JP2008189475A - Sheet processing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To permit off-set loading of a sheet bundle on a stack tray of a sheet processing device and maintain an aligning property of the sheet bundle. <P>SOLUTION: The sheet bundle aligned by an aligning member is discharged on the stack tray 200 on a processing tray 130 by a first mode in which sheets are conveyed in a bundle after bundle shift and a second mode in which sheets are conveyed in a bundle without the bundle shift. Consequently, the aligning property of the sheets is maintained while off-set loading of the stack tray is enabled. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a sheet processing apparatus, and more particularly, to a sheet processing apparatus that is provided in an image forming apparatus such as a copying machine and processes discharged sheets.

  Conventionally, a first sheet stacking unit (hereinafter referred to as a processing tray) for aligning image-formed sheets and performing sheet processing (also referred to as post-processing) such as staple binding, and sheet bundles are received and stacked for each bundle. Many devices including a second sheet stacking unit (hereinafter referred to as a stack tray) have already been proposed and implemented, including the technique disclosed in, for example, Japanese Patent Laid-Open No. 2-144370. Among them, in order to make it possible to identify the bundle on the stack tray, or to prevent the stacking height of the staple binding portion from increasing and the upper surface of the sheet bundle from becoming a uniform surface, Offset loading, in which a predetermined amount is alternately shifted, is also devised.

  However, as an embodiment of the offset stacking, in the type in which the stack tray shifts itself, it is effective if the stacking capacity on the stack tray is small. Further, in order to increase the load for shifting the stack tray and to maintain the stacked state of the sheet bundle, further improvements are desired from the viewpoint of bundle breakage, dropping, and the like.

  Also, a type has been devised in which the alignment position of the sheet bundle on the processing tray is alternately changed for each bundle, and the sheet bundle is discharged from that position to enable offset on the stack tray. However, since the alignment position of the sheet bundle is different, it is necessary to move the sheet processing means (post-processing means) in accordance with the offset amount of the sheet bundle, and the configuration of the post-processing means section becomes complicated.

  In addition, the alignment conditions of other mechanisms differ depending on the alignment position of the sheet bundle (for example, the amount of movement of the sheet, the alignment direction of the sheet, and other load conditions during alignment with respect to the sheet discharge position). There is a possibility that accurate sheet alignment cannot be obtained.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a sheet processing apparatus that enables offset stacking of sheet bundles on a stack tray and simplifies the configuration for avoiding misalignment of sheets.

  The present invention includes a first stacking unit that stacks discharged sheets, a bundle transport unit that transports a bundle of sheets stacked on the first stacking unit, and a sheet bundle that is transported by the bundle transport unit. And stacking the second stacking unit by changing the bundle discharge position in the direction intersecting the transport direction of the sheet bundle conveyed by the bundle transporting unit for each bundle. In the sheet processing apparatus, the aligning unit capable of aligning sheets at different alignment positions on the first stacking unit in a direction intersecting the transport direction, and the sheet bundle aligned on the first stacking unit Bundle shifting means for shifting the bundle in a direction intersecting the conveying direction, and in the case of a sheet having a size having a first sheet width in the direction intersecting the conveying direction, the alignment position is conveyed for each bundle. Direction and intersection The sheet bundle is conveyed to the second stacking unit by the bundle conveying unit without performing the shift operation by the shift unit, and the second sheet is smaller than the first sheet width. In the case of a sheet having a size having a sheet width, the sheets are aligned on the first stacking means without changing the alignment position for each bundle, and the bundle discharging position of the aligned sheet bundles by the shift means Then, the bundle conveying unit conveys the sheet bundle to the second stacking unit.

  According to the present invention, the sheet bundle on the first stacking unit is alternately shifted to the sheet bundle alignment position or the sheet bundle processing position, and the bundle discharge position of the sheet bundle is changed to discharge the bundle. As a result, it is possible to maintain consistency even with sheets of various sizes without impairing the conventional bundle identification by offset stacking by offset of the second stacking means and offset stackability on the second stacking means. An inexpensive device configuration that can be maintained can be realized.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to FIGS.

  First, an image forming apparatus according to the present invention, here, an image forming apparatus including a sheet processing apparatus will be described.

  Based on FIG. 26, the configuration of an image forming apparatus including a document conveying device and a sheet processing device will be described.

  The ADF 2 that is a document conveying device (sheet material conveying device) has a document tray 4 on the upper side, and a wide belt wound around a driving roller 36 and the other turn roller 37 is arranged below the document tray 4. A document (sheet material) P on the document tray 4 is sequentially separated and fed from the uppermost sheet by a separating unit, and is conveyed to a platen glass (platen) 3 which is a reading position (image reading unit) of the copying machine main body. .

  The wide belt is in contact with the platen 3 so as to rotate forward and backward, and the sheet material original P conveyed from the original tray 4 is placed on a predetermined position on the platen 3 or the sheet on the platen 3 is placed. The material original P is carried out onto the paper discharge tray 10. The documents P are placed on the document tray 4 in the order of 1 page (2 pages), 3 pages (4 pages),.

  A copying machine main body 1 'as an image forming apparatus main body includes an image input unit 200' (hereinafter referred to as a reader unit) and an image output unit 300 (hereinafter referred to as a printer unit).

  The reader unit 200 ′ optically reads image information recorded on the original P, photoelectrically converts it and inputs it as image data. The reader unit 200 ′ includes a scanner unit 204 having a platen 3, a lamp 202, and a mirror 203; A mirror 203a, a lens 205a, an image sensor 205b, and the like are included. The printer unit 300 is an image forming unit that uses well-known electrostatic latent image image formation.

  Next, the printer unit 300 that is an image output unit will be described.

  Reference numeral 800 denotes an upper cassette, and sheet materials in the cassette are separated and fed one by one by the action of the separation claw and the feeding roller 801 and guided to the registration roller 806. Reference numeral 802 denotes a lower cassette. The sheet material in the cassette is separated and fed one by one by the action of the separation claw and the feeding roller 803 and guided to the registration roller 806. Reference numeral 804 denotes a manual feed guide, and the sheet material is guided to the registration roller 806 via the roller 805 one by one. Reference numeral 808 denotes a sheet material stacking device (deck type) which includes an intermediate plate 808a that is moved up and down by a motor or the like. The sheet material on the intermediate plate is separated and fed one by one by the action of a feeding roller 809 and a separation claw and conveyed. Guided to roller 810.

  Reference numeral 812 denotes a photosensitive drum, 814 denotes a developing unit, 815 denotes a transfer charger, and 816 denotes a separation charger, and constitutes an image forming unit.

  Reference numeral 817 denotes a conveyance belt that conveys a sheet material on which an image is formed, 818 denotes a fixing device, 819 denotes a conveyance roller, and 820 denotes a flapper. The sheet material on which the image is formed is guided to a main body discharge roller (main body discharge means) 821 by a flapper 820 and discharged to a downstream sheet processing apparatus.

  An image is formed on the photosensitive drum 812 according to the set number of copies for one document placed on the platen, and the sheet material corresponding to the number of copies is one of the cassette 800, 802, or the deck 808. Therefore, the image is fed every time an image is formed on the photosensitive drum. The registration roller 806 aligns the image on the photosensitive drum 812 and the sheet material.

  When the required number of copies is formed, the document is discharged from the platen, and the next document is positioned on the platen. The same applies hereinafter.

  Reference numeral 900 denotes an intermediate tray. When an image is formed on both sides of a sheet material, or when an image is formed by overlapping one side of a sheet material (multiple), the sheet material on which the image is formed is once inserted into the intermediate tray 900. To stock. Reference numeral 901 denotes a conveyance roller, 902 denotes a conveyance belt, 903 denotes a flapper, 904 denotes a conveyance belt, and 905 denotes a conveyance roller. In the case of duplex copying, the sheet material is guided to the intermediate tray 900 through a path 906.

  The sheet material has the image surface facing upward. In the case of multiple copying, the sheet material is guided to the intermediate tray 900 through a path 907. The sheet material has the image surface facing downward.

  The sheet materials stacked on the intermediate tray 900 are separated one by one from the bottom by the action of the auxiliary rollers 909 and 910 and the forward / reverse separating roller pair 911 and are re-fed. The re-fed sheet material is guided to the image forming unit via conveying rollers 913, 914, 915, a roller 810, and a registration roller 806. After image formation, it is discharged as described above.

  First, one-sided copying is performed according to the number of copies set for one document placed on the platen, and these are stacked on the intermediate tray 900. Thereafter, the front and back of the document on the platen are reversed and guided again onto the platen, and this image is read by the number of copies. The read image is formed on a sheet material that is re-fed from the intermediate tray 900 every time it is read. On the other hand, there is a method in which only one set of copies is created each time a document is circulated by an automatic document feeder. According to this method, even when a plurality of copies are created, a copy group with the same page order is obtained in order, so that the necessary number of copies can be obtained by sorting without a sorter. When making a double-sided copy with this method, scan both sides of a single document, copy and discharge it continuously on the front and back of the sheet, and then do the same for both sides of the next document. If repeated many times, a divided double-sided copy group is obtained.

  An image-formed sheet discharged from the copying machine main body is discharged to a sheet processing apparatus (also referred to as a finisher) 1 by a main body discharge roller (main body discharge means) 302.

  In the non-sort mode, the sheet carried from the copying machine main body 1 ′ is discharged to the sample tray 201 by the discharge roller 9 through the buffer roller 5, the flapper 11, and the non-sort mode path 21. In the sort mode, the paper is temporarily stacked on the processing tray 130 as an intermediate tray by the discharge roller 7 via the buffer roller 5, the flapper 10, and the sort mode path 22. The sheet bundle on the processing tray 130 is aligned on both sides in the direction intersecting the sheet conveying direction by an alignment member (not shown), and the sheet trailing edge is bound by the stapler 100 (101) as necessary. After that, the sheet is discharged onto the stack tray 200 by the bundle discharge roller pair 180a and 180b.

  Next, the sheet processing apparatus according to the present invention will be described.

<Overview of the entire sheet processing apparatus>
First, the main components of the sheet processing apparatus will be described.

  FIG. 1 is an overall cross-sectional view schematically showing a schematic configuration of a sheet processing apparatus according to the present embodiment.

  In the configuration of the sheet processing apparatus (hereinafter referred to as “finisher”) 1 shown in this figure, 2 is an inlet roller pair that receives the sheet P discharged from the discharge roller pair 302 of the image forming apparatus 300, and 3 is received. A pair of first conveying rollers for conveying the sheet P, 31 is a seam detection sensor on the entrance side for detecting the passage of the sheet P. Reference numeral 50 denotes a punch unit that punches holes near the rear end of the conveyed sheet. Reference numeral 5 denotes a relatively large-diameter roller (hereinafter referred to as “buffer roller”) arranged in the course of conveyance, and the sheet P is conveyed against the roll surface by the pressing rollers 12, 13, and 14 disposed around the outside. .

  Reference numeral 11 denotes a first switching flapper that selectively switches between the non-sort path 21 and the sort path 22. A second switching flapper 10 switches between the sort path 22 and the buffer path 23 for temporarily storing sheets P. Reference numeral 33 denotes a sensor that detects the sheet P in the non-sort path 21, and reference numeral 32 denotes a sensor that detects the sheet P in the buffer path 23.

  Reference numeral 6 denotes a second conveying roller pair of the sort path 22, and 129 temporarily accumulates the sheets P, aligns the accumulated sheets P, and staples the staple unit 101 (binding means) with the stapler 101. This is a processing tray unit including an intermediate tray (hereinafter referred to as “processing tray”) 130 provided for performing the above-described processing. On the discharge end side of the processing tray (first stacking tray) 130, one discharge roller constituting a bundle discharge roller pair (transfer means), here, a lower discharge roller 180a as a fixed side is disposed. Reference numeral 7 denotes a first discharge roller pair which is arranged in the sort path 22 and discharges the sheet P onto the processing tray (first stacking tray) 130, and 9 is arranged in the non-sort path 21 to place the sheet P on the sample tray. 201 is a second discharge roller pair for discharging onto 201.

  180b is supported by the swing guide 150, and when the swing guide 150 comes to the closed position, the sheet P on the processing tray 130 is pressed against the lower discharge roller 180a in a stack tray. (Second stacking tray) An upper discharge roller for discharging a bundle onto the 200. Reference numeral 40 denotes a bundle stacking guide that supports the rear end (rear end with respect to the bundle discharge direction) edge of the sheet bundle stacked on the stack tray 200 and the sample tray 201. Also serves as.

<Detailed description of staple unit>
Next, regarding the staple unit (binding means) 100 constituting one of the main parts of the present invention, in particular, FIG. 2 (a side view corresponding to the main cross section), FIG. 3 (a plan view in the direction of arrow a in FIG. 2) and This will be described in detail with reference to FIG. 4 (a rear view in the direction of arrow b in FIG. 2).

  A stapler (binding means) 101 is fixed on the moving table 103 via a holder 102.

  The moving table 103 has a pair of stud shafts 104 and 105 fixed in parallel to the trailing edge of the sheets stacked on the processing tray 130. The moving rollers 106 and 107 are rotatably assembled, and each of the rolling rollers 106 and 107 is formed in a series of hole-shaped guide rails 108a and 108b that are similarly drilled and formed in parallel with the fixed base 108. , 108c are movably engaged.

  Each of the rolling rollers 106 and 107 has flanges 106a and 107a having a diameter larger than the hole width of the series of hole-shaped guide rails 108a, 108b, and 108c, and on the other hand, the lower surface side of the moving table 103 that holds the stapler 101. The support rollers 109 are provided at three locations, and the moving table 103 moves on the fixed table 108 along a series of hole-shaped guide rails 108a, 108b, and 108c.

  Here, as is apparent from FIG. 3, the series of hole-shaped guide rails 108a, 108b, and 108c are parallel to the main guide rail hole portion (108a) and the left end guide rail branched from the left end side of the portion. The hole portion (108b) and the right end guide rail hole portion (108c) which is branched from the right end side and are parallel to each other are formed. Therefore, due to the rail shape of each part, when the stapler 101 is positioned on the left end side, the rolling roller 106 is in the left end portion of the rail hole portion 108b, and the rolling roller 107 is in the left end portion of the rail hole portion 108a. To each of the rolling rollers 106 and 107 are located in the rail hole portion 108a when they are positioned in the middle and are maintained in the right-tilt posture in a state where they are inclined to the right by a predetermined angle. When maintained in a non-inclined parallel posture and positioned on the right end side, the rolling roller 107 is in the right end of the rail hole portion 108c, and the rolling roller 106 is in the right end of the rail hole portion 108a. It is moved and maintained in a left-tilt posture in a state where it is tilted to the left by a predetermined angle, and these posture changing actions are performed by an operating cam (not shown).

  The staple unit 100 is provided with a position sensor (not shown) that detects the home position of the stapler 101. In the normal case, the stapler 101 stands by at the home position at the left end.

<Detailed explanation of stapler moving mechanism>
Next, the moving mechanism of the stapler 101 will be described in detail.

  One rolling roller 106 of the moving table 103 is integrally formed with a pinion gear 106b below the flange 106a, and is integrally provided with a belt pulley 106c. The pinion gear 106b is connected via a drive belt stretched between the output pulley of the drive motor M100 on the table surface and the belt pulley 106c, and is fixed to the fixed table 108 along the rail hole. The moving table 103 is movable in the sheet width direction together with the stapler 101 in response to the forward / reverse rotation of the drive motor M100.

  Further, a stopper tilting roller 112 is provided on the stud shaft 111 extending downward from the lower surface of the movable table 103. The stopper tilting roller 112 will be described later in detail, but the rear end stopper of the processing tray 130 will be described later. In order to avoid contact between 131 and the stapler 101, the rear end stopper 131 is rotated.

<Detailed explanation of rear end stopper>
Next, the trailing edge stopper 131 that abuts and supports the trailing edge of the sheet P on the processing tray 130 will be described in detail.

  The trailing edge stopper 131 is formed so as to rise perpendicularly to the stacking surface of the processing tray 130, and has a bumping support surface 13la that bumps and supports the trailing edge of the sheet P. The bumping support surface 13la is swingable downward on the lower surface side of the processing tray 130 with a pivot pin 131b as a center, as indicated by an arrow. Further, the main link 132 having the cam surface 132a that is pressed by the stopper tilting roller 112 abutting is positioned to abut against the abutting plate 136, and a shaft 134 fixed to a frame or the like (not shown) is provided. The other end long hole of the connecting link 133 which is pivotable against the tension spring 135 at the center and whose one end is pivotally supported on the rear end stopper 131 by the pin 13lc with respect to the pin 132b at the upper end. Are slidably linked to each other.

  Therefore, in this case, with respect to the rear end stopper 131 that interferes with the stapler 101 as the moving table 103 moves, the stopper tilting roller 112 of the moving table 103 presses the cam surface 132a of the main link 132. , It is swung to a non-interfering position indicated by a two-dot chain line in the figure, thereby avoiding contact with the stapler 101. Then, after the stapling process, which will be described later, is finished, the rear end stopper 131 also returns to the original state when the movable table 103 returns to the home position. Here, a plurality (three in this case) of the stopper tilting rollers 112 are arranged in the moving direction of the moving table 103 in order to keep the rear end stopper 131 in the avoidance position during the operation of the stapler 101. ing.

  Further, a staple stopper (indicated by a two-dot chain line in FIG. 2) 113 having a support surface having the same shape as the abutting support surface 13la of the rear end stopper 131 is attached to both side surfaces of the holder 102 that holds the stapler 101. Thus, even if the trailing edge stopper 131 is in the avoidance position, the trailing edge of the sheet can be supported.

<Overview of processing tray unit>
Next, the processing tray unit 129 including the processing tray 130 will be described in detail with reference to FIGS.

  The processing tray unit 129 includes a processing tray 130, a rear end stopper 131, an aligning unit 140, a swing guide 150, a drawing paddle 160, and a bundle discharge roller pair 180.

  In this case, the processing tray 130 is inclined by positioning the downstream side (upper left side in the drawing) upward and the upstream side (lower right side in the drawing) downward with respect to the sheet bundle discharge direction. The above-mentioned rear end stopper 131 is disposed at the lower end portion on the upstream side, and the aligning means 140 that occupies its left and right positions and includes a retraction paddle 160 described later is disposed at the intermediate portion. In addition, a swing guide 150 including a pull-in paddle 160 and a bundle discharge roller pair 180, which will be described later, is disposed at an upper end portion on the downstream side, specifically, an upper region portion of the unit configuration. .

  Then, the sheet P discharged from the first discharge roller pair 7 has its trailing edge pushed against the abutting support surface 13la of the trailing edge stopper 131 by its own weight and the action of a pull-in paddle 160 described later. Slide on the processing tray 130 until it is hit.

  Further, as described above, one lower discharge roller 180a constituting the bundle discharge roller pair 180 is disposed at the upper end portion of the processing tray 130, and the lower surface front end portion of the swing guide 150 is disposed at the lower end of the swing guide 150. The other upper discharge roller 180b that is detachably contacted with the lower discharge roller 180a is disposed, and each of these discharge roller pairs 180a and 180b can be rotated forward and backward by a drive motor M180. .

<Detailed description of alignment means>
Next, the aligning means 140 constituting the other main part of the present invention will be described in detail with reference to FIGS. 5 and 6 and FIGS. 7 and 8 that are C arrow views of FIG.

  A pair of aligning members 141 and 142 constituting the aligning means 140 are disposed on the surface of the processing tray 130 so as to face each other independently on a lower part and an upper part (corresponding to both side edges of the sheet P) in the drawing, The first alignment member 141 on one lower side and the second alignment member 142 on the other upper side are perpendicular to the surface of the processing tray 130 for pressing and supporting the sheet-side end surface. Each of the alignment surfaces 14la and 142a and rack gear portions 14lb and 142b for supporting the back surface of the sheet. The rack gear portions 14lb and 142b are formed in the vertical direction (sheet P). Are arranged on the lower surface side through a pair of guide grooves 130a and 130b parallel to the width direction of the first and second guide grooves.

  That is, in summary, the alignment surfaces 14la and 142a are arranged to face the processing tray 130 on the upper surface side, and the rack gear portions 14lb and 142b can move in the alignment direction on the lower surface side. It is assembled to.

  The rack gear portions 141b and 142b are meshed with individual pinion gears 143 and 144 that are driven to rotate in the forward and reverse directions by the drive motors M141 and M142, respectively. The alignment members 141 and 142 are movable in the alignment direction. Here, for the first and second alignment members 141 and 142, position sensors (not shown) for detecting the respective home positions are arranged. In a normal case, the first alignment member 141 is at the lower end. And the second alignment member 142 stand by at each home position position set at the upper end.

<Relationship between alignment position, bundle discharge position, and binding position>
Next, the relationship among the sheet bundle alignment position, the bundle discharge position to the stack tray 200, and the binding processing position according to the main part of the present invention will be described.

  Obviously, based on the above configuration, the alignment direction and alignment position of the sheet bundle with respect to the sheet discharge position can be arbitrarily set. Further, as described above, the binding processing position is divided into three areas, that is, a position that can be moved in the right tilt position, a position that can be moved in the left tilt position, and a position that can be moved in the parallel position. In this embodiment, the alignment position of the sheet bundle is set according to the above conditions and the sheet size.

<A4 size (alignment position, binding position, bundle discharge position are the same)>
In the above-mentioned size, which has relatively good alignment, can be tilted, and requires high productivity, as shown in FIG. Alternately, bundle alignment is performed by changing the alignment position by a predetermined amount. Thereafter, the binding process is performed, and the bundle is discharged at the same position.

<A4R size (the alignment position and the binding position are the same, but the bundle discharge position is different)>
For sizes that are poorly aligned and can be partly tilted, bundle alignment is performed with the alignment position and alignment direction fixed at the sheet discharge position, as shown in FIG. 6B, and then binding is performed. Execute the process. In the subsequent operation, the bundle to be discharged as it is and the aligning means pair are moved in the same direction by a predetermined amount to perform the bundle shift, and then the bundle to be discharged is alternately performed.

  Note that black arrows in FIG. 6 indicate the bundle shift direction of the sheet bundle.

<B5R size (the binding position is the same as the bundle discharge position but the alignment position is different)>
When the size is poor and the tilting posture is impossible, bundle alignment is performed with the alignment position and alignment direction being constant with respect to the sheet discharge position as shown in FIG. Thereafter, the bundle shift is performed while changing the movement amount of the matching means pair in the same direction and alternately. Thereafter, the binding process is performed, the bundle is discharged as it is, and the offset stacking is performed.

  As described above, the sheet bundle on the processing tray 130 is bundled on the stack tray 200 in the first mode in which the bundle is conveyed (bundle discharge) after the bundle shift and in the second mode in which the bundle is conveyed without the bundle shift. Since the sheets are discharged, the sheet alignment on the stack tray 200 can be offset and the sheet alignment can be maintained.

  Further, after the bundle processing by the stapler 101, the sheet bundle is shifted by the first mode in which the sheet bundle is shifted and conveyed and the second mode in which the sheet bundle after the bundle processing is transferred without changing the bundle. By discharging the bundle to the stack tray 200, it is possible to maintain the sheet alignment while enabling the stack stack 200 to be offset.

<Detailed explanation of swing guide>
Next, the swing guide 150 will be described in detail.

  As described above, the swing guide 150 is located at the front end of the lower surface corresponding to the downstream side (left side in FIG. 5), and pivots the upper discharge roller 180b that contacts the lower discharge roller 180a of the bundle discharge roller pair 180. At the same time, it is pivotally supported by a support shaft 151 at the rear end of the lower surface corresponding to the upstream side (the right side in FIG. 5), and swings by the control drive of the rotary cam 152 by the drive motor Ml50. Here, the closed state in which the upper discharge roller 180b is brought into contact with the lower discharge roller 180a is the home position, and a position sensor (not shown) for detecting this is provided.

  In a normal case, when each individual sheet P is discharged onto the processing tray 130, the upper discharge roller 180b is spaced apart from the lower discharge roller 180a and the swing guide 150 is swung upward. The sheet P is discharged and aligned, and the pull-in paddle operation described below can be performed without any trouble. When discharging onto the stack tray 200, the state is changed to a closed state (the upper discharge roller 180b comes into contact with the lower discharge roller 180a and the swing guide 150 swings downward).

<Detailed description of retractable paddle>
Next, the pull-in paddle 160 will be described in detail.

  The pull-in paddle 160 is fixed to the drive shaft 161 above the processing tray 130, and is driven to rotate counterclockwise in FIG. 5 at an appropriate timing by the drive motor Ml60. Is set to be slightly longer than the distance to the surface of the processing tray 130, and its home position is a position that does not hinder the discharge of the sheet P from the first discharge roller pair 7 onto the processing tray 130 (FIG. 5). (Solid line display position).

  Then, when the sheet P is discharged onto the processing tray 130 in this state, the pull-in paddle 160 is driven to rotate counterclockwise, whereby the sheet P discharged onto the processing tray 130, and thus the sheet. The rear end edge of P is retracted until it abuts against the abutting support surface 13la of the rear end stopper 131, and then waits for a predetermined time and stops at the home position detected by a position sensor (not shown) with good timing. .

<Detailed explanation of stack tray and sample tray>
Next, the stack tray 200 and the sample tray 201 will be described in detail with reference to FIGS.

  The stack tray 200 and the sample tray 201 are selectively used depending on the situation. The stack tray 200 disposed below is selected when receiving a sheet bundle for copy output, printer output, and the like, and is disposed above. The sample tray 201 is selected when receiving a sheet for sample output, interrupt output, stack tray overflow output, function output, job mixed load output, or the like.

  The stack tray 200 and the sample tray 201 are respectively held by the tray base plates 202 and 203, and stepping motors M200 and M201 fixed to the base plates 202 and 203 via the attachment frame plates 204 and 205, respectively. By using this, it is possible to independently run independently in the up and down direction. In this case, since both are configured in substantially the same mode, here, mainly on the stack tray 200 side only. State.

  That is, a pair of frames 250 and 250 are provided in the vertical direction at both ends of the sheet processing apparatus 1, and the rack gear members 251 that also serve as guide rails in the vertical direction with respect to the frames 250 and 250, respectively. 251 is attached to the rear end portion extended from one side of the tray base plate 202 (corresponding to the left end side with respect to the sheet width direction) and the mounting frame plate facing this (similarly corresponding to the right end side) A pair of guide rollers 206 that are rotatably provided at the rear end portion extended from 204 are used, and the respective guide rollers 206 are fitted and inserted into the corresponding guide rail portions, thereby the stack tray 200. By holding the regulating member 208a on the folded end edge of one frame 250, The play in the width direction is restricted and regulated.

  On the other hand, the rotation output of the stepping motor M200 is transmitted to the pulley 212 of the drive shaft 213 via the timing belt 211. The drive shaft 213 is provided with a ratchet wheel 215 that is urged by a spring 216 so that the drive shaft 213 can only slide in the axial direction. The ratchet wheel 215 is engaged with the drive gear 214 on the shaft in one direction. I'm allowed. The drive gear 214 is engaged with one of idler gears 207 and 207 disposed at both ends of the driven shaft 208, and the rack gear member is connected to the idler gears 207 and 207 via the elevating gears 209 and 209, respectively. 251 and 251 are engaged. That is, the stack tray 200 can be raised and lowered in the vertical direction via a drive system composed of these gear trains.

  In addition, the ratchet wheel 215 that is unidirectionally engaged with the drive gear 214 on the drive shaft 213 is when the stack tray 200 is lowered, and the drive system may be damaged, for example, with foreign matter or the like interposed therebetween. Here, the spring 216 is given a required biasing force, and only when the stack tray 200 is lifted, the spring 216 has a biasing force corresponding to a preset condition. When the idle state, that is, when an abnormality occurs, the clock slit formed in the flange portions of the idler gears 207 and 207 is immediately stopped to stop the driving of the stepping motor M200. Etc. are detected by the sensor S201. The sensor S201 is also used for step-out detection during normal operation.

  Next, sensor arrangements for controlling the raising / lowering positions of the stack tray 200 and the sample tray 201 will be described.

  The sensor S202 is a sensor for detecting the stacking area of the sample tray 201, and is located in a range belonging to the area from the rising limit position detection sensor S203a of the sample tray 201 to the processing tray sheet surface detection sensor S205. Detect.

  The sensor S203b is a sensor for detecting that a predetermined number of sheets P are discharged from the second discharge roller pair 9 onto the sample tray 201. Here, the non-sorted sheet surface detection sensor S204 to the sheet S It is arranged at a position equivalent to 1000 sheets.

  The sensor S203c is a sensor for detecting that a predetermined number of sheets P are discharged from the processing tray 130 onto the sample tray 201. Similarly, the sensor S203c is equivalent to 2000 sheets stacked from the sheet surface detection sensor S205. Placed in position.

  The sensor S203d is a sensor for limiting the height of the stacking amount when the stack tray 200 receives the sheet P from the processing tray 130, and is arranged at a position corresponding to 2000 sheets stacked from the sheet surface detection sensor S205. .

  The sensor S203e is a sensor that sets the lower limit position of the stack tray 200.

  The stack tray 200 and the sample tray 201 are provided with sheet presence / absence detection sensors 206a and 206b, respectively.

  Of these sensors, only the sheet surface detection sensors S204 and S205 are set to a light transmission type that detects the presence or absence of light by transmitting light from one side edge of the sheet P to the other side edge. Here, as the sheet surface detection method, the state in which the trays 200 and 201 are raised from below the sheet surface detection sensors S204 and S205 to a position covering them is initial, and the optical axis of the sensor after the sheets are stacked Is repeated until the sensor optical axis is covered again.

  Next, the flow of the sheet P in the sheet processing apparatus will be described as the sheet size A4.

<Flow of sheet P in non-sort mode>
When the user designates the non-sort setting for the paper discharge mode of the image forming apparatus, the first switching flapper 11 of the sheet processing apparatus 1 loads the sheet P on the non-sort path 21 side as shown in FIG. In this state, the inlet roller pair 2, the first conveying roller pair 3, and the buffer roller 5 are rotationally driven, and the sheet P discharged from the image forming apparatus 300 is taken into the apparatus. Then, it is transported toward the non-sort path 21. When the trailing edge of the sheet P is detected by the non-sort path sensor 33, the second discharge roller pair 9 is rotationally driven at a speed suitable for stacking, and discharges and stacks the sheet P on the sample tray 201. .

<Flow of sheet P in staple sort mode>
When the user designates the paper discharge mode setting of the image forming apparatus as staple sort, as shown in FIG. 11, the first switching flapper 11 and the second switching flapper 10 of the sheet processing apparatus 1 are arranged in the sort path. In this state, the entrance roller pair 2, the first transport roller pair 3, and the buffer roller 5 are rotationally driven to discharge the sheet from the image forming apparatus 300. P is taken into the apparatus and conveyed toward the sort path 22. When the trailing edge of the sheet P passes through the last stage roller 14, the sheet P is discharged onto the processing tray 130 by the knurled belt 8 and the roller 7 b of the discharge roller 7 a constituting the first discharge roller pair 7. In this case, since the swing guide 150 opens upward, the upper discharge roller 108b is separated from the lower discharge roller 180a of the bundle discharge roller pair 180, and the retracting tray 170 protrudes to the protruding position. Thus, even if the sheet P is discharged onto the processing tray 130 by the first discharge roller pair 7, the leading end of the sheet P does not hang down and the return failure described below does not occur. Alignment of the sheet P is improved satisfactorily.

  The sheet P discharged onto the processing tray 130 begins to return to the trailing end stopper 131 due to its own weight, and in addition, the return is accompanied by the counterclockwise rotation of the paddle 160 stopped at the home position. The action is promoted. When the trailing edge of the sheet P stops against the trailing edge stopper 131, the rotation of the paddle 160 is also stopped, and then the alignment of the sheet P by the alignment members 141 and 142 is performed, and then the sheet bundle is bound by the stapling operation. The sheet bundle is stacked on the stack tray 200 by the discharge operation by the bundle discharge roller pair 180 in a state where the swing guide 150 is closed.

On the other hand, as shown in FIG. 12, the sheet P discharged from the image forming apparatus 300 is wound around the buffer roller 5 by the switching operation of the second switching flapper 10 and advances from the buffer path sensor 32 by a predetermined distance. By the way, the buffer roller 5 is on standby with the stop, and at the point where the leading edge of the next sheet P has advanced a predetermined distance from the entrance sensor 31, as shown in FIG. The second sheet P ₂ is wound around the buffer roller 5 again as shown in FIG. 14 in a state where the _second sheet P ₂ is overlapped by a predetermined length before the second sheet P ₁ . for third sheet P ₃ is than wrapped buffer roller 5 as well, then, as shown in FIG. 15, and re-switching the second switching flapper 10, the Three sheets P ₁ which overlapped by shifting the urchin tip by a predetermined _length, to convey the P _2, P ₃ to the sort path 22.

At this point, the bundle discharging operation of the sheet bundle is finished. Here, as shown in FIG. 16, the bundle discharging roller pair 180a that is rotating forward in the discharging direction with the swing guide 150 being closed is shown. , 180b once receive the _three conveyed sheets P ₁ , P ₂ , P ₃ . Then, as shown in FIG. 17, when the end of the three sheets P passes through the first discharge roller pair 7a, 7b and comes into contact with the surface of the processing tray 130, the bundle discharge roller pair 180a, 180b is reversed. For example, as shown in FIG. 18B, the three sheets P that have been received are returned and before the end of the three sheets P is abutted against the surface of the rear end stopper 131. As shown in FIG. 18A, when the three sheets P having b and b approach each other with a gap a between the end and the rear end stopper 131 surface, the swing guide 150 is opened and bundled. The pair of discharge rollers 180a and 180b are separated from each other. Then, the fourth and subsequent sheets P are discharged onto the processing tray 130 through the sort path 22 in the same manner as the first copy operation. For the third and subsequent copies, the same operation as that for the second copy is repeated, and the processing is completed after stacking on the stack tray 200 for the set number of copies.

As described above, in the overlap conveyance of the plurality of sheets, each sheet P is offset in the conveyance direction. That is, the sheet P ₂ is offset downstream with respect to the sheet P ₁ , and the sheet P ₃ is offset downstream with respect to the sheet P ₂ . Here, the offset amount between the sheets P and the roller pair separation (up) start timing of the swing guide 150 are related to the settling time of the sheet P by the return speed between the bundle discharge roller pair 180a and 180b. That is, it is determined by the processing capability of the image forming apparatus 300. In the present embodiment, the bundle discharge roller has a sheet P conveyance speed of 750 mm / s, an offset amount b = about 20 mm, and a bundle discharge roller return speed of 500 mm / s. spacing start position is set to the timing at the time the end of the sheet P ₁ is abutted about 40mm to the rear end stopper 131 side (the value of the interval a) reaches the front.

<Description of sort mode>
After the user sets a document on the document reading unit 400 of the image forming apparatus 300, the user designates a sort mode on an operation unit (not shown) and turns on a start key (not shown). As a result, the entrance roller pair 2 and the first transport roller pair 3 transport and stack the sheets P on the processing tray 130 as in the staple sort mode, as shown in FIG. The aligning means 140 aligns the sheet bundle on the processing tray 130 and loads a small number of sheets on the processing tray 130, and then the swing guide 150 descends in the closing direction as shown in FIG. A small number of sheet bundles are conveyed.

Next, the conveyed sheet P is again wound around the buffer roller 5 in the same manner as in the staple sort mode, and is discharged onto the processing tray 130 after the bundle discharge is completed. Here, the number of the small number of bundles to be discharged is preferably 20 or less according to the experimental results. About this number,
The number of documents is set so as to satisfy the number of documents ≧ the number of bundles discharged ≦ 20.

  Therefore, if the number of bundles discharged when a program is set is set to five, when the number of documents is four, the bundle is discharged four by four. Further, when the number of documents is 5 or more, for example, if it is 14 sheets, it is divided into 5 sheets + 5 sheets + 4 sheets, aligned and discharged in a bundle.

  When the first set of bundles has been completely discharged, the left alignment member 141 moves together with the right alignment member 142, and the second alignment position is offset from the first alignment position. (The details of this operation will be described later). The second copy is aligned at the offset position, and a small number of bundles are discharged in the same manner as the first copy. When the second copy is completed, the alignment members 141 and 142 return to the position where the first copy is aligned and align the third copy. In this way, as shown in FIG. 21, all set copies are terminated while shifting the sheet bundles.

<Description of alignment and stapling operation>
First, when there is no sheet P on the processing tray 130, that is, when the first sheet P (three sheets) of the job is discharged, as shown in FIG. Further, the left and right alignment members 141 and 142 are moved in advance to positions PS11 and PS21 that have escaped slightly outward with respect to the width of the discharged sheet P in advance.

  As described above, when the three sheets P are supported by the rear end stopper 131 at the rear end and the support surfaces 141c and 142c of the alignment members 141 and 142, respectively, as shown in FIG. The members 141 and 142 move to the positions PS12 and PS22 to move and align the sheet P to the first alignment position 190. Thereafter, one of the alignment members 141 returns to the position PS11 in preparation for the sheet P to be subsequently discharged and waits. When the sheet is discharged, the alignment member 141 moves to the position PS12 again and moves the discharged sheet P to the first position. Move and align to one alignment position 190.

  At this time, the other alignment member 142 serves as a reference position by continuing to stop at the position PS22. The above operation is continued until the final sheet P of the bundle is reached. Therefore, since the aligning operation is performed in this way, for example, the end portion of the moving sheet P as shown in FIG. 24 does not come into contact with the end portion of the support surface 142c and the like, thereby causing buckling. Absent.

  The first sheet bundle that has been aligned is bundle-shifted and stapled as necessary, and the bundle is discharged and transferred to and stacked on the stack tray 200.

  Subsequently, the second copy sheet P (three sheets) is discharged to the processing tray 130. At this time, the alignment members 141 and 142 are waiting at the positions PS11 and PS21 as in the first copy. However, the alignment position moves to the second alignment position 191. As shown in FIG. 25, the second alignment position 191 is positioned to the right by a predetermined amount L with respect to the first alignment position 190.

  That is, after that, bundle stacking is performed on the stack tray 200 while changing the alignment position for each sheet bundle, and sorting and stacking by the offset amount L becomes possible.

Here, the offset amount L may be changed between the sort mode and the staple mode. For example, in the staple mode, the amount L ₁ (about 15 mm) that can prevent the binding needles of adjacent bundles after stacking is stacked, and in the sort mode, the amount L ₂ (about 20 to 30 mm) that improves the visibility of bundle identification. By doing so, the alignment moving distance in the staple mode can be shortened and the processing speed can be improved.

  Next, in the stapling mode, the stapler 101 is waiting in advance at a desired clinch position with respect to the sheet bundle to be aligned, and staples when the discharge and alignment of the final sheet P of the bundle are completed. . As described above, the alignment position of the sheet bundle changes corresponding to the offset amount L for each bundle, and the stapler 101 also moves accordingly.

  In addition, the configuration in which the stapler 101 moves in the direction corresponding to the binding mode (diagonal binding at the left side end, diagonal binding at the right side end, two places) is as described above. . However, in this configuration, there is a limit to the range in which the same stapling posture (horizontal and inclined states) can be maintained, and furthermore, there are many sheet widths for stapling, and the same alignment for different binding modes. Since there is a case where stapling cannot be performed at the position, the first and second alignment positions 190 and 191 may be changed corresponding to each binding mode.

1 is a front view illustrating an overall configuration of a sheet processing apparatus according to the present invention. The side view of a stapler and a processing tray part similarly. FIG. 3 is a plan view of the stapler moving mechanism in the same view as shown in FIG. FIG. 3 is a rear view of the stapler as seen in FIG. The vertical side view of the same swing guide and processing tray. Similarly, the plane explanatory view showing the arrangement relation between the matching means and the binding means. The rear view of a processing tray and an alignment member moving mechanism similarly. The top view of a stack tray movement mechanism similarly. Similarly, sensor layout around the stack tray. The operation | movement figure of the sheet processing apparatus at the time of non-sort mode similarly. Similarly, the operation | movement figure of the sheet processing apparatus at the time of a staple sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of a staple sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of a staple sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of a staple sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of a staple sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of a staple sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of a staple sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of a staple sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of sort mode. Similarly, the operation | movement figure of the sheet processing apparatus at the time of sort mode. Similarly, a stacking diagram of sheet bundles in the sort mode. The top view of the processing tray which similarly shows alignment operation | movement of a sheet bundle. The top view of the processing tray which similarly shows alignment operation | movement of a sheet bundle. The top view of the processing tray which similarly shows alignment operation | movement of a sheet bundle. The top view of the processing tray which similarly shows alignment operation | movement of a sheet bundle. 1 is a longitudinal front view showing an outline of an image forming apparatus to which a sheet processing apparatus according to the present invention is applied.

Explanation of symbols

P sheet 130 processing tray (first stacking means)
140 Alignment means 141 Front alignment member (alignment means)
142 Back alignment member (alignment means)
180 Bundle discharge roller pair (Bundle transport means)
180a Lower bundle discharge roller 180b Upper bundle discharge roller 200 Stack tray (second sheet stacking means)
201 Sample tray 300 Image forming apparatus main body 302 Discharge roller pair (main body discharge means)
600 Image forming unit (image forming means)
310 Control Device (Control Unit) of Image Forming Apparatus Main Body

Claims (7)

A first stacking unit for stacking discharged sheets, a bundle transporting unit for transporting a bundle of sheets stacked on the first stacking unit, and a first stacking unit for stacking a sheet bundle transported by the bundle transporting unit. And a stacking unit that changes the bundle discharge position in the direction intersecting the conveyance direction of the sheet bundle conveyed by the bundle conveying unit for each bundle and stacks the sheet on the second stacking unit. In
Alignment means capable of aligning sheets at different alignment positions in the direction intersecting the transport direction on the first stacking means;
Bundle shifting means for shifting the bundle of sheets aligned on the first stacking means in a direction crossing the transport direction;
In the case of a sheet having a size having a first sheet width in a direction crossing the transport direction, the alignment is performed by changing the alignment position to a direction crossing the transport direction for each bundle, and a shift operation by the shift unit In the case of a sheet of a size having a second sheet width smaller than the first sheet width, the sheet bundle is conveyed to the second stacking unit by the bundle conveying unit. Without changing the alignment position, the sheets are aligned on the first stacking unit, and the shift unit changes the bundle discharge position of the aligned sheet bundle. A sheet processing apparatus that conveys the sheet to a stacking unit.   In the case of a sheet having a size having the first sheet width, the aligning unit alternately conveys a predetermined amount for each bundle with respect to the sheet discharge position of the sheet discharged on the first stacking unit. The sheet processing apparatus according to claim 1, wherein the alignment position is changed in a direction intersecting with the sheet.   3. The sheet processing apparatus according to claim 1, wherein, in the case of a sheet having a size having the second sheet width, the shift unit performs a shift operation every other bundle.   3. The sheet processing apparatus according to claim 1, wherein in the case of a sheet having a size having the second sheet width, the shift unit performs a shift operation for each bundle.   5. The sheet bundle processing means for processing the sheet bundle stacked on the first stacking means, wherein the sheet bundle processing means processes the aligned sheet bundle. The sheet processing apparatus according to claim 1.   6. The sheet processing apparatus according to claim 5, wherein the sheet bundle processing means is a sheet bundle binding means.   The sheet processing apparatus according to claim 1, wherein the bundle shift unit also serves as the alignment unit.

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