JP2005089121A - Sheet post-treatment device and image formation device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sheet post-treatment device with a simple constitution forming a bundle of sheets by conveying and aligning the sheet successively discharged to a tray for applying the post-treatment and applying stapling to the bundle of sheet wherein stable sheet conveying on the tray is achieved with less alignment deviation. <P>SOLUTION: There are provided a sheet conveying means for conveying the sheet loaded on the post-treatment tray to the same direction as a sheet discharge direction and to a reverse direction, and a crossing direction movement means for conveying the sheet to the sheet discharge direction and a perpendicular direction by moving the sheet conveying means to a direction perpendicular to the sheet discharge direction. The sheet is conveyed in the state that the roller of the sheet conveying means is contacted with the sheet and is abutted on a wall to carry out alignment. After the sheets are conveyed slightly more than an actual movement amount in a specified size of the sheet and abutted on the wall, the roller is slid on the sheet. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a sheet post-processing apparatus and an image forming apparatus that stack, align, or bind sheets discharged from an image forming apparatus such as a copying machine, a laser printer, a facsimile, or a complex machine thereof.

  Conventionally, a sheet stacking operation for stacking a plurality of discharged sheets, a sheet post-process for performing alignment processing for aligning a plurality of stacked sheets, processing for binding the aligned sheets (staple processing), and the like When binding a bundle of sheets, the apparatus and the image forming apparatus discharge the sheets so that the sheets are discharged onto the staple tray by the sheet discharge rollers. That is, when the trailing edge of the sheet passes through the sheet discharge rollers, the sheets are freely dropped onto the tray. The sheet is discharged, and the discharged sheet is moved in the direction along the sheet conveyance direction, and then the alignment operation is performed. After aligning the end portions in the sheet conveyance direction, the sheet bundle is bound.

  For this reason, the sheet post-processing apparatus has an elastic member called a paddle and an alignment belt that rotates in synchronization with a discharge roller for discharging the sheet onto the staple tray, and the nip point between the alignment belt and the staple tray by the paddle. After that, the sheet is abutted against the alignment abutting member by the frictional force of the alignment belt, and alignment in the conveying direction is performed.

  Further, the sheet discharged onto the staple tray and abutted against the alignment abutting member and aligned at the end in the sheet conveying direction is further subjected to an alignment operation such that the sheet is sandwiched in the direction perpendicular to the conveying direction by the width alignment member. The widths can be made uniform (see, for example, Patent Document 1).

JP 2002-37512 A (FIG. 2)

  However, in the above-described conventional apparatus, when the frictional force obtained by the rotation of the paddle is used as a method for aligning the sheet in the sheet conveyance direction, the deflection amount of the paddle increases as the number of sheets stacked increases. The contact pressure of the paddle increased, and there was a risk of buckling when the sheet abuts against the abutting portion.

  Further, in order to align the sheet in the sheet conveying direction, in addition to the paddle rotation mechanism, as another method, when the frictional force obtained by the rotation of the alignment belt is used, the alignment that occurs when the alignment belt rotates. There is a possibility that the aligned sheet bundle may be displaced due to the slight fluctuation of the belt.

  In addition, when the sheet is discharged onto the staple tray by the sheet discharge roller, the discharge roller discharges the sheet so as to kick out (flip) the sheet. When the sheet has been conveyed, the sheet may not be stably conveyed to the sheet abutting portion.

  In addition, since the sheets discharged onto the staple tray are simply returned and stacked by paddles and alignment belts, it is necessary to regulate the size and installation angle of the staple tray to prevent the following sheets from being fed and to return them stably. was there.

  Further, as a method of aligning in the sheet width direction, when a width aligning member that is movable in the sheet width direction is provided and the aligning is performed by moving the width aligning member to the sheet on the staple tray, the width aligning member is changed to the sheet. Depending on the position to be moved, it is necessary to take a wide staple tray. Assuming that subtle changes in the sheet size occur due to the effects of temperature, humidity, etc., the change is absorbed to some extent by attaching a spring to the width alignment member. However, the change may not be absorbed and the sheet may be buckled, which may cause misalignment.

  Further, in order to carry out the above operations, a large number of independent members such as a mechanism for aligning the sheet conveying direction and a mechanism for aligning the width direction of the sheet as described above are required, and the apparatus is complicated and large. It was.

  The present invention relates to a sheet post-processing apparatus and an image forming apparatus that can obtain stable sheet conveyance with a simple configuration with a small processing tray that is less affected by tray shape, angle, and the like, and that reduce sheet misalignment. The purpose is to provide.

  In order to achieve the above object, a sheet post-processing apparatus according to the present invention includes a sheet stacking unit that stacks sequentially discharged sheets, a sheet transport unit that transports sheets discharged to the sheet stacking unit, and the sheet transport A cross-direction moving means capable of moving the means in a direction crossing the sheet discharge direction, a regulating means for aligning sheet edges of the sheet, and a post-processing for post-processing the sheets aligned by the regulating means Means.

  The sheet post-processing apparatus of the present invention includes a sheet stacking unit that stacks sequentially discharged sheets, a sheet transport unit that can selectively transport the discharged sheets in the downstream direction and the upstream direction of the sheet discharge direction, and the sheet A regulating unit that abuts and aligns the upstream end of the sheets stacked on the stacking unit, a cross-direction moving unit that can move the sheet conveying unit in a direction crossing the sheet discharging direction, and a sheet discharging direction. Crossing side restricting means that abuts and aligns the sheet ends on the intersecting side, and post-processing means that performs post-processing on the sheets aligned by the restricting means.

  In the sheet post-processing apparatus of the present invention, the sheet conveying unit conveys the uppermost sheet of the sheets stacked on the sheet stacking unit, and aligns the uppermost sheet against the regulating unit and the intersecting side regulating unit. It is characterized by that.

  In the sheet post-processing apparatus of the present invention, the transport amount of each of the uppermost sheets by the sheet transport unit that abuts and aligns the sheet end with each of the regulating units corresponds to the sheet end against which the uppermost sheet abuts. Control means for controlling the conveyance amount of the sheet conveying means so that the sheet conveying means slides on the uppermost sheet after abutting the uppermost sheet is made longer than the distance to the regulating means. .

  In the sheet post-processing apparatus of the present invention, when the succeeding sheet is stacked on the sheet stacked on the sheet stacking unit and is transported by the sheet transporting unit, the sheet is followed by the movement of the succeeding sheet. Holding means for blocking is provided.

  The sheet post-processing apparatus according to the present invention further includes a second sheet stacking unit arranged in the vicinity of the sheet stacking unit and capable of moving in the vertical direction, and holds the sheets stacked on the sheet stacking unit, Transfer means for transferring the sheet to the sheet stacking means.

  The sheet conveying means in the sheet post-processing apparatus of the present invention is composed of a rotatable roller, and the outer peripheral portion thereof is an elastic body close to rubber such as rubber or foam.

  In order to achieve the above object, an image forming apparatus according to the present invention includes an image forming unit that forms an image, and any one sheet post-processing device that performs post-processing on a sheet on which an image is formed by the image forming unit. And.

  In order to achieve the above object, an image forming apparatus of the present invention includes an image forming unit that forms an image, a sheet stacking unit that sequentially stacks sheets on which images are formed by the image forming unit, and a sheet stacking unit. Sheet conveying means for conveying stacked sheets, crossing direction moving means capable of moving the sheet conveying means in a direction intersecting the sheet discharge direction, and regulating means for aligning the sheet edges of the sheets; Control means for controlling the sheet conveying means and the cross direction moving means.

  In order to achieve the above object, in the sheet post-processing apparatus of the present invention or the image forming apparatus of the present invention, a succeeding sheet is stacked on a sheet stacked on the sheet stacking unit and is transported by the sheet transporting unit. Holding means for preventing follow-up of the sheet due to movement of the succeeding sheet, second sheet stacking means arranged in the vicinity of the sheet stacking means and movable in the vertical direction, and sheets stacked on the sheet stacking means Holding the sheet, transferring the sheet to the second sheet stacking unit, and controlling the transfer unit to transfer the sheet to the second sheet stacking unit, and then transferring the sheet to the second sheet stacking unit. Control means for moving the second sheet stacking means to a position where the position of the upper surface of the sheet transferred to the means and the position of the stacking surface of the sheet stacking means are substantially equal.

  In order to achieve the above object, the sheet post-processing apparatus of the present invention or the image forming apparatus of the present invention further includes an up-and-down moving means for moving the sheet conveying means in the up-and-down direction with respect to the sheet placing means. Yes.

  In the sheet post-processing apparatus according to the present invention, when the sheets are sequentially discharged to the sheet stacking unit, the sheets are received by the sheet conveying unit, conveyed, and the sheet ends are aligned. The sheet can be conveyed and aligned with a low level of stability.

  In the sheet post-processing apparatus of the present invention, the sheet conveying means directly conveys the discharged sheet and abuts and aligns the trailing end of the sheet with the trailing end stopper, so that the sheets can be aligned reliably. Further, since the sheet conveying means is moved in the direction intersecting the sheet discharge direction as it is and the side edge of the sheet is abutted and aligned with the positioning wall, the sheet can be reliably aligned even with a small post-processing tray, The apparatus configuration can be simplified without providing a separate apparatus for aligning the sheet side edges.

  Since the sheet conveying means in the sheet post-processing apparatus of the present invention conveys and aligns the uppermost sheet of the sheets stacked on the sheet stacking means with its own weight and frictional force, a constant load is always applied to the uppermost sheet. Unlike the case where the sheet is aligned by rotation, the sheet can be stably conveyed and aligned without being affected by the number of stacked sheets, temperature, humidity, and the like.

  When the sheet post-processing apparatus of the present invention abuts and aligns the sheet end against the trailing end stopper and the positioning wall, the distance between the abutting sheet end, the trailing end stopper, and the positioning wall is determined by the sheet conveying means. The sheet conveying means slides on the uppermost sheet while adjusting the skew of the sheet after hitting the edge of the sheet, so it does not exert excessive force on the sheet and the influence of temperature, humidity, etc. Therefore, it is possible to absorb the influence due to the change in the sheet size due to the sheet size and to ensure the alignment.

  The sheet post-processing apparatus according to the present invention further includes a holding unit that holds the sheets stacked on the sheet stacking unit. Therefore, when the succeeding sheet is conveyed to the sheet stacking unit, the previously stacked sheet follows. It is possible to prevent following by movement of the sheet. In addition, a plurality of sheets can be efficiently aligned with a simple configuration regardless of the shape and installation angle of the post-processing tray.

  The sheet post-processing apparatus of the present invention further includes a second sheet stacking unit that is movable in the vertical direction in the vicinity of the sheet stacking unit, and the second sheet stacking unit while holding the sheets stacked on the sheet stacking unit. Since the post-processing tray for processing the sheets can be reduced in size and the sheet bundle after the post-processing can be successively conveyed to the second stacking means. A lot of sheets can be processed well.

  The sheet conveying means in the sheet post-processing apparatus of the present invention is composed of a rotatable roller, and its outer peripheral part is an elastic body close to rubber such as rubber or foam, so that it is optimal for conveying and aligning sheets. A frictional force and a conveying force can be obtained. In addition, since a load more than necessary is not applied to the sheet, the sheet is not damaged, and stable conveyance and alignment that are hardly affected by the state and type of the sheet can be obtained.

  In order to achieve the above object, an image forming apparatus according to the present invention includes an image forming unit that forms an image, and any one of the above-described sheet post-processing apparatuses that performs post-processing on a sheet on which the image is formed. Therefore, the sheet conveyed to the sheet post-processing apparatus in cooperation with the sheet post-processing apparatus can be efficiently and stably aligned and post-processed, and includes a sheet post-processing apparatus with a simple configuration. An image forming apparatus can be provided.

  In order to achieve the above object, an image forming apparatus according to the present invention includes an image forming unit that forms an image, a sheet stacking unit that sequentially stacks sheets on which images are formed, and a sheet transport unit that transports stacked sheets. And a control means for controlling the sheet conveying means to move the sheet conveying means in a direction intersecting the sheet discharge direction and align the sheet side edges by conveying the sheet by the sheet conveying means. Is provided in the image forming apparatus, it is possible to provide an image forming apparatus that reliably performs post-sheet processing such as sheet alignment processing with a simple configuration.

  In order to achieve the above object, the sheet post-processing apparatus of the present invention or the image forming apparatus of the present invention further includes the following sheet when the subsequent sheet is stacked and conveyed on the sheet stacked on the sheet stacking means. A holding means for preventing follow-up of the sheet due to movement; a second sheet stacking means disposed in the vicinity of the sheet stacking means; and a second sheet stacking means for holding the sheets stacked on the sheet stacking means; A transfer unit configured to transfer the sheet to the stacking unit; and an upper surface of the sheet transferred to the second sheet stacking unit after controlling the transfer unit to transfer the sheet to the second sheet stacking unit. And the position of the stacking surface of the sheet stacking means are controlled so as to include a control means for moving the second sheet stacking means to a substantially equal position. By controlling the physical tray and the stack tray that ultimately stacks the sheets after sheet processing, the sheet bundle after the sheet post-processing is transported to the stack tray one after another, and is transported and stacked on the stack tray. By controlling the position of the upper surface of the sheet to approximately the same height as the position of the sheet stacking surface of the sheet post-processing tray, the post-processing tray can be reduced in size, and a larger amount of sheets can be processed more efficiently.

  In order to achieve the above object, the sheet post-processing apparatus according to the present invention or the image forming apparatus according to the present invention further includes the sheet conveying means placed on the sheet when the sheet is conveyed by the sheet conveying means or the sheet alignment process is not performed. Since it is separated from the means, it does not unnecessarily impose a load on the sheet, does not damage the sheet, and can stably convey and align the sheet without being affected by the number of sheets stacked, temperature, humidity, etc. .

  Hereinafter, a sheet post-processing apparatus and an image forming apparatus according to an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a front sectional view showing a schematic internal configuration of a copying machine as an example of an image forming apparatus provided with a sheet post-processing apparatus of the present invention in an apparatus main body. Examples of the image forming apparatus include a copying machine, a facsimile machine, a printer, and a complex machine of these. Therefore, the sheet post-processing apparatus according to the present invention can be installed not only in a copying machine but also in other image forming apparatuses such as a facsimile, a printer, and a multi-function machine thereof. Further, the sheet post-processing apparatus may be incorporated in the apparatus main body of the image forming apparatus. It can also be used alone.

  In FIG. 1, reference numeral 400 denotes a sheet post-processing apparatus according to an embodiment of the present invention, 500 denotes a copying machine, and 300 denotes an automatic document feeder (hereinafter referred to as ADF) that automatically feeds a document.

The copier 500 includes a reader unit 100, a printer unit 200, a sheet post-processing device 400, and the like. An ADF 300 for supplying originals one by one onto the platen glass 102 is provided at the top of the copier 500. A sheet post-processing apparatus 400 that performs post-processing of sheets discharged from the apparatus main body 500A of the copier 500 is connected to the side of the apparatus main body 500A of the copier 500.
In FIG. 1, a reader unit 100 converts a document into image data. The printer unit 200 includes a plurality of types of sheet cassettes 204 and 205 on which a plurality of sheets are stacked, and forms image data as a visible image on a sheet according to a print command.

  When the document is conveyed to a predetermined position on the platen glass 102 by the ADF 300, the reader unit 100 turns on the lamp 103 of the reader unit 100 and the scanner unit 104 moves horizontally, and the lamp 103 irradiates the document. To do.

  The reflected light from the document is input to the CCD image sensor unit 109 through the mirrors 105, 106, 107 and the lens 108. The reflected light of the original irradiated to the CCD image sensor unit 109 is subjected to electrical processing such as photoelectric conversion in the CCD image sensor unit 109 and is subjected to normal digital processing. Thereafter, these image signals are input to the printer unit 200.

  The image signal input to the printer unit 200 is converted into an optical signal modulated by the exposure control unit 201, and is irradiated on, for example, the photoconductor 202 as an image forming unit. An electrostatic latent image is formed on the photosensitive member 202 by this irradiation light, and the electrostatic latent image on the photosensitive member 202 is developed and visualized by the developing device 203 to form a toner image. Then, in synchronization with the leading edge of the toner image, the sheet is conveyed from one of the sheet cassettes 204 and 205, and the toner image is transferred to the sheet by the transfer unit 206. The transferred image is fixed on the sheet by the fixing unit 207. The sheet on which the image has been fixed passes through a path 214 by a conveyance path direction switching member 209 and is discharged from the sheet discharge unit 208 to the outside of the apparatus main body 500A of the copier 500. Thereafter, the sheets are sorted, bound, and the like according to a sheet processing operation mode designated in advance by the sheet post-processing apparatus 400.

  Next, the order of forming sequentially read images on both sides of one sheet will be described.

  As described above, the sheet on which the image is fixed on one side by the fixing unit 207 is guided to the paths 215 and 218 by the direction switching members 209 and 217, and subsequently guided to the reverse path 212 by the direction switching member 213. After the trailing edge of the sheet passes through the direction switching member 213, when the direction switching member 213 is switched and the rotation direction of the roller 211 is reversed, the sheet is reversed in the conveyance direction and the image fixing surface (front surface) is raised. In this state, the sheet is conveyed to the transfer paper stacking unit 210 and temporarily stands by there. Next, when the next document is prepared on the platen glass 102 by the ADF 300, the image of the document is read by the reader unit 100, and in the same manner as in the above-described process, exposure and development are performed on the photoconductor 200 through the printer unit 200. An image is formed. The sheet waiting on the transfer paper stacking unit 210 is conveyed to the transfer unit 206 in synchronization with the leading edge of the toner image, the image is transferred to the back surface of the sheet, and fixed on the fixing unit 207, and the direction switching member. 209 passes the path 214 and is discharged from the sheet discharge unit 208 to the outside of the apparatus main body 500A of the copier 500. As described above, two document images can be formed on the front and back surfaces of the same sheet.

(Sheet post-processing equipment)
FIG. 2 is a schematic front sectional view of the sheet post-processing apparatus 400. FIG. 3 is a block diagram illustrating a connection relationship between the control unit of the sheet post-processing apparatus 400, a sensor, a motor, and the like.

  The sheet post-processing apparatus 400 includes a stapling function that is, for example, a binding operation by the stapler unit 420 in addition to a sorting operation for sorting sheets.

The sheet post-processing apparatus 400 receives, for example, a post-processing tray 410 and a sheet discharged from the apparatus main body 500A of the copier 500 as a sheet stacking unit that stores sheets sequentially discharged from the apparatus main body 500A of the copier 500, and performs post-processing. For example, an offset roller 407 is used as a sheet conveying unit that performs alignment processing on the tray 410, and a second stacking unit that finally stacks a sheet bundle formed on the post-processing tray 410 is used. As a control unit for controlling the sheet post-processing apparatus 400 based on a control signal from the control unit 501 (see FIG. 1), for example, the CPU 111, sensors 403, 150, 160, 230, and 415, which will be described in detail later, and motors 431. , 432, 430, 135, solenoids 433, 434, seal Includes a stapling stapler unit 420 or the like bundle, a bundle of sheets of the number that corresponds to the number of documents is formed on the post-processing tray 410, is arranged to discharge the stack tray 421 for each sheet bundle. The control unit 501 and the CPU 111 in the apparatus main body 500A may be integrated into one of them and controlled.
In FIG. 5, as a sheet conveying unit, for example, a conveying motor 431, a belt 435, a square shaft 418, pulleys 442 and 443, a belt 437, an offset roller arm 406, an offset roller 407, and the like are also used. For example, a transport direction moving device 446 is configured as a transport direction moving means for selectively moving between the downstream side and the upstream side.

  The offset motor 432, the pinion 439, the rack 441, the rack support member 444, the square shaft 418, the offset roller arm 406, the offset roller 407, and the like position the offset roller 407 with the offset home position and the sheet as the sheet alignment position. For example, a cross-direction moving device 445 is configured as a cross-direction moving unit that moves in a direction crossing the sheet conveying direction to the position to be moved to the wall 416.

  In FIG. 3, as a control means of the sheet post-processing apparatus 400, for example, a CPU 111 has a ROM 110 therein, reads out and executes a control program corresponding to the flowcharts of FIGS. It comes to perform control. Further, the CPU 111 has a built-in RAM 120. The RAM 120 stores work data 121 such as an offset movement amount and a sheet size shown in FIG. 3B, and the CPU 111 controls each unit based on the work data 121. ing.

  An input port of the CPU 111 detects whether an inlet sensor 403 that detects a sheet sent from the apparatus main body 400A to the sheet receiving unit 401 illustrated in FIG. 2 and whether the offset roller 407 illustrated in FIG. 5 is in the offset home position. The offset home position sensor 150, the bundle discharge home position sensor 160 for detecting whether or not the sheet bundle discharge member 413 shown in FIG. 7 is at the home position 413a, and whether or not the sheet bundle is discharged to the stack tray 421 shown in FIG. A sheet bundle discharge sensor 230 to be detected, and a sensor such as a sheet discharge sensor 415 for detecting whether or not a sheet has been discharged and stacked on the post-processing tray 410 shown in FIG. 6 are connected.

  The output port of the CPU 111 includes a conveyance motor 431 that rotates the offset roller 407 shown in FIG. 5 in the direction of conveying the sheet downstream and the direction of conveying the sheet upstream, and the offset roller 407 shown in FIG. An offset motor 432 for moving the offset home position and a position for moving the sheet to the positioning wall 416 as a sheet alignment position in a direction intersecting the sheet conveying direction, and the sheet bundle discharge member 413 shown in FIG. A sheet bundle discharge motor 430 that moves the sheet tray to a sheet bundle discharge position, a stack tray lift motor 135 that lifts and lowers the stack tray 421 shown in FIG. 7, a pickup solenoid 433 that lifts and lowers the offset roller 407 shown in FIG. 5, and a sheet shown in FIG. A clamp that opens and closes the clamp member 412 Such as up solenoid 434 is connected.

  The CPU 111 determines each motor, solenoid, stapler unit 420, etc. connected to the output port according to a program for executing the flowcharts shown in FIGS. 8 and 9 stored in the ROM 110 based on the detection signals of these sensors. It comes to control.

  The CPU 111 includes a serial interface unit 130, and exchanges control data and control signals with the control unit 501 of the apparatus main body 500A of the copying machine 500. The CPU 111 controls each unit based on control data and control signals sent from the control unit 501 of the apparatus main body 500A via the serial interface unit 130.

  4 to 6 are diagrams showing a driving mechanism of the offset roller 407. FIG. The offset roller 407 is supported by an offset roller arm 406 that can be rotated up and down in the directions of arrows U and D so that the sheet can be received on the post-processing tray 410. The offset roller arm 406 is rotatably supported on a square shaft 418 having a square cross section by a round hole 406a. Note that the offset roller arm 406 is arranged outside the pair of offset rollers 407 in FIGS. 6 and 10 to 16 in order to make the configuration easy to understand. As shown in FIG. 4, the pair is disposed between a pair of offset rollers 407.

  The offset roller arm 406 is moved up and down by a pickup solenoid 433 via a down lever. The offset roller 407 is rotated by a conveyance motor 431 via a belt 435, a square shaft 418, a pulley 442, a belt 437, and a pulley 443. The conveyance motor 431 rotates the conveyance roller 405 and the offset roller 407 in the sheet conveyance direction or in the opposite direction to the sheet conveyance direction by an amount corresponding to the rotation amount. The pulley 442 is provided on the square shaft 418 by a square hole (not shown) so that the pulley 442 rotates integrally with the square shaft 418 and can move in the thrust direction on the square shaft 418 by the engagement of the square hole and the square shaft 418. It has become.

  Between the pair of offset roller arms 406, a U-shaped rack support member 444 having a rack 441 is supported by a square shaft 418. The rack support member 444 is rotatably provided on the square shaft 418 through a round hole (not shown). For this reason, the rack support member 444 does not rotate following the angular axis 418 even when the angular axis 418 rotates, and can move in the thrust direction on the angular axis 418. The rack 441 meshes with a pinion 439 provided on a fixed offset motor 432. The pickup solenoid 433 is movable along the angular axis 418.

  Therefore, the belt 437, the pulley 443, the offset roller arm 406, and the offset roller 407 can be rotated up and down in the directions of arrows U and D in FIG. The stapler unit 420 can be moved closer to and away from the stapler unit 420 as the rack support member 444 is guided.

  The offset roller 407 is lowered by its own weight and pressed against the upper surface of the sheet when the sheet discharge sensor 415 detects that the sheet is stacked on the post-processing tray 410 and the pickup solenoid 433 is turned off. The sheet is conveyed downstream so that the entire sheet is stacked on the post-processing tray 410.

  Further, the offset roller 407, after conveying the sheet to the post-processing tray 410, stops and rotates in the reverse direction, and regulates the sheet upstream end (sheet rear end) serving as an alignment position reference in the sheet conveying direction. For example, the upstream end of the sheet is abutted against the rear end stopper 411, and the upstream end is aligned.

  Further, when the offset motor 432 rotates in FIG. 5, the offset roller 407 is moved by the pinion 439 and the rack 441 with respect to the sheet conveyance direction, which is the binding position of the stapler unit 420 and serves as the alignment position reference in the sheet width direction. As the crossing side restricting means for restricting the crossing direction, for example, it can be moved toward the positioning wall 416. The reason why the offset roller 407 moves toward the positioning wall 416 is to move the sheet to the positioning wall 416 by using the contact friction of the offset roller 407 with respect to the sheet to move the sheet following the offset roller 407. .

  The sheet adjusted by the offset roller 407 to the alignment position in the sheet conveyance direction (the abutting position of the trailing end stopper 411) is moved to the positioning wall 416 in the direction intersecting the sheet conveyance direction by the frictional force of the offset roller 407. After moving and abutting the side edge of the sheet against the positioning wall 416, the offset roller 407 continues to slide on the sheet and stops. By sliding on the sheet in this manner, the sheet can be reliably aligned with the positioning wall 416.

  In order to obtain a more effective alignment effect described above, the present embodiment uses the offset roller 407 and a hollow roller in which the outer peripheral portion of the roller is made of ethylene propylene rubber (EPDM). As for the material, in addition to EPDM, foamed urethane, sponge, or the like may be used as an elastic body having elasticity close to rubber.

  4, 6, and 7 are diagrams for explaining the configuration of, for example, a sheet bundle discharge member 413 as a transfer unit that transfers a sheet on the post-processing tray 410 to the stack tray 421 and a holding unit that holds the sheet. is there. The sheet bundle discharge member 413 installed near the rear end stopper 411 can move toward and away from the stack tray 421 by the pinion 451 and the rack 452 when the sheet bundle discharge motor 430 rotates. The sheet bundle discharge member 413 is fixed at the home position by excitation of the sheet bundle discharge motor 430. The sheet clamp member 412 of the sheet bundle discharge member 413 is opened and closed in the vertical direction of the arrow shown in FIG.

  In the above configuration, the control unit 501 of the apparatus main body 500A of the copier 500 to which the sheet post-processing apparatus 400 shown in FIG. 1 is attached knows the size of the sheet discharged from the sheet discharge unit 208. For this reason, the CPU 111 of the sheet post-processing apparatus 400 formed of a microcomputer system performs serial communication with the control unit 501 of the apparatus main body 500A, and the size of the sheet carried on the post-processing tray 410 and the binding process for the sheet. It is possible to grasp whether or not to implement.

  4 and 7 are diagrams showing a schematic configuration of the sheet bundle discharging mechanism.

  For example, the sheet bundle discharge member 413 as the sheet holding unit holds the sheet bundle PB aligned by the alignment operation described later of the offset roller 407 on the post-processing tray 410, and bundles it from the home position 413 a toward the stack tray 421. It moves to the take-out position 413b and is discharged from the post-processing tray 410 to the stack tray 421. The sheet bundle discharge member 413 is moved by rotating the pinion 451 and moving the rack 452 by the sheet bundle discharge motor 430. The home position 413 a of the sheet bundle discharge member 413 is detected by a bundle discharge home position sensor 160. Further, whether or not a sheet bundle is discharged to the stack tray 421 is detected by a sheet bundle discharge sensor 230 provided on the stack tray 421.

  In the sheet post-processing apparatus 400 of the present embodiment, since the sheet bundle PB stacked on the stack tray 421 constitutes a part of the post-processing tray 410, when the sheet bundle PB is discharged from the post-processing tray 410, The stack tray 421 is lowered by the stack tray lifting / lowering motor 135 until the uppermost surface of the sheet bundle PB stacked on the stack tray 421 substantially coincides with the post-processing tray 410.

  Next, the operation of the present embodiment configured as described above is shown in the block diagram of FIG. 3, the flowcharts shown in FIGS. 8 and 9, FIGS. 1, 2, 4 to 7, and 10 to 16. This will be explained based on.

  First, when copying operation by the apparatus main body 500A of the copying machine 500 is started, the CPU 111 of the sheet post-processing apparatus 400 checks whether or not a sheet discharge signal has been received from the control unit 501 of the copying machine 500 (S100). . When the CPU 111 receives a sheet discharge signal from the control unit 501 via the serial interface unit 130, the CPU 111 drives the pickup solenoid 433 shown in FIG. 5 to move the offset roller arm 406 to the arrow U shown in FIGS. 4 and 6. The offset roller 407 supported by the offset roller arm 406 is raised (S110). The position where the offset roller 407 is raised is the position indicated by the broken line in FIG.

  Next, the CPU 111 starts the conveyance motor 431 and conveys the conveyance roller 405 and the offset roller 407 that rotates in the conveyance direction in synchronization with the conveyance roller 405 in the same direction as the sheet discharge direction of the copying machine. As shown in FIG. 10, it is rotated in the direction of arrow E shown in FIG. 10 (S120). As a result, the offset roller 407 rises and rotates to wait for a sheet to be fed.

  The leading edge of the first sheet passes through the entrance sensor 403 (S130), the sheet reaches the conveyance roller 405, and power is transmitted from the conveyance roller 405 to the sheet, and the sheet discharge section inside the apparatus main body 500A of the copier 500 When the sheet is separated from 208, the delivery of the sheet is completed (S140).

  The CPU 111 conveys the sheet to the post-processing tray 410 by the conveyance roller 405 and turns off the pickup solenoid 433 before the sheet is completely removed from the conveyance roller 405 (S150), and the offset is indicated by the solid line in FIG. The roller 407 is landed on the sheet by its own weight, and the sheet surface is pressed. The offset roller 407 has already rotated in the direction of arrow E, and continues to rotate by the transport motor 431 to transport the sheet in the direction of arrow F, which is the downstream direction. When the sheet is conveyed to a predetermined position where the sheet discharge sensor 415 shown in FIG. 6 detects the trailing edge of the sheet P (S160), the CPU 111 stops the conveyance motor 431 and temporarily rotates the offset roller 407. The conveyance is stopped in the direction of arrow F (S170).

  When the rotation of the offset roller 407 stops, the CPU 111 turns on the clamp solenoid 434 shown in FIG. 4 (S180) and opens the sheet clamp member 412 installed in the vicinity of the rear end stopper 411.

  Thereafter, the CPU 111 rotates the transport motor 431 in the direction opposite to the sheet transport direction, and the offset roller 407 rotates in the reverse direction in the arrow G direction as shown in FIG. Pulling back in the M direction, as shown in FIG. 12, the upstream end (sheet rear end) of the sheet is abutted against the rear end stopper 411 (S190), and then the rotation is stopped.

  Here, the CPU 111 controls the amount of rotation of the offset roller 407 when the sheet is abutted against the trailing end stopper 411 and takes into account the skew of the sheet that occurs when the sheet is fed from the apparatus main body 500A of the copying machine 500. The sheet is rotated so that the sheet can be conveyed a little more than the distance from the point where the sheet conveyance is stopped and switched back to the rear end stopper 411. In this way, the upstream end of the sheet can be reliably abutted against the trailing end stopper 411, and the skew of the sheet can be corrected.

  Next, the CPU 111 checks the size information of the sheet ejected from the copier 500 based on the work data 121 stored in the RAM 120 (S200), and the offset movement amount corresponding to the size of the ejected sheet, that is, the later A moving distance necessary for pressing the sheet inserted on the processing tray 410 against the positioning wall 416 in the width direction is calculated (S210).

  The CPU 111 starts the offset motor 432, and moves the offset roller 407 through the rack and pinion by a predetermined distance in the direction of arrow J from the position of the broken line to the position of the solid line as shown in FIG. 13 (S220).

  The sheet in contact with the offset roller 407 moves together with the offset roller 407 in the direction of the positioning wall 416 by the frictional force of the offset roller 407. After the offset roller 407 abuts the side edge of the sheet against the positioning wall 416, the offset roller 407 slides slightly on the sheet and stops. Then, the CPU 111 corrects the misalignment in the conveyance direction after the offset movement. The conveyance motor 431 is rotated in the direction opposite to the sheet conveyance direction, and the offset roller is rotated again in the direction opposite to the conveyance direction (arrow G direction) to perform the alignment correction operation on the upstream side of the sheet, and then the conveyance motor 431. , And the rotation of the offset roller 407 is stopped. By performing the alignment correction operation on the upstream end of the sheet, the alignment of the first sheet is completed (S230).

  Next, the CPU 111 turns on the pickup solenoid 433 and raises the offset roller 407 in the arrow U direction shown in FIG. 14 (S240), and then turns off the clamp solenoid 434 and closes the sheet clamp member 412 so that the aligned sheet is obtained. Is held (S250).

  As a result, as shown in FIG. 15, the sheet discharged first is sheet clamped in a state where the upstream end of the sheet is aligned by the trailing end stopper 411 and the side end of the sheet is aligned by the positioning wall 416 (the position of 416a). Since the sheet 412 is pressed and held by the member 412, the sheet is not affected by the follow-up or the like with respect to the conveyance in the conveyance direction of the second and subsequent sheets discharged by the offset roller 407 and the like, and remains aligned. Can be held.

  Next, the CPU 111 drives the offset motor 432 to move the offset roller 407 from the position indicated by the broken line to the home position indicated by the solid line while being lifted as shown in FIG. 15 via the rack and pinion. (S260). The CPU 111 recognizes the home position by receiving the detection signal of the offset home position sensor 150 shown in FIGS. 3 and 5, and controls the driving of the offset motor 432.

  Thereafter, the CPU 111 checks whether or not the sheet stored on the post-processing tray 410 is a sheet corresponding to the final page of the copy document based on the information sent from the apparatus main body 500A of the copying machine 500 (S270). If it is determined that the page is not the final page based on the information sent from the apparatus main body 500A of the copier 500, the process returns to S100 and the sheet discharge signal sent from the control unit 501 of the copier 500 is received next. The above-described flow is repeated until the last page sheet is stored in the post-processing tray 410. Thus, every time a sheet is discharged from the apparatus main body 500A of the copying machine 500, the control unit of the sheet post-processing apparatus 400 grasps the size of the sheet and calculates an offset movement amount suitable for the sheet. The sheet grounded to the offset roller 407 is subjected to alignment processing based on the calculated movement amount, and is reliably aligned with the positioning wall 416.

  On the other hand, when it is determined that the page is the last page, a sheet bundle corresponding to the copy document is formed on the post-processing tray 410, and therefore the CPU 111 determines whether or not the stapling process is selected. A check is made (S280), and if it is selected, the stapler unit 420 shown in FIG. 5 is driven to execute the stapling process (S290).

  After the stapling process is completed or when the stapling process is not selected, the CPU 111 operates the clamp solenoid 434 to cause the sheet clamp member 412 of the sheet bundle discharge member 413 to grip the sheet bundle. The CPU 111 advances the sheet bundle discharge member 413 that has grasped the sheet bundle from the home position 413a toward the stack tray 421 through the pinion 451 and the rack 452 by controlling the sheet bundle discharge motor 430 as shown in FIG. Then, the sheet is moved to the bundle discharge position 413b and the clamp solenoid 434 is operated to discharge the sheet bundle to the stack tray 421 (S300).

  Thereafter, the CPU 111 controls the stack tray lifting / lowering motor 135 to lower the stack tray 421 by substantially the same distance as the thickness of the sheet bundle (S310).

  The CPU 111 reverses the sheet bundle discharge motor 430 to return the sheet bundle discharge member 413 to the home position 413a (S320), stops the conveyance motor 431 to stop the rotation of the conveyance roller 405 and the offset roller 407 (S330), The pickup solenoid 433 is turned off and the offset roller 407 is lowered (S340), and a series of processing is completed.

  In the embodiment of the present invention, a fixed stapler disposed in the vicinity of the positioning wall 416 is used. However, when a plurality of staplers or a movable stapler is used, different portions or a plurality of portions of the sheet bundle are used. Staple processing is also possible.

  In this embodiment, the roller member is used as the sheet conveying unit and for aligning the sheet. However, when the sheet on the post-processing tray conveyed by the sheet conveying unit is moved toward the trailing edge stopper, For example, the member itself can be moved back and forth in the conveyance direction, and the sheet can be moved in a direction crossing the conveyance direction, and the same effect can be obtained by using the sheet conveyance direction movement unit and the sheet cross direction movement unit. Is obtained.

  Further, in this embodiment, the CPU 111 performs control while reading the program corresponding to the flowcharts shown in FIGS. 8 and 9 stored in the ROM 110, but the hardware may perform the processing on the control program. Similar effects can be obtained.

1 is a schematic front sectional view of a copying machine which is an example of an image forming apparatus provided with a sheet post-processing apparatus according to an embodiment of the present invention in an apparatus main body. It is a section explanatory view showing the composition of the sheet post-processing apparatus in the embodiment of the present invention. It is a block diagram which shows the connection relation of the control part of a sheet | seat post-processing apparatus in embodiment of this invention, a sensor, a motor, etc. FIG. (A) It is the whole block diagram. (B) It is a figure which shows the content of the work data stored in RAM. FIG. 3 is a schematic front view of a drive mechanism for an offset roller and a conveyance roller and a drive mechanism for a sheet bundle discharge member of the sheet post-processing apparatus according to the embodiment of the present invention. FIG. 3 is a schematic plan view of a drive mechanism for an offset roller and a conveyance roller of the sheet post-processing apparatus according to the embodiment of the present invention. FIG. 4 is a schematic front view illustrating an arrangement relationship among an offset roller, a sheet bundle discharge member, and a post-processing tray of the sheet post-processing apparatus according to the embodiment of the present invention. FIG. 10 is a diagram for explaining the movement operation of the sheet bundle discharge member of the sheet post-processing apparatus according to the embodiment of the present invention. 6 is a flowchart for explaining the operation of the sheet post-processing apparatus according to the embodiment of the present invention. It is a flowchart following the flowchart of FIG. In the sheet post-processing apparatus of the embodiment of the present invention, it is a perspective view of the offset roller and the like when the sheet is discharged on the post-processing tray. FIG. 6 is a perspective view of the offset roller and the like when the offset roller is transporting the sheet toward the trailing end stopper in the sheet post-processing apparatus of the embodiment of the present invention. In the sheet post-processing apparatus of the embodiment of the present invention, the offset roller is a perspective view of the offset roller and the like when the sheet abuts the trailing end stopper. FIG. 6 is a perspective view of the offset roller and the like when the offset roller moves the sheet to the alignment position in the sheet post-processing apparatus of the embodiment of the present invention. In the sheet post-processing apparatus of the embodiment of the present invention, after the offset roller has moved the sheet to the alignment position, it is a perspective view of the offset roller when it is separated from the sheet. In the sheet post-processing apparatus of the embodiment of the present invention, the sheet clamp member presses the sheet against the processing tray and the offset roller returns to the offset home position and is a perspective view of the offset roller and the like. In the sheet post-processing apparatus of the embodiment of the present invention, it is a diagram for explaining the operation of the offset roller, and the accompanying movement of the sheet.

Explanation of symbols

P sheet PB sheet bundle 100 reader unit 111 CPU
200 Printer unit 202 Photosensitive member 208 Sheet discharge unit 300 Automatic document feeder 400 Sheet post-processing device 403 Entrance sensor 405 Conveying roller 407 Offset roller 410 Post-processing tray 411 Rear end stopper 412 Sheet clamp member 413 Sheet bundle discharging member 416 Positioning wall 420 Stapler unit 421 Stack tray 431 Conveyor motor 432 Offset motor 433 Pickup solenoid 434 Clamp solenoid 500 Copier 500A Copier main body 501 Control unit of main body

Claims (11)

Sheet stacking means for stacking sequentially discharged sheets;
Sheet conveying means for conveying the sheet discharged to the sheet stacking means;
Cross direction moving means capable of moving the sheet conveying means in a direction crossing the sheet discharge direction;
Regulating means for aligning the sheet edges of the sheet;
Post-processing means for post-processing the sheets aligned by the restriction means;
A sheet post-processing apparatus comprising: Sheet stacking means for stacking sequentially discharged sheets;
Sheet conveying means capable of selectively conveying the discharged sheet in the downstream direction and the upstream direction in the sheet discharging direction;
Regulation means for abutting and aligning the upstream end of the sheets stacked on the sheet stacking means;
Cross direction moving means capable of moving the sheet conveying means in a direction crossing the sheet discharge direction;
Crossing side regulating means for abutting and aligning the sheet end on the side crossing the sheet discharge direction;
Post-processing means for post-processing the sheets aligned by the restriction means;
A sheet post-processing apparatus comprising:   The sheet conveying means conveys the uppermost sheet of the sheets stacked on the sheet stacking means, and aligns the uppermost sheet by abutting against the restricting means and the intersecting side restricting means. The sheet post-processing apparatus according to 2.   The conveyance amount of each of the uppermost sheets by the sheet conveying unit that abuts and aligns the sheet end with each regulating unit is greater than the distance to the regulating unit corresponding to the sheet end against which the uppermost sheet strikes, and 4. The apparatus according to claim 1, further comprising a control unit that controls the conveyance amount of the sheet conveyance unit so that the sheet conveyance unit slides on the uppermost sheet after the uppermost sheet is abutted. 5. The sheet post-processing apparatus according to claim 1.   And a holding unit that prevents follow-up of the sheet due to movement of the succeeding sheet when the succeeding sheet is stacked on the sheet stacking unit and stacked on the sheet and is transported by the sheet transporting unit. The sheet post-processing apparatus according to claim 1. A second sheet stacking means arranged in the vicinity of the sheet stacking means and movable in the vertical direction;
Transfer means for holding the sheets stacked on the sheet stacking means and transferring the sheets to the second sheet stacking means;
The sheet post-processing apparatus according to any one of claims 1 to 5, further comprising:   The sheet rear means according to any one of claims 1 to 6, wherein the sheet conveying means includes a rotatable roller, and an outer peripheral portion thereof is an elastic body close to rubber such as rubber or foam. Processing equipment.   An image comprising: an image forming unit that forms an image; and a sheet post-processing device according to claim 1 that performs post-processing on a sheet on which an image is formed by the image forming unit. Forming equipment. Image forming means for forming an image, sheet stacking means for sequentially stacking sheets on which images are formed by the image forming means,
Sheet conveying means for conveying sheets stacked on the sheet stacking means;
Cross direction moving means capable of moving the sheet conveying means in a direction crossing the sheet discharge direction;
Regulating means for aligning the sheet edges of the sheet;
Control means for controlling the sheet conveying means and the cross direction moving means;
An image forming apparatus comprising: Holding means for preventing the following of the sheet from being moved by the movement of the succeeding sheet when the succeeding sheet is stacked on the sheet stacked on the sheet stacking means and conveyed by the sheet conveying means;
A second sheet stacking means arranged in the vicinity of the sheet stacking means and movable in the vertical direction;
Transfer means for holding the sheets stacked on the sheet stacking means and transferring the sheets to the second sheet stacking means;
After the sheet is transferred to the second sheet stacking unit by controlling the transfer unit, the position of the upper surface of the sheet transferred to the second sheet stacking unit and the position of the stacking surface of the sheet stacking unit Control means for moving the second sheet stacking means to a substantially equal position;
A sheet post-processing apparatus or an image forming apparatus according to claim 1, wherein the sheet post-processing apparatus or the image forming apparatus is provided. The sheet post-processing apparatus or image forming apparatus according to claim 1, further comprising an up-down direction moving unit that moves the sheet conveying unit in an up-down direction with respect to the sheet placing unit.

Images