JP5506862B2 - Sheet discharging apparatus, sheet processing apparatus, and image forming apparatus - Google Patents

Description

  The present invention relates to a sheet discharging apparatus in which sheets are sequentially discharged and stacked on a stacking tray, a sheet processing apparatus having the sheet discharging apparatus, and an image forming apparatus.

  Conventionally, as a sheet processing apparatus that handles sheets such as a binding apparatus that binds a sheet bundle and a punching apparatus that punches holes in a sheet bundle, a sheet tray that sequentially stacks sheets and a discharge roller that discharges sheets to the stacking tray are provided. Yes (see Patent Documents 1 and 2).

  FIG. 24 is a configuration diagram of a discharge unit in the sheet processing apparatuses disclosed in Patent Documents 1 and 2. As shown in FIG. 24, the conventional sheet processing apparatus has a pair of carry-out rollers 1007 (a carry-out roller 1007a and a carry-out roller 1007b), a processing tray 1130, and a stacking tray 1200. The sheet processing apparatus includes a pair of alignment members 1140 on the left and right sides in the sheet width direction, a pair of discharge rollers 1180, a swing guide 1150, and a pull-in paddle 1160.

  The unloading roller pair 1007 unloads the sheet S from the upstream conveyance path. The processing tray 1130 receives the sheet S to be carried out. A stacking tray 1200 stacks sheet bundles that are discharged after processing.

  A knurled belt is wound around the lower unloading roller 1007a of the unloading roller pair 1007 at several positions in the axial direction between the unloading roller 1007b and sheet guides are arranged at appropriate positions between the knurling belts.

  The processing tray 1130 is inclined, and is positioned on the downstream side (upper left side in the figure) and the upstream side (lower right side in the figure) below with respect to the sheet S discharge direction. A rear end stopper 1131 is provided at the upstream end of the processing tray 1130. The discharge roller pair 1180 (bundle discharge rollers 1180a and 1180b) is arranged on the downstream side of the processing tray 1130. The swing guide 1150 has an upper bundle discharge roller 1180b on the lower surface of the tip, and supports the upper bundle discharge roller 1180b so as to be detachable from the lower bundle discharge roller 1180a. The lead-in paddle 1160 is arranged above the middle part.

  The discharged sheet S starts to move to the trailing edge stopper 1131 due to its own weight, and the paddle 1160 that has stopped at the home position rotates counterclockwise to assist the movement of the sheet. When the trailing edge of the sheet S reliably comes into contact with the stopper 1131 and stops, the rotation of the paddle 1160 is also stopped, and the alignment member 1140 aligns the sheet.

  When all the first sheets are discharged onto the processing tray 1130 and aligned, the swing guide 1150 descends and the upper bundle discharge roller 1180b gets on the sheet bundle. The sheet bundle is stapled by the stapler that is waiting on the rear end stopper 1131 side, and is discharged onto the stacking tray 1200.

  On the other hand, the sheet S1 discharged from the main body of the image forming apparatus in the meantime is wound by a large conveying roller provided in the upstream portion of the processing tray 1130, and up to three sheets are stored so as not to convey the sheet to the processing tray 1130 side. Is done.

  The three sheets S2 are conveyed as they are through the upstream conveyance path to the processing tray 1130 side by the large conveyance roller unit. At this time, three sheets S2 are received by the rollers 1180a and 1180b while the swing guide 1150 is lowered. When the trailing edge of the sheet S2 passes through the carry-out roller pair 1007, the rollers 1180a and 1180b are reversed, and the swing guide 1150 is raised before the trailing edge of the sheet S2 comes into contact with the stopper 1131. The roller 1180b Get away from. Similar to the operation of the first copy, the fourth and subsequent sheets are discharged onto the processing tray through the upstream conveyance path with the swing guide 1150 opened. For the third and subsequent copies, alignment processing is performed in the same operation as the second copy, and the set number of copies are stacked on the stacking tray 1200, and the process ends.

  Here, the bundle return angle of the bundle discharge roller 1180 is slightly larger than the angle of the processing tray 1130 with respect to the horizontal. This is because when three stacked sheets abut against the stopper 1131, the sheet is prevented from buckling by abutting against the lower portion of the stopper, and even a curled sheet can be easily aligned.

  Further, in Patent Document 2, in a sorting (sorting) process in the stapleless mode, one sheet bundle is divided into a small number (2 to 5 sheets) and a small number of sheets are stacked and aligned on the processing tray 1130. A small number of sheets (2 to 5 sheets) are discharged to the stacking tray 1200. Thereby, the loadability on the stacking tray 1200 is improved.

  When the sheets stacked on the inclined processing tray are discharged by the bundle discharge roller as in Patent Documents 1 and 2, usually, the conveyance direction (nip angle) of the bundle discharge roller is slightly smaller than the processing tray angle ( 1-2 °) is increased. The processing tray angle usually has an inclination of about 35 ° with respect to the horizontal plane in consideration of sheet alignment and time reduction required for alignment. Thus, the sheet is set to follow the processing tray surface when the sheet is conveyed backward from the bundle discharge roller toward the rear end stopper. The loading tray is also set at an angle slightly closer to the horizontal than the processing tray (approximately 30 ° with respect to the conventional horizontal plane) in consideration of consistency, discharge loading time, and loading shape.

  The sheet discharge direction may be larger than 25 ° from the horizontal plane in consideration of the basis weight (continuous amount) of the sheet, the use environment, and the curl state.

Japanese Patent Laid-Open No. 10-181988 JP-A-10-194568

  However, when the discharge direction is larger than the stacking tray angle, it is known that the discharge performance deteriorates due to the floating of the tip due to air resistance, the instability of the posture when discharging and dropping, and the like. For this reason, normally, in order to perform stable discharge at the discharge unit, the discharge direction is set to 20 ° to 22 ° from the horizontal plane, and the front end of the sheet comes into contact with the stacking tray surface before passing through the discharge nip. , Have stable discharge control. By doing so, it is possible to maintain the stability when discharging the sheets one by one, but when discharging the bundle, the weight applied to the front end of the sheet increases and the already loaded sheets are pushed out. Further, if a sheet bundle made up of a large number of sheets is discharged, the discharge port may be blocked.

  Therefore, in Patent Document 2, the paper is discharged further upward than the stacking tray inclination angle (35 °). For this reason, after the rear end has passed through the bundle discharge roller nip, there is concern that the posture when discharging and dropping onto the stacking tray will become unstable, and it is always necessary to discharge the bundle in a state where a small number of sheets are stacked. The emission stability is improved by increasing the weight.

  However, since the discharge direction is large (approximately 35 ° to 36 °), there has been a problem such as poor stacking even if a small number of sheets of light thin paper or a sheet with the leading end curled upward are stacked. In addition, considering the floating of the tip at the time of discharge and the instability of discharge and drop, there is a limit to increasing the discharge speed. Also, since the sheets are always stacked once on the processing tray 1130 and then bundled and discharged as a plurality of sheet bundles, it is necessary to complete stacking alignment processing on the processing tray during the sheet conveyance interval. Therefore, it was difficult to cope with further high-speed discharge.

  Accordingly, the present invention provides a sheet discharging apparatus, a sheet processing apparatus, and an image forming apparatus that can improve the consistency and stackability, and can cope with a wide range of paper types, paper sizes, and speed. It is an object.

In order to solve the above problems, a sheet discharge apparatus according to the present invention includes a first stacking tray for stacking sheets, a transporting unit for transporting sheets, and the first stacking tray for sheets transported by the transporting unit. And a second stacking tray for stacking and stacking sheets conveyed in the direction opposite to the sheet discharging direction by the discharging means, and a discharging unit capable of conveying the sheet in a direction opposite to the sheet discharging direction. a stopper for regulating the conveying direction of the distal end of the sheet conveyed to the second tray by the discharging means, a first discharge direction when discharging the sheets one by one by the discharge means to the first tray , it is possible to change the discharge angle of the discharge means to the second discharge direction when discharging a plurality of sheet bundle sheet are stacked in the second stacking tray, and the second And a changing means for changing the discharge angle of the discharge means so as to approach the first stack tray than the discharge direction the second discharge direction, the discharge direction of the sheet over bets of the discharge means Ri by said changing means When the sheet is transported to the second stacking tray by the discharging means in a state where the sheet is in the second discharging direction, the sheet transporting direction is directed toward the lower portion of the stopper.

According to the present invention, the end portions of the sheets conveyed to the second stacking tray are reliably brought into contact with the stopper to be aligned, and the alignment of a plurality of stacked sheets can be improved. By improving the alignment of the stacked sheets, even if the discharging direction is far from the first stacking tray when discharging by the discharging means, the stacking of sheets is discharged to the first stacking tray without greatly deteriorating the alignment state. can do.

1 is a configuration diagram of an image forming apparatus according to an exemplary embodiment. It is a block diagram of a sheet processing apparatus. FIG. 10 is a cross-sectional view illustrating the operation of the sheet processing apparatus. FIG. 10 is a cross-sectional view illustrating the operation of the sheet processing apparatus. FIG. 10 is a cross-sectional view illustrating the operation of the sheet processing apparatus. It is a front view of a shift unit. It is a perspective view of a shift unit. It is sectional drawing explaining an intermediate processing tray. It is a top view explaining a staple part. It is a top view explaining a matching means. It is a block diagram explaining a rocking | fluctuation guide. FIG. 10 is a diagram illustrating sheet flow and an operation of an intermediate processing tray in an unbound sort mode. FIG. 10 is a diagram illustrating sheet flow and an operation of an intermediate processing tray in the staple sort mode. FIG. 10 is a diagram illustrating sheet flow and an operation of an intermediate processing tray in the staple sort mode. FIG. 10 is a diagram illustrating sheet flow and an operation of an intermediate processing tray in the staple sort mode. FIG. 10 is a diagram illustrating sheet flow and an operation of an intermediate processing tray in the staple sort mode. FIG. 10 is a diagram illustrating sheet flow and an operation of an intermediate processing tray in the staple sort mode. It is an operation | movement figure explaining buffer paper alignment. 3 is a block diagram of an image forming apparatus control unit that controls the image forming apparatus. FIG. It is a block diagram of a control unit that controls the sheet processing apparatus. It is a flowchart of sheet discharge control. It is a comparison figure of a discharge nip angle. It is explanatory drawing of a discharge nip angle. It is sectional drawing explaining the conventional sheet processing apparatus.

<Overall configuration of image forming apparatus>
FIG. 1 is a configuration diagram of an image forming apparatus. As shown in FIG. 1, the image forming apparatus includes an image forming apparatus main body 300 that performs monochrome / color image formation, and a finisher 100 that is a sheet processing apparatus connected thereto. The finisher 100 includes a saddle stitching processing device (saddle unit) 135 and a flat stitching processing device as a sheet discharging device. For this reason, the sheet discharged from the image forming apparatus main body 300 can be processed online. Note that the finisher 100 may be used as an option. Therefore, the image forming apparatus main body 300 can be used alone. Further, the image forming apparatus main body 300 may be integrated with the finisher 100 as a sheet discharge apparatus. Here, a position where the user faces the operation unit 301 (FIG. 19) for performing various inputs / settings on the image forming apparatus main body 300 is referred to as a front front side (hereinafter referred to as a front side) of the image forming apparatus. Is called the back side. FIG. 1 shows the configuration of the image forming apparatus viewed from the front side of the apparatus. The finisher 100 is connected to a side portion of the image forming apparatus main body 300.

  Four-color toner images are transferred to the sheets supplied from the cassettes 909a to 909d in the image forming apparatus main body 300 by yellow, magenta, cyan, and black photosensitive drums 914a to 914d as image forming units, respectively. The sheet to which the toner image has been transferred is conveyed to a fixing device 904 where the toner image is fixed and discharged outside the apparatus.

<Sheet processing device>
FIG. 2 is a configuration diagram of a finisher 100 as a sheet processing apparatus. As shown in FIG. 2, the sheet discharged from the image forming apparatus main body 300 is delivered to the inlet roller pair 102 of the sheet processing apparatus 100. At this time, the sheet delivery timing is simultaneously detected by the entrance sensor 101. The sheet conveyed by the inlet roller pair 102 is detected by the lateral registration detection sensor 104 while passing through the conveyance path 103, and how much the lateral registration with respect to the center (center) position of the sheet processing apparatus is detected. Detect if an error has occurred.

  After the lateral registration error is detected, the sheet is shifted by a predetermined amount of the shift unit 108 moving forward / backward while the sheet is being conveyed to the pair of shift rollers 105 and 106, so that the sheet is shifted. This shift operation will be described later in detail.

  Thereafter, the sheet conveyed by the conveyance roller 110 and the separation roller 111 is conveyed by the buffer roller pair 115. Thereafter, when the sheet is discharged to the upper discharge tray 136, the upper path switching member 118 is brought into a broken line state in the drawing by a driving means such as a solenoid (not shown) and is guided to the upper path conveying path 117, and is moved by the upper discharge roller 120. It is discharged to the discharge tray 136.

  When the sheet is not discharged to the upper discharge tray 136, the sheet conveyed by the buffer roller pair 115 is guided to the bundle conveyance path 121 by the upper path switching member 118. Thereafter, the buffer roller pair 122 and the bundle transport roller pair 124 sequentially pass through the transport path. When the sheet is subjected to saddle (saddle stitching) processing, the saddle path switching member 125 is in a broken line state by driving means such as a solenoid (not shown). Then, the sheet is conveyed to the saddle path 133, guided to the saddle unit 135 by the saddle entrance roller pair 134, and subjected to saddle processing (saddle stitching processing).

When the conveyed sheet S is discharged to the lower discharge tray ( first stacking tray) 137, the sheet conveyed to the bundle conveying roller pair 124 is conveyed to the lower path 126 by the saddle switching member 125. Become. Thereafter, a plurality of sheets discharged onto the intermediate processing tray 138 (second stacking tray) by the lower discharge roller pair (conveying means) 128 are stacked and processed in the intermediate processing tray 138, and the discharge roller pair (discharge) Means) 130 is discharged to the lower discharge tray 137. Sheet processing in the intermediate processing tray 138 will be described in detail later.

<Description of shift unit>
Next, the configuration and operation of the shift unit 108 will be described with reference to FIGS. FIG. 6 is a front view of the shift unit. FIG. 7 is a perspective view of the shift unit.

  As shown in FIGS. 6 and 7, the sheet S that has been conveyed drives the shift roller pair 105 by the drive of the shift conveyance motor 208 being transmitted to the drive belt 209. Further, by driving the shift roller pair 106 by the driving belt 213, the sheet S is conveyed in the direction C in the drawing. At this time, the position of the sheet S is detected by the lateral registration detection sensor 104 being moved in the direction of arrow E by driving means (not shown). The sheet is moved during conveyance by the amount of sheet shift, which is obtained by adding the amount of movement to cancel the lateral registration error and the set amount of sheet shift. By performing this operation in the front / back direction (between arrows D) when the sheet S is held between the shift roller pairs 105 and 106, the sheet S can be shifted by a predetermined amount while being conveyed in the conveyance direction C.

<Description of buffering processing operation>
When stapling or saddle processing is performed, a certain processing time is usually required. Normally, it is difficult to complete the processing between the sheet discharge intervals, and therefore the processing time exceeds the sheet discharge interval. This processing time also depends on the image forming speed of the image forming apparatus. For this reason, a so-called sheet buffering processing method that performs sheet processing without stopping image formation of the image forming apparatus is widely known. Hereinafter, the sheet buffering process will be described.

  As shown in FIG. 3, the sheet S <b> 1 conveyed by the conveyance roller 110 and the separation roller 111 is guided to the bundle conveyance path 121 by the buffer roller pair 115. At this time, the leading edge of the sheet S1 is detected by the buffer sensor 116. Then, the buffer roller pair 115 performs stop control by a driving unit (not shown) so that the sheet stops when the sheet rear end position reaches the position A based on the size information of the sheet recognized in advance.

  As shown in FIG. 4, the buffer roller pair 115 performs a reverse operation in a state where the buffer path switching member 114 is in a broken line state by drive means such as a solenoid (not shown). As a result, the trailing edge of the sheet is guided to the buffer path 113 and the sheet S1 is conveyed in the reverse direction until the leading edge of the sheet reaches the position B.

  As shown in FIG. 5, after the leading edge of the sheet S2 conveyed following the sheet S1 is detected by the buffer sensor 109, the same as the leading edge of the sheet S2 when the stopped sheet S1 reaches the conveying speed. The driving of the buffer roller pair 115 is started so as to reach the position. Thereby, the sheet S1 and the sheet S2 are in a state where the leading ends are aligned.

  Here, when another sheet is overlapped, the buffer roller pair 115 is driven until the rear end positions of the sheets S1 and S2 reach the A point. Thereafter, another process of overlaying can be performed by repeating the above-described process.

  After a predetermined number of sheets are overlapped in this manner, a plurality of sheet bundles are conveyed to the intermediate processing tray 138 or the saddle unit 135 by the downstream buffer roller pair 122 and the bundle conveying roller pair 123.

<Intermediate processing tray 138>
Next, the intermediate processing tray 138 will be described with reference to FIGS.

  As shown in FIG. 8, the intermediate processing tray 138 as the second stacking tray has the downstream side (left side in FIG. 8) upward and the upstream side (right side in FIG. 8) downward with respect to the sheet bundle discharge direction. Inclined. A rear end stopper 150 is disposed at a lower end portion on the upstream side of the intermediate processing tray 138.

  An upper discharge roller 130 b of the discharge roller pair 130 is disposed at the upper end portion that is the downstream side of the intermediate processing tray 138. An upper discharge roller 130 b of the discharge roller pair 130 is disposed at the lower surface front end of the swing guide 149. The upper discharge roller 130b comes in contact with and separates from the lower discharge roller 130a as the swing guide 149 opens and closes. The discharge roller pair 130 is rotated forward and reversely by the rotational drive from the drive motor M130 as drive means being applied to the upper and lower discharge roller shaft portions. Accordingly, the discharge roller pair 130 can be discharged and conveyed in a discharge direction for discharging onto the lower discharge tray 137 and a transfer direction for transferring onto the intermediate processing tray 138.

  In the swing guide 149, a guide guide 151, a first static elimination needle 152, and a second static elimination needle 153 are respectively arranged in the axial direction. The swing guide 149 is rotatably supported by a support shaft 154 and can move in the vertical direction.

  The guide guide 151 is provided upstream of the upper discharge roller 130 b in the sheet conveyance direction, and guides the sheet to the nip portion of the discharge roller pair 130. The first static elimination needle 152 is a static elimination unit that removes the charged potential on the sheet surface when the sheet is discharged from the lower discharge roller 128 into the intermediate processing tray 138. The second static elimination needle 153 is provided on the downstream side of the upper discharge roller 130b in the sheet conveyance direction, and is a static elimination unit that removes the charged potential of the sheet surface discharged from the discharge roller pair 130.

  Further, the abutting member 155 arranged coaxially with the support shaft 154 is accommodated in a slider so as to be movable, and is always supported by an urging spring (not shown) so as to abut against the eccentric cam 156. . As shown in FIG. 11, the eccentric cam 156 can be rotated by a discharge angle moving motor 160. Depending on the rotational position of the eccentric cam 156, the contact member 155 moves in the slider together with the support shaft 154, and moves the swing guide 149. The abutting member 155, the eccentric cam 156, and the discharge angle moving motor 160 constitute changing means.

  By the operation of the changing means, the roller nip position formed by the upper discharge roller 130b and the lower discharge roller 130a moves on the outer circumference of the lower discharge roller 130a, and the discharge angle of the discharge roller pair 130 is variable. Regarding the series of swing guide 149 operations, the accompanying guide guide 151, first static elimination needle 152, and second static elimination needle 153 also move in the same manner as the swing guide 149 operation. Therefore, the arrangement relationship with the upper discharge roller 130b does not always change.

  A stapler 132 as sheet processing means is fixed on a slide support 303. As shown in FIG. 9, rolling rollers 304 and 305 are provided at the lower part of the slide support 303. The slide support 303 is guided by the rolling rollers 304 and 305 and the guide rail groove 307 on the stapler moving table 306, and along the rear edge of the sheet S stacked on the intermediate processing tray 138 (arrow Y). Move in the direction).

  The stapler 132 is maintained in a posture inclined by a predetermined angle α with respect to the trailing edge of the sheet at the corner of the sheet S stacked on the intermediate processing tray 138. The inclination angle α is set to about 30 degrees, but can be changed by changing the shape of the guide rail groove 307. The stapler moving table 306 is provided with a position sensor (not shown) that detects the home position of the stapler 132. Normally, the stapler 132 stands by at the home position on the front side of the apparatus.

  As shown in FIG. 10, the aligning means 340 and 341 include first and second aligning members 340 a and 341 a that align the left and right end sides in the width direction of the sheets stored in the intermediate processing tray 138.

  The first and second alignment members 340a and 341a are independently opposed to the both side edges of the sheet S on the surface of the intermediate processing tray 138. The first and second alignment members 340a and 341a have alignment surfaces 340a1 and 341a1 that are perpendicular to the processing tray 138 surface and non-alignment surfaces 340b and 341b that are inclined upward on the alignment surfaces 340a1 and 341a1. Yes. The alignment surfaces 340a1 and 341a1 press and support the sheet side end surface.

  The left and right alignment means 340 and 341 include first and second drive motors M340 and M341 that can be driven independently. The driving force is transmitted from the leading pulleys of the drive motors M340 and M341 to the first and second alignment members 340 and 341 via the timing belts B340 and B341. As a result, the first and second alignment members 340 and 341 can move independently along the sheet width direction with respect to the processing tray 138. That is, the alignment surfaces 340a1 and 341a1 are arranged on the processing tray 138 so as to face each other, and the moving means are assembled on the lower surface side so as to be able to move forward and backward in the alignment direction.

  Here, sensors S340 and S341 for detecting respective home positions are arranged for the first and second alignment members 340a and 341a. When not operating, the first and second alignment members 340 and 341 stand by at the respective home position positions (both ends).

  As shown in FIG. 8, a plurality of pull-in paddles 131 are disposed above the intermediate processing tray 138, and a plurality of pull-in paddles 131 are fixed along a drive shaft 157 that is rotated by a drive motor (not shown). The pull-in paddle 131 is rotated counterclockwise in FIG. 8 at an appropriate timing by a drive motor M131 (not shown). The pull-in paddle 131 is a sheet conveying unit that conveys a sheet and abuts against the rear end stopper 150. There are a plurality of pull-in paddles 131 in the axial direction of the drive shaft 157.

  Next, the sheet rear end alignment portion will be described. On the upstream side of the intermediate processing tray 138, a belt roller 158 as a sheet conveying unit and a rear end lever 159 as a sheet pressing member are arranged.

  The sheet strikes the rear end stopper 150 and is aligned while being guided by the rear end lever 159 by the counterclockwise rotation of the belt roller 158.

  The belt roller 158 is hung on the outer periphery of the discharge roller 128a constituting the lower discharge roller pair 128 as the conveying means, and rotates counterclockwise following the rotation of the discharge roller 128a. Further, the belt roller 158 is provided above the intermediate processing tray 138 in such a positional relationship that the lower portion thereof is in contact with the uppermost sheet stacked on the intermediate processing tray 138.

<Explanation of operation of discharging means in unbound sort mode>
Next, the flow of the sheet and the operation of the discharge roller pair 130 as the discharge unit in the unbound sort mode (first discharge mode) will be described with reference to FIG.

  When a job in the unbound sort mode is selected, the eccentric cam 156 waiting at the home position is rotated 180 degrees before the first sheet of the job is discharged from the image forming apparatus 300. As a result, the abutting member 155 that forms the changing means together with the eccentric cam 156 is slid, and the swing guide 149 is moved toward the conveyance downstream side.

  The discharge angle changing operation by the changing means is performed after the swing guide 149 is moved upward and the nip is not in contact with the upper discharge roller 130b and the lower discharge roller 130a. By doing in this way, the abrasion by the rubbing of the roller surfaces at the time of roller movement can be prevented.

  When the operation of changing the discharge angle by the changing means is completed, the swing guide 149 is moved downward to bring the upper discharge roller 130b and the lower discharge roller 130a into contact with each other and stand by at a discharge nip angle β with respect to the vertical line.

  The sheet discharged from the image forming apparatus is conveyed by the shift unit 108 (shifted to the front in FIG. 2) while being shifted by a predetermined amount, and is directly discharged from the lower discharge roller pair 128 to the upper discharge roller 130b and the lower discharge roller 130a pair. The Then, the paper is discharged to the lower discharge tray 137 by the discharge roller pair 130. The same operation is repeated for the specified number of sorted sheets, while the second copy is shifted by a predetermined amount to the side opposite to the shift direction of the first copy (the back side in FIG. 2), and the upper discharge from the lower discharge roller pair 128 is the same as the first copy The paper is discharged to the lower discharge tray 137 through a pair of the roller 130b and the lower discharge roller 130a.

  For example, in the present embodiment, the shift amount for one time is determined to be 15 mm on one side from the discharge center. As a result, the sheet bundle is stacked on the lower discharge tray 137 while being shifted by 30 mm as the sort offset amount between the sheet bundles.

  When the mode without sorting is designated, a lateral registration correction operation is performed in which the shift unit 108 returns the sheet that has been conveyed by being skewed in the upstream portion to the discharge center position. Then, it passes through the upper discharge roller 130b and the lower discharge roller 130a pair at the discharge center position and is discharged to the lower discharge tray 137 as a stacking tray.

  In this way, in an unbound job in which the binding process is not performed, when discharging sheets one by one to the lower discharge tray 137, the discharge nip angle of the discharge roller pair 130 as discharge means is β, and a sheet bundle described later Compared to the time of discharge, the discharge direction is set to the lower discharge tray 137 side. Thereby, the floatability of the sheet after the trailing edge of the sheet passes through the discharge roller pair 130 can be stabilized. In addition, by bringing the leading edge of the sheet into contact with the stacking tray as soon as possible, it is possible to prevent the sheet from being ramped up and stackability is improved. In addition, since it is not necessary to reverse the discharge roller pair 130 in the conventional unbound sort mode and pull it into the intermediate processing tray 138, it is possible to reduce wear deterioration of the apparatus and operation noise.

<Explanation of operation of ejecting means in staple sort mode>
The flow of the sheet and the operation of the discharge roller pair 130 as discharge means in the staple sort mode (second discharge mode) will be described with reference to FIGS.

  When a job in the staple sort mode is selected, the eccentric cam 156 is rotated until the first sheet of the job is discharged from the image forming apparatus 300. As a result, the abutting member 155 that forms the changing means together with the eccentric cam 156 is slid, and the swing guide 149 is moved upstream in the conveyance direction (in the opposite direction to that in the unbound sort mode).

  The discharge angle changing operation by the changing means is performed after the swing guide 149 is moved upward and the nip is not in contact with the upper discharge roller 130b and the lower discharge roller 130a. As shown in FIG. 13, when the discharge angle changing operation is completed, the swing guide 149 is moved downward to bring the upper discharge roller 130b and the lower discharge roller 130a into contact with each other and stand by at the discharge nip angle γ. The discharge angle (discharge nip angle γ) at this time is set upward (in the direction away from the lower discharge tray 137) from the discharge angle (discharge nip angle β) in the unbound sort mode (first discharge mode).

  The first first sheet S11 discharged from the image forming apparatus 300 is conveyed by the shift unit 108 while being shifted by a predetermined amount in the front direction in FIG. 2, and the upper discharge roller 130b and the lower It is conveyed to the discharge roller 130a.

  As shown in FIG. 14, the sheet S11 has its rear end passed through the lower discharge roller pair 128 and is fed by a predetermined amount by the upper discharge roller 130b and the lower discharge roller 130a. Thereafter, the upper discharge roller 130b and the lower discharge roller 130a are reversed to be conveyed at the conveyance speed Vb so that the rear end of the sheet S11 contacts the rear end stopper 150.

  As shown in FIG. 15, before the rear end of the sheet S11 hits the rear end stopper 150, the swing guide 149 is raised to separate the upper discharge roller 130b and the lower discharge roller 130a. As a result, the conveyed sheet S11 at the conveying speed Vb can be abutted and aligned with the trailing end stopper 150 in a non-nipping state, and the occurrence of buckling that is particularly likely to occur with a thin sheet can be prevented.

  The discharge directions of the upper discharge roller 130b and the lower discharge roller 130a are directed toward the lower portion of the rear end stopper 150 when reversely rotating. Thereby, the rear end of the sheet S11 can be reliably aligned by the rear end stopper 150. The angle formed between the direction connecting the center points of the upper discharge roller 130b and the lower discharge roller 130a and the vertical direction is the discharge nip angle γ.

  When the alignment in the transport direction (rear end portion) of the sheet S11 is completed, the alignment in the width direction is performed by the alignment units 340 and 341.

  Next, the second sheet S12 of the first copy is discharged from the lower discharge roller pair 128 to the intermediate processing tray 138. At this time, the swing guide 149 is in the raised position, and the sheet S12 is greeted with the upper discharge roller 130b and the lower discharge roller 130a separated. When the trailing edge of the sheet S12 passes through the nip of the lower discharge roller pair 128, the sheet S12 is discharged onto the intermediate processing tray 138.

  As shown in FIG. 16, the sheet S12 discharged onto the intermediate processing tray 138 is conveyed toward the trailing edge stopper 150 with the trailing edge of the sheet S12 rotating by the counterclockwise rotation of the pull-in paddle 131. The

  The sheet S12 is further attracted to the rear end stopper 150 by the belt roller 158 that rotates counterclockwise, and abuts against the surface of the rear end stopper 150 to be aligned. When the alignment in the transport direction (rear end portion) of the sheet S12 is completed, alignment in the width direction is performed by the alignment means 340 and 341, as in the first sheet. This series of operations is repeated until the final sheet S1n of the first copy hits the rear end stopper 150.

  When the alignment operation for the final sheet S1n is completed, the stapler 132 staples the trailing edge of the sheet bundle S1T. Then, as shown in FIG. 17, the swing guide 149 is lowered, the sheet bundle S1T is sandwiched between the upper discharge roller 130b and the lower discharge roller 130a, and discharged to the lower discharge tray 137.

  The stapling operation after the final sheet S1n hits the trailing edge stopper 150 and the bundle discharging operation to the lower discharge tray 137 are times that require extra processing time than the normal sheet processing. During this time, the sheet, that is, the first sheet S21 of the second copy cannot be placed in the intermediate processing tray 138.

  Therefore, in the sheet processing apparatus according to the present embodiment, as described above, the sheet discharged from the image forming apparatus main body 300 is buffered (stored) during this period. As a result, the next sheet is sequentially received from the image forming apparatus 300 while the sheet is not discharged to the intermediate processing tray 138.

  As shown in FIG. 18, the second sheet S21, S22, S23 buffered until the first sheet bundle is discharged to the lower discharge tray 137 is in a state of being tiled with three sheets. . The buffered sheet bundles S21 to S23 are conveyed from the lower discharge roller pair 128 to the upper discharge roller 130b and the lower discharge roller 130a pair. The three sheet bundles are fed by a predetermined amount by the upper discharge roller 130b and the lower discharge roller 130a after the rear ends thereof pass through the lower discharge roller pair 128. Thereafter, the upper discharge roller 130b and the lower discharge roller 130a are reversed in the same manner as the first sheet of the first copy, and are conveyed at a conveyance speed Vb in a direction in which the rear end of the sheet bundle contacts the rear end stopper 150.

  Before the trailing edge of the sheet bundle hits the trailing edge stopper 150, the swing guide 149 is raised to separate the upper discharge roller 130b and the lower discharge roller 130a. The sheet processing from the 4th sheet to the last sheet of the 2nd copy is aligned as in the 1st copy, and after stapling, discharge to the lower discharge tray 137 is performed. After repeating this operation for the specified number of copies, the job is terminated.

(Control part)
FIG. 19 is a block diagram of an image forming apparatus control unit that controls the image forming apparatus. As illustrated in FIG. 19, the CPU circuit unit 330 includes a CPU 329, a ROM 331, and a RAM 350. The CPU circuit unit 330 controls the document feeder control unit 332, the image reader control unit 333, the image signal control unit 334, the printer control unit 335, the finisher control unit 336, and the external interface 337. The CPU circuit unit 330 performs control according to the program stored in the ROM 331 and the setting of the operation unit 301.

  The document feeder control unit 332 controls the document feeder 500. The image reader control unit 333 controls the image reader. The printer control unit 335 controls the image forming apparatus main body 300. The finisher control unit 336 controls the finisher 100. In the present embodiment, a configuration in which the finisher control unit 336 is mounted on the finisher 100 will be described. However, the finisher control unit 336 is provided in the image forming apparatus main body 300 integrally with the CPU circuit unit 330 and controls the finisher 100 from the image forming apparatus main body 300 side. You may do it.

  The RAM 350 is used as an area for temporarily storing control data and a work area for operations associated with control. The external interface 337 is an interface from the computer 320 and develops print data into an image and outputs the image to the image signal control unit 334. An image read by the image sensor is output from the image reader control unit 333 to the image signal control unit 334, and an image output from the image signal control unit 334 to the printer control unit 335 is input to the exposure control unit.

  FIG. 20 is a block diagram of the finisher control unit 336 that controls the finisher 100. As illustrated in FIG. 20, the finisher control unit includes a microcomputer (CPU) 701, a RAM 702, a ROM 703, an input / output unit (I / O) 705, a communication interface 706, and a network interface 704.

  In the conveyance control unit 707, sheet lateral registration detection processing, sheet buffering processing, and conveyance processing are performed. In the intermediate processing tray control unit 708, the alignment plate operation control, paddle operation control, belt roller movement control, bundle discharge control, and discharge angle movement control are controlled by the home position detection sensor and the movement motor, respectively. In the binding control unit 709, staple movement control and clinch control are controlled by a home sensor and a motor, respectively.

  Various sensor signals are input to the input port of the I / O 705. The output port of the I / O 705 is connected to each drive system connected via a control block (not shown) and various drivers (not shown).

(Sheet discharge control)
FIG. 21 is a flowchart of sheet discharge control. As shown in FIG. 21, when a discharge position is selected for the lower discharge tray 137 (S710), a binding process presence / absence determination mode is entered (S711). When the binding process is performed, the discharge nip angle of the discharge roller pair 130 as the discharge unit is set to γ with respect to the vertical line (S712). In the case of non-binding processing in which binding processing is not performed, the discharge nip angle of the discharge roller pair 130 is set to β smaller than γ with respect to the vertical line (S713).

  Next, it is determined whether or not there is a shift sort process (S714). When the shift sort mode is selected, the shift unit 108 is controlled (S715), and the sheet discharge operation from the image forming unit is started (S716). If there is no shift sort processing, the sheet discharge operation from the image forming unit is started without controlling the shift unit 108 (S716).

(effect)
As shown in FIG. 22, in the case of unbound sheet processing (first discharge mode), the discharge nip angle of the discharge roller pair 130 is β, and the discharge direction compared to the case where the discharge nip angle during bundle discharge is γ. Is directed toward the lower discharge tray 137 (first discharge direction). Thus, the sheets can be discharged to the lower discharge tray 137 while maintaining a stable posture one by one without reducing productivity.

  In the case of the staple process ((second discharge mode)), the discharge nip angle of the discharge roller pair 130 is γ, and the discharge direction is directed away from the lower discharge tray 137 compared to the case where the discharge nip angle is β (first discharge mode). Two discharge directions). Thereby, even if a sheet bundle made up of a large number of sheets is discharged at a time, the discharge port is not blocked. Further, during reverse rotation, the sheet is directed toward the lower side of the rear end stopper 150, so that the consistency of the plurality of sheet bundles subjected to the buffering process is ensured, and the discharge to the lower discharge tray 137 is always discharged by a plurality of sheets. For this reason, the loadability on the lower discharge tray 137 is not lowered.

  In the present embodiment, the discharge direction of the discharge roller pair 130 is upward from the horizontal in both the unbinding process and the binding process, but the first discharge direction in the unbinding process is the same as that in the binding process. If it is on the stacking tray side with respect to the second discharge direction, it may be downward with respect to the horizontal. The discharge angle of the discharge roller pair 130 is preferably changed according to the sheet size, conveyance length, curl state, basis weight (continuous amount), thickness, image forming density, apparatus usage environment, and folding form.

  Here, a description will be given of the operation of the discharge roller pair 130 when a sheet having a large sheet size and a long conveying length or a heavy sheet having high surface resistance such as coated paper is discharged unbound. When discharging a sheet or coated paper having a large sheet size and a long conveyance length as shown in FIG. 23, the discharge sheet itself is distant from the discharge roller pair 130 when discharging the sheet because the discharge sheet itself has a large mass. Becomes shorter. For this reason, there is a tendency that the rear end portion of the sheet is leaned. Further, a phenomenon that the leading end of the sheet at the time of discharging pushes out the discharged sheet on the stacking tray in the transport direction and disturbs the stacking state easily occurs.

  For this reason, the rotational position of the eccentric cam 156 as the changing means is changed, and the discharge nip angle of the discharge roller pair 130 is set to be perpendicular to the discharge nip angle β in the normal non-binding mode (first discharge mode). Is set to a large θ. As a result, compared with the case where the discharge nip angle is β, the sheet discharge direction can be directed slightly upward (in the direction away from the lower discharge tray 137). Extrusion phenomenon can be prevented. In addition, when the curl direction is downward, the basis weight, the paper thickness is large, the image forming density is high, the humidity of the usage environment is high, or the origami is discharged, the same applies. It is preferable that the discharge direction is slightly upward. As a result, it is possible to cope with a wide range of paper types, paper sizes, speedups, and the curl direction and size of the sheet under a wide range of usage environments. The discharge nip angle θ at this time can be set to an arbitrary angle between β and γ.

A, B: Positions B340, B341 ... Timing belts M340, M341 ... Drive motor S ... Sheets S340, S341 ... Sensor Vb ... Conveying speed Ws ... Sheet discharge width Wt ... Finishing retraction width 100 ... Finisher 101 ... Inlet sensor 102 ... Inlet roller Pair 103 ... Conveying path 104 ... Horizontal registration detection sensors 105, 106 ... Shift roller pair 108 ... Shift unit 109 ... Buffer sensor 110 ... Conveying roller 111 ... Separating roller 113 ... Buffer path 114 ... Buffer path switching member 115 ... Buffer roller pair 116 ... Buffer sensor 117 ... Upper path conveying path 118 ... Upper path switching member 120 ... Upper discharge roller 121 ... Bundle conveyance path 122 ... Buffer roller pair 124 ... Bundle conveyance roller pair 125 ... Saddle path switching member 128 ... Lower ejection roller pair (conveying means)
128a ... discharge roller 130 ... discharge roller pair (discharge means)
130a ... Lower discharge roller 130b ... Upper discharge roller 131 ... Pull-in paddle 132 ... Stapler 134 ... Saddle inlet roller pair 135 ... Saddle stitching processing device 136 ... Upper discharge tray 137 ... Lower discharge tray ( first stacking tray)
138 ... Intermediate processing tray (second loading tray)
149 ... Swing guide 151 ... Guide guide 152 ... First static elimination needle 153 ... Second static elimination needle 154 ... Support shaft 155 ... Contact member 156 ... Eccentric cam 157 ... Drive shaft 158 ... Belt roller 159 ... Rear end lever 160 ... Discharge angle movement motor 208 ... shift conveyance motor 209, 213 ... drive belt 300 ... image forming apparatus main body 301 ... operation unit 303 ... slide support 304, 305 ... rolling roller 306 ... stapler moving table 307 ... guide rail groove 320 ... computer 329, 701 ... CPU
330: CPU circuit units 331, 703 ... ROM
332: Document feeder control unit 333 ... Image reader control unit 334 ... Image signal control unit 335 ... Printer control unit 336 ... Finisher control unit 337 ... External interface 340 ... Alignment means 340a, 341a ... Alignment members 340a1, 341a1 ... Alignment surface 340b, 341b ... non-alignment surfaces 350, 702 ... RAM
500 ... Document feeder 601 ... Sheet conveying means 681 ... Stacking means 682 ... Sheet width direction aligning means 682b ... Sheet guide member 704 ... Network interface 705 ... Input / output unit 706 ... Communication interface 707 ... Conveyance control unit 708 ... Intermediate processing tray Control unit 709 ... Binding control unit 904 ... Fixing device 909 ... Cassette 914 ... Photosensitive drum

Claims (11)

A first stacking tray for stacking sheets;
Conveying means for conveying the sheet;
Discharging the sheet conveyed by the conveying unit to the first stacking tray and discharging unit capable of conveying the sheet in a direction opposite to the sheet discharging direction;
A second stacking tray for stacking and stacking sheets conveyed in the direction opposite to the sheet discharging direction by the discharging unit;
A stopper that regulates the leading end in the conveying direction of the sheet conveyed to the second stacking tray by the discharging means;
A first discharge direction when discharging the sheets one by one to the first stacking tray by the discharging means, and a second discharge direction when discharging a sheet bundle in which a plurality of sheets are stacked on the second stacking tray And changing the discharge angle of the discharge means so that the first discharge direction is closer to the first stacking tray than the second discharge direction. Means, and
In a state where the discharge direction of the sheet over bets of the discharge means Ri by said changing means in the second discharge direction, when conveying the sheet to the second stacking tray by the discharge means, the conveying direction of the sheet, the A sheet discharging apparatus characterized by being directed toward a lower portion of the stopper. 2. The sheet discharging apparatus according to claim 1, wherein when discharging one sheet at a time by the discharging unit, the sheet conveyed by the conveying unit is directly discharged to the first stacking tray. The changing means determines a discharge angle of the discharge means when discharging the sheets one by one by the discharge means, such as a sheet size, a conveyance length, a curled state, a basis weight, a thickness, an image forming density, an apparatus use environment, a folding environment. The sheet discharging apparatus according to claim 1, wherein the sheet discharging apparatus is changed based on any one of the forms. The discharge means is composed of a discharge roller pair composed of a plurality of discharge rollers, and the changing means changes the discharge angle by changing a discharge nip angle of the discharge roller pair. 4. The sheet discharge device according to any one of 3 above. The said changing means moves at least one discharge roller of the said discharge roller pair, and changes the said discharge angle by changing the discharge nip angle of the said discharge roller pair, The change angle of Claim 4 characterized by the above-mentioned. Sheet discharge device. 6. The sheet discharge apparatus according to claim 5, wherein the changing unit moves at least one discharge roller in a state where the discharge roller pair is separated from the discharge roller pair to change a discharge nip angle of the discharge roller pair. . The sheet discharging apparatus according to any one of claims 4 to 6, wherein the discharge roller pair is provided with rotational driving from a driving unit on each of the upper and lower discharge roller shaft portions. A guide guide provided on the upstream side in the sheet conveying direction of at least one of the discharge rollers, and guiding the conveyed sheet to the discharge unit;
Provided on the upstream side in the sheet conveying direction of the one discharge roller, and has a charge eliminating means for removing the charged potential on the sheet surface;
The changing means is
8. The discharge angle of the discharge unit is changed so that an arrangement relationship between the guide guide and the charge removal unit and the one discharge roller is not changed. 9. Sheet discharge device. 9. A sheet processing apparatus comprising: a sheet processing unit that performs a binding process on a bundle of sheets stacked on the second stacking tray; and a sheet discharge device according to claim 1. Image forming means for forming an image on a sheet;
The sheet processing apparatus according to claim 9, which processes a sheet on which an image is formed by the image forming unit;
An image forming apparatus comprising: Image forming means for forming an image on a sheet;
The sheet discharging apparatus according to any one of claims 1 to 8, wherein sheets on which images are formed by the image forming unit are stacked.
An image forming apparatus comprising:

Images