding shaft 31. The holding member rotating motor 43 applies driving force to a drive gear portion 42 and drives a drive shaft 41 to rotate. The drive shaft 41 transmits the driving force to the holding shaft 31 via a drive portion 40 which is arranged at the supporting member 35 and drives the holding shaft 31 to rotate. The sorting portion of the present embodiment is configured with the holding member 11, the holding shaft 31, the drive portion 40, the drive shaft 41, the drive gear portion 42 and the holding member rotating motor 43.
A holding member position detection sensor 44 serving as a sensor portion detects the rotating position of the holding member 11 by detecting the rotating angle of the drive shaft 41. The position of the holding member 11 which is rotated by the holding member rotating motor 43 is controlled based on the detection result.
With the abovementioned configuration, the holding member 11 is capable of being moved to a sheet holding position (i.e., the solid-line position in
The supporting member 35 is supported to a moving shaft 49 being free to slide via a slide bush 50 which is fixedly provided at the supporting member 35. Slide rails 38, 39 are fixed at both end sides of the frame 30 in X-axis direction. Slide bushes 36, 37 which are fixedly provided to the supporting member 35 are attached on the slide rails 38, 39 being free to slide.
Further, a timing belt 48 is attached at an approximate middle part of the frame 30. The longitudinal direction of the timing belt 48 is along Y-axis direction. A holding member moving motor 45 transmits driving force to the timing belt 48 via a drive portion 46. A supporting member position detection sensor 51 serving as the sensor portion detects the position of the supporting member 35. The position in Y-axis direction of the supporting member 35 which is moved by the holding member moving motor 45 is controlled based on the detection result.
With such the configuration, the holding member 11 is movable in the conveying direction of the sheet P to be at the positions in
Further, as illustrated in
The abovementioned configuration is different from the sorting member of the first embodiment which works only for the predetermined sheet size. In other words, the sheets can be sorted so that the trailing end of the stacked sheet bundle is not to be into collision with the top end of the sheet P which is subsequently conveyed while holding the trailing end (i.e., the upper end) of the stacked sheet bundle even in the case that the size of the sheets to be stacked is uneven.
Here, for the sheet sorting, it may be considered that the pair of saddle entrance rollers 801 is configured to move in the conveying direction in accordance with the sheet size. However, by simply arranging the angle of the sheet-passing guide surface 11a as described above, it is not needed that the pair of saddle entrance rollers 801 is configured to move in the conveying direction in accordance with the sheet size. Therefore, the apparatus can be compact.
Next, a tapping member 12 is described.
As illustrated in
In this manner, the tapping member 12 and the holding member 11 sort the trailing end of the stacked sheet and the top end of the subsequent sheet by being operated for each sheet which is to be stacked.
In the present embodiment, the holding member 11 which is movable in accordance with the sheet length is arranged along the stack tray 15. Therefore, the subsequent sheet can be inserted in the state that the trailing end (i.e., the upper end) of the stacked sheet bundle is held even when the sheet to be stacked is a non-standardized size. Consequently, the sheet can be conveyed from the pair of saddle entrance rollers 801 directly to the binding position and the folding position without a jam caused by the interference between the trailing end of the stacked sheet and the top end of the subsequent sheet to be inserted to the storing guide 803.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2008-181251, filed Jul. 11, 2008, and No. 2009-152305, filed Jun. 26, 2009, which are hereby incorporated by reference herein in their entirety.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2008-181251 | Jul 2008 | JP | national |
| 2009-152305 | Jun 2009 | JP | national |
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| Number | Date | Country | |
|---|---|---|---|
| 20100007072 A1 | Jan 2010 | US |
