JP2009001426A - Sheet processing device and sheet processing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique capable of stably moving a bundle of sheets from a stapler after stapling operation regardless of the number of sheets constituting the sheet bundle or a conveying resistance. <P>SOLUTION: When a bundle of stapled sheets are moved in a direction for retreating from a stapler by a stacker, alignment rollers are brought into contact with the sheet bundle held by the stacker, so as to assist the movement of the sheet bundle. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a sheet processing technique for performing predetermined processing on a sheet.

  2. Description of the Related Art Conventionally, in a sheet processing apparatus that performs predetermined processing such as stapling processing or folding processing on a sheet, the sheet bundle is moved to a position where folding processing is performed after execution of stapling processing on the sheet bundle.

  In the movement of the sheet bundle at this time, a configuration is known in which the sheet bundle positioning stopper used at the stapling process is moved, and the sheet bundle is moved to a predetermined folding processing standby position by following the stopper by its own weight.

  However, in the configuration in which the sheet bundle after the stapling process is retracted from the stapler using the self-weight of the sheet bundle as in the above prior art, the number of sheets constituting the stapled sheet bundle is large. In addition, when the sheet bundle conveyance resistance is large due to the influence of static electricity or the like, the bundle conveyance may not be performed normally.

  The present invention has been made in order to solve the above-described problems, and the sheet bundle after the stapling process can be retreated from the stapler stably regardless of the number of sheets constituting the sheet bundle, the conveyance resistance, and the like. The object is to provide a technique that can be performed.

  In order to solve the above-described problem, a sheet processing apparatus according to an aspect of the present invention acquires at least one of information regarding a sheet bundle to be folded by a folding blade and information regarding an environment in which the folding process is performed. And a folding position adjusting unit that adjusts a position where the folding blade is brought into contact with the sheet bundle to be folded based on the information acquired by the information acquiring unit. It is set as the characteristic characterized by becoming.

  In order to solve the above-described problem, a sheet processing apparatus according to an aspect of the present invention holds a sheet bundle and is held by the stacker that can move substantially parallel to the sheet surface of the sheet bundle. An aligning roller that can be brought into contact with and separated from the sheet surface of the sheet, and abuts the rotating roller surface against the sheet to align with the reference position in the stacker; and the aligning roller A stapler that performs a stapling process on a sheet bundle that has been aligned and moved to a predetermined position by the stacker, and a sheet bundle that has been subjected to the stapling process is rotated when the stacker is moved in a direction to retract from the stapler. And a control section for bringing the alignment roller into contact with a sheet bundle held by the stacker. It has a configuration that.

  In order to solve the above-described problem, a sheet processing apparatus according to an aspect of the present invention is a stapling unit that performs a stapling process on a sheet bundle conveyed to a predetermined stapling position in a sheet conveyance path. A pressing portion that presses the sheet surface of the sheet bundle when performing the operation, and a sheet bundle that is arranged so as to face the inside of the sheet conveying path from an opening provided on the inner wall of the sheet conveying path, A staple unit that staples the sheet bundle by cooperating with a receiving unit that receives the sheet, and a sheet conveying direction in the sheet conveying path supported by one of the wall surface of the sheet conveying path and the receiving unit. And an elastic member that covers the vicinity of the upstream end portion of the receiving portion.

  In order to solve the above-described problem, a sheet processing apparatus according to an aspect of the present invention includes a first conveyance speed and a roller pair capable of conveying a sheet at a second conveyance speed that is faster than the first conveyance speed. A folding blade that pushes a sheet bundle to be folded into the nip of the roller pair driven at the first conveying speed by moving from the standby position toward the nip of the roller pair; and the folding blade Until the trailing edge of the sheet bundle pushed into the nip portion of the roller pair by the folding blade passes through the nip of the roller pair after finishing the pushing operation of the sheet bundle and starting the returning operation to the standby position. A conveyance control unit that switches the sheet conveyance speed by the roller pair from the first conveyance speed to the second conveyance speed at a predetermined timing between the first conveyance speed and the second conveyance speed. We are trying to be.

  In order to solve the above-described problem, a sheet processing apparatus according to an aspect of the present invention includes a sensor that detects a relatively moving sheet, and a size that calculates a size of the sheet based on a detection result of the sensor. A calculation unit; and a processing position adjustment unit that adjusts a position where the predetermined process is performed on a sheet bundle to be subjected to a predetermined process based on the sheet size calculated by the size calculation unit. It is set as the characteristic characterized by becoming.

  In order to solve the above-described problem, a sheet processing apparatus according to an aspect of the present invention performs switchback conveyance of a first sheet conveyance path for conveying a sheet and a sheet conveyed in the first sheet conveyance path. And a second sheet conveying path having at least one of an opening, a protrusion, and a recess in the vicinity of the joining position with the first sheet conveying path in the conveying path. And a slide part that allows the first sheet conveyance path and the second sheet conveyance path to be integrally pulled out of the apparatus.

  As described above in detail, according to the present invention, the sheet bundle after the stapling process can be stably retracted from the stapler regardless of the number of sheets constituting the sheet bundle, the conveyance resistance, and the like. Technology can be provided.

  Embodiments of the present invention will be described below with reference to the drawings.

(First embodiment)
First, a first embodiment of the present invention will be described.

  FIG. 1 is a diagram for explaining a schematic configuration of a sheet processing apparatus 1F according to a first embodiment of the present invention and an image processing apparatus M including the sheet processing apparatus 1F.

  As shown in the figure, an image processing apparatus M according to the present embodiment forms an image with an image reading apparatus 1A that reads an image of a document, an image forming apparatus 1P that forms an image on a sheet, and an image forming apparatus 1P. The sheet processing apparatus 1 </ b> F performs predetermined post-processing on the processed sheet. In the configuration example shown in the figure, a sheet on which an image is formed by the image forming apparatus 1P is conveyed in the sheet conveying direction (arrow direction) in the figure and supplied to the sheet processing apparatus 1F.

  Next, details of the sheet processing apparatus 1F according to the present embodiment will be described.

  FIG. 2 is a longitudinal sectional view showing the basic configuration of the sheet processing apparatus 1F according to the first embodiment of the present invention. The sheet processing apparatus 1F according to the present embodiment includes a folding processing function that performs a middle folding process on a sheet supplied from the image forming apparatus 1P with a center position in the sheet conveyance direction as a folding position, and a predetermined position by the stacker 2. And a stapling function for binding the bundle of sheets moved to the position by the staple 5. Hereinafter, the unit that performs the folding process and the unit that performs the stapling process are collectively referred to as a saddle unit.

  In the sheet processing apparatus 1F and the image processing apparatus M according to the present embodiment, not only a paper medium such as plain paper or cardboard but also a sheet such as an OHP film can be handled as a medium. For the sake of convenience, a case where the sheet to be processed in the sheet processing apparatus 1F and the image processing apparatus M is a paper medium will be described as an example.

  The saddle unit in the sheet processing apparatus 1F is disposed as close to the lower side as possible in the vertical direction of the sheet processing apparatus 1F. The sheets discharged from the image forming apparatus 1P are temporarily stacked and stored on the stack tray 1 via the conveyance path A. The stack tray 1 in the present embodiment is arranged to be inclined with respect to the vertical direction. The sheets stacked and stored on the stack tray 1 are assisted to slide down by the rotationally driven assist roller 42, and the lower end of the sheet is abutted against a stacker claw (so-called stopper) of the stacker 2 to align. Is done.

  The timing of assisting the movement of the sheet by the assist roller 42 is a discharge roller sensor provided on the conveyance path A (which functions as an optical sensor and a media sensor, and the reflectance, surface roughness, thickness, etc. of the sheet surface). It is determined based on the sheet detection timing by 41). The sheet bundle temporarily stacked and stored in the stack tray 1 in this way is aligned by sandwiching both end positions in the direction orthogonal to the sheet conveying direction by the lateral alignment mechanism 3.

  The sheet bundle on the stack tray 1 aligned as described above is subjected to a stapling process by a stapler 5 provided near both ends in a direction orthogonal to the sheet conveying direction.

  The sheet bundle that has been stapled by the stapler 5 is subjected to a middle folding process by the folding blade 100 and the folding roller pair 89.

  The sheet bundle that has been subjected to the above-described folding process and has been fed to the nip position of the folding roller 7 is subjected to folding processing by the folding roller 7.

  FIG. 3 is a structural diagram for explaining the operation until the sheet conveyed in the conveyance path A is abutted against the stacker claw 21 of the stacker 2 and aligned.

  In the conveyance mechanism that conveys the sheet discharged from the image forming apparatus 1P to the stack tray 1, the driving force from the conveyance motor 40 is transmitted to the gear / pulley 402a via the gear trains 401a and 401b. The driving force transmitted to the gear / pulley 402a is transmitted to each conveying roller by a timing belt 403 wound around the gear / pulley 402a.

  The assist roller 42 is required to have a certain degree of elasticity and frictional force because the sheet is brought into contact with the stacker claw 21 as a reference stopper and aligned. Further, when the assist roller 42 performs the sheet abutting operation on the stacker claw 21 with the sheet completely nipped by the assist roller 42, even if the rotational drive amount of the assist roller 42 exceeds the appropriate amount, It is desirable to be made of a material that can absorb some excessive force applied to the sheet and suppress the occurrence of buckling of the sheet. Therefore, in the present embodiment, for example, a sponge roller is employed as the assist roller 42. Of course, as a material of the assist roller 42, it is needless to say that other materials may be adopted as long as they have the required characteristics.

  The assist roller 42 rotates when the driving force from the transport motor 40 is transmitted by the timing belt 421 further wound around the gear / pulley 402b around which the timing belt 403 is wound. The assist roller 42 is brought into contact with the sheets stacked on the stack tray 1 with a support shaft to which the gear / pulley 402b is connected by an assist roller solenoid 422 provided below the conveyance path as shown in FIG. Move in the direction shown.

  The assist roller 42 rotates in the direction of arrow B, which is the same rotation direction as the discharge roller 43 supported together with the gear / pulley 402b by the support shaft. Accordingly, when the assist roller solenoid 422 is turned on and the assist roller 42 is in contact with the stack tray 1, the sheet conveyed in the direction of arrow C shown in FIG. The sheet can be conveyed so as to assist in sliding down in the D direction, and the sheet end can be brought into contact with the stacker claw 21 serving as a reference stopper for alignment.

  FIG. 4 is a configuration diagram for explaining a lateral alignment portion that aligns sheet side edges in the stack tray 1.

  The lateral alignment unit here has a function of aligning the end portions in the direction orthogonal to the conveyance direction of the sheet bundle stacked on the stack tray 1. The lateral alignment unit includes a lateral alignment motor 30 that is a stepping motor, a drive unit that includes a gear 301, a rack 302a, and a rack 302b, a lateral alignment plate 31a, a lateral alignment plate 31b, and a frame 32 that is a support frame that supports them. It is composed of

  The driving force from the lateral alignment motor 30 is transmitted to the gear 301. Racks 302a and 302b are engaged with the gear 301, and the racks 302a and 302b move in the direction of the arrow shown in FIG. The racks 302a and 302b are respectively mounted on the lateral alignment plates 31a and 32b, and the lateral alignment plates 31a and 31b move in a direction orthogonal to the sheet conveying direction by the movement of the racks 302a and 302b.

  Further, the positions of the lateral alignment plates 31 a and 31 b in the moving direction are managed by the pulses of the lateral alignment motor 30 based on the detection result of the lateral alignment motor HP sensor 33 provided on the frame 32. In addition, HP here means a home position.

  5 and 6 are perspective views for explaining the configuration in the vicinity of the stack tray 1.

  A stacker portion serving as a positioning stopper at the lower end of the sheet bundle stacked on the stack tray 1 includes a stacker motor 20 that is a stepping motor, a drive unit including a gear 201, a gear / pulley 202, and a timing belt 203, and a stacker. It is comprised from the nail | claw 21a, the stacker nail | claw 21b, and the support part 22 which supports these.

  The driving force from the stacker motor 20 is transmitted to the gear / pulley 202 via the gear 201 and is transmitted to the timing belt 203 wound around the gear / pulley 202. As a result, the support portion 22 fixedly connected to the timing belt 203 moves in the direction of the arrow shown in FIG. 6 (the vertical direction in the figure).

  The support portion 22 is provided with stacker claws 21a and 21b, and moves in the direction of the arrow shown in FIGS. 5 and 6 as the support portion 22 moves.

  As described above, the stacker unit in the present embodiment holds the sheet bundle when the folding blade 100 is brought into contact with the sheet bundle in the folding process, and the sheet surface direction when the folding blade 100 is brought into contact with the sheet bundle. It can move approximately in parallel.

  The stacker claws 21a and 21b are provided with flexible members 210a and 210b, respectively, and the sheet bundles abutted against the stacker claws 21a and 21b by these flexible members are pressed against the reference plane and held. is doing.

  Further, the positions of the stacker claws 21 a and 21 b in the moving direction are managed by the pulse of the stacker motor 20 based on the detection result of the stacker motor HP sensor 23.

  Next, the center folding mechanism in the present embodiment will be described.

  7 to 9 are diagrams for explaining details of the sheet folding mechanism in the sheet processing apparatus according to the first embodiment of the present invention.

  As shown in FIG. 7, the sheet folding device 92 includes a folding roller pair 89 that folds a sheet bundle sandwiched between nips into two, and a folding blade 100 that is a pushing member that pushes the sheet bundle into the nip portion of the folding roller pair 89. The folding blade 100 is held so as to be movable toward the folding roller pair 89, and before the sheet bundle is pushed into the nip portion, the guide for regulating the swing in the direction intersecting the moving direction of the folding blade 100. Member (regulating means) 102.

  The pair of folding rollers 89 includes a fixed folding roller (first roller) 89a and a movable folding roller (second roller) 89b.

  The movable folding roller 89b is fixedly disposed so as to be rotatable on a device frame (not shown). In addition, the movable folding roller 89b is rotatably supported by one end 104b of the arm 104 that is supported on an apparatus frame (not shown) so as to be rotatable about a fulcrum 104a, and is substantially orthogonal to the moving direction of the folding blade 100. It is possible to move in the direction and contact / separate with respect to the fixed folding roller 89a.

  A spring 106 is attached to the other end 104c of the arm 104, and the movable folding roller 89b urged by the arm 104 pivoted about the fulcrum 104a presses against the fixed folding roller 89a so that a nip portion is formed. Form. Further, the first end 104b of the arm 104 is provided with a first support hole 104d that allows the movable folding roller 89b to move linearly without drawing an arc when the arm 104 rotates. . The fixed folding roller 89a and the movable folding roller 89b are rotationally driven by a drive motor (not shown).

  The folding blade 100 includes a blade portion 90 that projects the sheet bundle, a first holding member 108 and a second holding member 110 that sandwich and hold the blade 90, and a direction orthogonal to the blade movement direction of the second holding member 110. And side plates 112 attached to both ends.

  A stud 114 is provided at the front portion of the side plate 112, that is, the folding roller pair 89 side, and a shaft 116 is provided at the rear portion (first protrusion 114 and second protrusion 116). The guide member 102 is slidably supported via the stud 114 and the shaft 116. Further, the longer the distance between the stud 114 and the shaft 116, the more stable the folding blade 100 is. Therefore, in this embodiment, the mounting position of the stud 114 is closer to the folding roller pair 89 side than the tip of the blade portion 90. Is set to

  Note that the stud 114 and the shaft 116 as the sliding members are not limited to the above-described configuration, respectively, and both the first and second protrusions 114 and 116 may be studs or shafts, and rotate. A free roller may be used. Further, the attachment position of the stud 114 to the side plate 112 is not limited to the above configuration.

  Further, driving means 118 for sliding the folding blade 100 is provided at both ends of the shaft 116. The driving means 118 includes a cam shaft 120, a groove cam 122 in which a groove portion 122 a is formed and rotatable around the cam shaft 120, and a driven member 124. In the groove 122 a of the groove cam 122, for example, a roller 126 such as a roller follower that is a contactor is rotatably guided, and the roller 126 is attached to the driven member 124.

  A driven member rotating shaft 128 is provided at one end of the driven member 124, and the driven member rotating shaft 128 is attached to an apparatus frame (not shown). The groove cam 122 is rotationally driven by a drive motor (not shown) connected to one end of the cam shaft 120. When the roller 126 is guided along the groove 122a by the rotation of the groove cam 122, the driven member 124 repeats a reciprocating operation like a pendulum around the driven member rotating shaft 128 according to the eccentricity of the groove 122a. .

  Next, the driving mechanism for the folding roller pair 89 and the folding blade 100 will be described in detail.

  The folding mechanism section includes a folding motor 800 that is a DC motor, a timing belt 801, a one-way clutch 802, gears 803a, 803b, 803c, 803d, 803e, 803f, 803g, 901a, 901b, and an electromagnetic clutch 900 (FIG. 8). And see FIG. 9).

  First, the driving force from the folding motor 800 is transmitted to the gear 803a via the timing belt 801 applied between the folding motor 800 and the gear 803a. As the gear 803a rotates, the electromagnetic clutch 900 and the gear 803b are rotationally driven. The gear 803b is provided with a one-way clutch 802. When the folding motor 800 is rotated in the forward direction, rotational driving force is applied from the gear 803b to the folding roller 89a via the gear 803c, gear 803d, and gear 803e. Communicated. On the other hand, when the folding motor 800 is rotated in the reverse direction, the rotational driving force is transmitted from the gear 803b to the folding roller 89a via the gear 803f, the gear 803g, the gear 803d, and the gear 803e.

  In the present embodiment, the driving force from the folding motor 800 is also used to drive the folding blade 100. When the electromagnetic clutch 900 is turned on, the driving force is transmitted to the gear 901a and the gear 901b and connected to the gear 901b. 7 is rotated, the folding blade 100 is driven.

  Further, the rotational speed of the pair of folding rollers 89 and the movement position of the folding blade 100 are managed by the encoder pulse of the folding motor 800 based on the detection results by the encoder actuator 810 and the folding motor encoder sensor 811 connected to the folding motor 800. The

  10 to 16 are diagrams for explaining the operation flow in the sheet processing apparatus according to the first embodiment of the present invention.

  First, an operation flow when stacking and storing sheets on the stack tray 1 will be described.

  When a discharge signal for the first sheet is output from the image forming apparatus, the conveyance motor 40 starts to be driven (S1), and the stacker 2 and the lateral alignment plates 31a and 31b are moved to the standby positions (S2, S3). .

  After that, the sheet is detected by the discharge roller sensor 41, and after the sensor is detected to be off (S4a, Yes), when the sheet is driven by a predetermined pulse reaching the stack tray 1 (S4b, Yes), the assist roller The solenoid 422 is turned on (S5).

  When the assist roller solenoid 422 is turned on, the assist roller 42 conveys the sheet conveyed to the stack tray 1 to the stacker 2.

  After the assist roller solenoid 422 is turned on, when the conveying motor 40 is further driven by a predetermined pulse (S6, Yes), the driving of the lateral alignment motor 30 is started to perform the lateral alignment operation of the sheet (S7). .

  When the conveyance motor 40 is further driven by a predetermined pulse from the start of the driving of the lateral alignment motor 30, the assist roller solenoid 422 is turned off (S8), and when the lateral alignment operation is finished thereafter, the lateral alignment motor 30 is in the reverse direction. The lateral alignment plates 31a and 31b are driven to the standby position by rotating in the opening direction (S9).

  It should be noted that after the discharge roller sensor 41 detects the trailing edge of the sheet in S4 shown in FIG. 10, the conveyance speed when the sheet currently being processed (the sheet whose trailing edge is detected) is the first sheet. To slow down. When this is the first sheet, since there is no sheet on the stack tray 1, the frictional force applied to the sheet is small, and when the sheet is discharged onto the stack tray 1 from the discharge roller 43 which is the final roller of the conveyance path A. This is because the sheet may fly up too much. Therefore, if there is even one sheet on the stack tray 1 as in the second and subsequent sheets, the sheets will rub against each other, so that there will be no problem that the sheets fly too much.

  The predetermined pulse for turning on the assist roller 42 between S5 shown in FIG. 10 and S8 shown in FIG. 11 is the same as the standby position of the stacker 2 is different for each sheet size designated by the image forming apparatus. Different for each size.

  The predetermined pulse in S6 shown in FIG. 11 differs depending on the conveyance speed of the first sheet or the second and subsequent sheets. This is because the horizontal alignment operation by the horizontal alignment plates 31a and 31b requires the horizontal alignment plate to be in contact with the end in the direction orthogonal to the sheet conveyance direction with the assist roller 42 in the standby position. This is because the driving of the operation (S7) is terminated by a predetermined time before the timing (S8) when the assist roller 42 is turned off.

  Next, a description will be given of the flow of operations when performing stapling and folding on the sheet bundle loaded and stored in the stack tray 1.

  When the operations up to S9 in FIG. 11 for loading and storing on the stack tray 1 are completed, when the number of sheets to be folded are stacked (S10, Yes), the horizontal alignment motor 30 is driven again in the alignment direction to perform horizontal operation. A matching operation is performed (S11).

  Thereafter, the lateral alignment motor 30 is driven in the opening direction, and the lateral alignment plate is driven to the guide position when performing the stapling operation (S12).

  Simultaneously with the start of the operation of S12, a stapling process is performed by driving the first staple motor on the far side of the left and right staples (S13).

  After a predetermined time has elapsed from the start of driving the first staple motor in S13 (S14), the second staple motor on the near side is driven to complete the binding process (S15).

  When the staple processing on the sheet by the stapler 5 is completed, the lateral alignment motor 30 is driven in the opening direction to move the lateral alignment plate from the staple guide position to the standby position (S16).

  After a lapse of a predetermined time from the start of the lateral alignment motor driving in S16 (S17), the stacker motor 20 is driven to move the stacker position from the staple position to the folding position, and the bundle conveying operation is performed (S18).

  After the bundle conveying operation is completed, the lateral alignment motor 30 is again driven in the alignment direction to perform the lateral alignment operation (S19), and then is driven in the opening direction to drive to the guide position when performing the folding operation (S20).

  Simultaneously with the start of driving of the lateral alignment motor 30 in S20, the folding motor 800 and the electromagnetic clutch 900 are turned on to start the folding operation (S21). It should be noted that a very high torque is required for the folding operation of the folding motor 800 and the load applied to the electromagnetic clutch 900 is large. Therefore, the electromagnetic clutch 900 is turned on, waits for a predetermined time, and then the folding motor 800 is driven. You may start.

  When the folding process is performed and the sheet is conveyed by the folding roller pair 89 and the folding position detection sensor 71 detects the sheet bundle (S22), the stacker motor 20 and the lateral alignment motor 30 are driven to move to the home position. (S23, S24).

  On the other hand, when the folding roller pair 89 is driven by a predetermined pulse from the sheet bundle detection timing by the folding position detection sensor 71 (see FIG. 2) in S22, the leading edge of the sheet bundle reaches the folded position (S25, Yes). Then, the driving of the folding motor 800 is stopped and the sheet bundle is stopped at the additional folding position (S26).

  When the sheet bundle stops at the folding position, the folding motor is driven to drive the folding roller 7 from the home position to the near side (S27), and then from the near direction to the home position (S28). Then, the folding process is performed.

  If there is a next job continuously, the stacker motor 20 is driven to move the stacker to the next sheet receiving position during the folding operation of S28 (S29).

  When the folding increase process is completed, the folding motor 800 is driven to start the discharging and conveying operation (S30).

  After a predetermined pulse drive from the start of the folding motor drive in S30 (S31), if there is a next job in the same manner as the stacker, the horizontal alignment motor 30 is driven to move the horizontal alignment plate to the next sheet receiving position. (S32).

  When it is detected that the discharge sensor is turned off by performing the discharge conveyance operation (S33, Yes), the folding motor 800 is driven by a predetermined pulse (S34) and then stopped (S35).

  If there is a next job continuously, the processing is continued from S4 shown in FIG. 9, and if there is no next job, the processing is terminated and a stop command from the image forming apparatus is waited.

(Control of stacker standby position during folding process)
In the configuration as described above, when folding a sheet bundle, when the number of sheets constituting the sheet bundle to be folded is large, or when folding is performed on a sheet having a large mass such as cardboard, the stacker is used. Even if the sheet bundle is aligned at the specified position, the sheet bundle may slide down during the folding process due to the influence of gravity or frictional force, and the folding process accuracy may be distorted. .

  17 to 20 are diagrams for explaining in detail the above-described problem in the folding process of the sheet bundle.

  As shown in FIG. 17, for example, when there are a small number of sheet bundles S to be folded, when the stacker claws are aligned with the folding position in S18 shown in FIG. The folding processing after S21 is performed in a state matched to the above, and the accuracy of the folding position can be obtained as shown in FIG. 18 (folded with a crease at the center position of the sheet).

  However, for example, when there are a large number of sheet bundles S ′ to be processed as shown in FIG. 19, the center of the sheet is adjusted to the position of the folding blade 100 in the process of S18 as in the case of FIG. Even when the folding process is performed, the sheet bundle S ′ does not follow when the folding blade 100 is pushed into the pair of folding rollers 89 because the entire sheet bundle S ′ is heavy. That is, during the folding process, the sheet bundle S ′ slips downward due to the influence of gravity g, and the folding roller pair 89 nips above the center position K of the original sheet bundle S ′. Therefore, the sheet bundle cannot be folded at an appropriate folding position (see FIG. 20).

  Therefore, the sheet processing apparatus according to the present embodiment employs the following configuration in order to solve such a problem.

  FIG. 21 is a functional block diagram of the sheet processing apparatus according to the first embodiment of the present invention. A sheet processing apparatus 1F according to the present embodiment includes an information acquisition unit 1101 and a folding position adjustment unit 1102. Note that the folding position adjustment unit 1102 may be hardware independent of the CPU 101, may be a combination of the CPU 101 and software, or may be a combination of a processor and software different from the CPU 101. For example, the folding position adjustment unit 1102 may be realized by the CPU 101 executing a program stored in the MEMORY 103, but is not limited thereto.

  The information acquisition unit 1101 acquires at least one of the information related to the sheet bundle to be folded by the folding blade 100 and the information related to the environment in which the folding process is performed.

  Specifically, the information acquisition unit 1101 includes, for example, the number of sheets constituting the sheet bundle to be folded (for example, obtained from the image forming apparatus 1P), and the material of the sheets constituting the sheet bundle to be folded. (For example, obtained from the discharge roller sensor 41), the thickness of the sheet constituting the sheet bundle to be folded (for example, obtained from the discharge roller sensor 41), and the sheet constituting the sheet bundle to be folded. Type (for example, acquired from the image forming apparatus 1P), direction of sheets constituting the sheet bundle when the folding process is performed (for example, acquired from the image forming apparatus 1P), temperature and humidity (for example, the image forming apparatus 1P or At least one of a temperature sensor and a humidity sensor (not shown) provided in the sheet processing apparatus 1F.

  Note that the various types of information to be acquired by the information acquisition unit 1101 are not necessarily acquired only in the sheet processing apparatus 1F, and are externally connected to be communicable with the image forming apparatus 1P and the image processing apparatus M depending on the situation. It can also be obtained from the device.

  The folding position adjustment unit 1102 controls the stacker motor 20 based on the information acquired by the information acquisition unit 1101 and changes the position of the stacker claw 21, thereby folding the folding blade 100 in the sheet bundle to be folded. Adjust the position to contact.

  Specifically, when the information acquisition unit 1101 acquires information regarding the number of sheets constituting the sheet bundle to be folded, the folding position adjustment unit 1102 includes the number of sheets constituting the sheet bundle to be folded. As the amount of the sheet increases, the position at which the folding blade 100 abuts in the sheet bundle to be folded is lowered (the stacker claw 21 is raised). Note that while the number of sheets constituting the sheet bundle is extremely small, such as one or two, if the influence on the folding position is small, the folding blade 100 is applied up to a predetermined number (for example, five). The adjustment may be performed only when the sheet bundle is composed of six or more sheets without adjusting the contact position.

  In addition, when the information acquisition unit 1101 acquires information on the friction coefficient of the sheets constituting the sheet bundle to be folded, the folding position adjustment unit 1102 is used for the sheets constituting the sheet bundle to be folded. The lower the friction coefficient, the easier it is for the sheet bundle to slide down during the folding process, so the position where the folding blade 100 abuts on the sheet bundle to be folded may be lowered.

  In addition, when the information acquisition unit 1101 acquires information regarding the types of sheets constituting the sheet bundle to be folded, the folding position adjustment unit 1102 is the size of the sheets constituting the sheet bundle to be folded. The larger the is, the greater the weight of the entire sheet bundle, and the easier it is to slide down during the folding process. Therefore, it is preferable to lower the position where the folding blade 100 contacts the sheet bundle to be folded.

  As described above, the folding position adjustment unit 1102 is based on the information acquired by the information acquisition unit 1101 and the higher the bending rigidity of the sheet bundle to be folded, or the sheet bundle to be folded. As the weight of the sheet becomes heavier, the operation of pushing the sheet bundle by the folding blade 100 becomes more difficult, and therefore the position of the folding blade in the sheet bundle to be folded is lowered.

  The acquisition of various types of information by the information acquisition unit 1101 has the greatest influence on the relationship with the pair of folding rollers 89 in the folding process, and is the most folded sheet among the sheets constituting the sheet bundle to be folded by the folding blade 100. It is desirable to carry out with respect to the sheet located on the side close to the roller pair 89 (the side not close to the folding blade).

  The CPU 101 has a role of performing various processes in the sheet processing apparatus 1 </ b> F, and also has a role of realizing various functions by executing programs stored in the MEMORY 103. The MEMORY 103 includes, for example, a ROM, a RAM, and the like, and has a role of storing various information and programs used in the sheet processing apparatus 1F.

Furthermore, according to the first embodiment of the present invention, for example, a sheet processing apparatus having the following configuration can be provided.
(1). In the sheet processing apparatus configured as described above,
The folding position adjusting means is configured to provide the folding blade in the sheet bundle to be folded as the bending rigidity of the sheet bundle to be folded is higher based on the information obtained by the information obtaining means. A sheet processing apparatus that lowers the position where the contact is made.
(2). In the sheet processing apparatus configured as described above,
The folding position adjusting unit is configured to, based on the information acquired by the information acquiring unit, the folding blade in the sheet bundle to be folded as the weight of the sheet bundle to be folded is heavier. A sheet processing apparatus that lowers the position where the contact is made.
(3). In the sheet processing apparatus configured as described above,
The information acquisition means acquires information related to the number of sheets constituting the sheet bundle to be folded.
The sheet processing apparatus, wherein the folding position adjusting unit lowers a position where the folding blade is brought into contact with the sheet bundle to be folded as the number of sheets constituting the sheet bundle to be folded is increased.
(4). In the sheet processing apparatus configured as described above,
The information acquisition means acquires information on a friction coefficient of sheets constituting the sheet bundle to be subjected to the folding process,
The folding position adjusting unit lowers the position of the folding blade in contact with the folding blade as the coefficient of friction of the sheets constituting the folding target sheet bundle decreases. .
(5). In the sheet processing apparatus configured as described above,
The information acquisition means acquires information relating to the types of sheets constituting the sheet bundle to be folded.
The sheet processing apparatus, wherein the folding position adjusting unit lowers a position where the folding blade is brought into contact with the sheet bundle to be folded as the size of the sheet constituting the sheet bundle to be folded is larger.
(6). In the sheet processing apparatus configured as described above,
The information acquisition unit is a sheet processing apparatus that acquires information relating to a sheet that is positioned closest to the folding blade among the sheets that constitute a sheet bundle to be folded by the folding blade.
(7). In the sheet processing apparatus configured as described above,
A stacker that holds the sheet bundle when the folding blade is brought into contact with the sheet bundle in the folding process and is movable substantially parallel to the sheet surface direction when the folding blade is brought into contact;
The folding position adjusting unit is a sheet processing apparatus that adjusts a position where the folding blade is brought into contact with the sheet bundle to be folded by changing the position of the stacker.

  As described above, according to the present embodiment, it is possible to realize a stable and highly accurate folding process regardless of the number, material, and the like of the sheets constituting the sheet bundle to be folded.

(Second Embodiment)
Next, a second embodiment of the present invention will be described.

  The present embodiment is a modification of the above-described first embodiment. Hereinafter, parts having the same functions as those already described in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

(Assistance by assist roller during sheet bundle conveyance)

  2. Description of the Related Art Conventionally, in a sheet processing apparatus that performs predetermined processing such as stapling processing or folding processing on a sheet, after performing stapling processing on a sheet bundle, the sheet is moved to a position where folding processing is performed.

  In the movement of the sheet bundle at this time, a configuration is known in which the sheet bundle positioning stopper used at the stapling process is moved, and the sheet bundle is moved to a predetermined folding processing standby position by following the stopper by its own weight.

  However, in the configuration in which the sheet bundle after the stapling process is retracted from the stapler using the self-weight of the sheet bundle as in the above prior art, the number of sheets constituting the stapled sheet bundle is large. In addition, when the sheet bundle conveyance resistance is large due to the influence of static electricity or the like, the bundle conveyance may not be performed normally.

  Therefore, the sheet processing apparatus according to the second embodiment of the present invention employs the following configuration in order to solve such a problem.

  FIG. 22 is a functional block diagram of the sheet processing apparatus according to the second embodiment of the present invention, and FIG. 23 is a diagram for explaining the operation according to the second embodiment of the present invention. These are timing charts showing drive timing of assist rollers and the like. In FIG. 23, in the stack tray 1, the center position of the sheet bundle when the stapling process is executed is N1, the center position of the sheet bundle when the folding process is executed is N2, and the sheet bundle conveyance distance from the position N1 to the position N2 is l. .

  The sheet processing apparatus 1Fb according to the present embodiment is configured to include a drive control unit 2001 and an information acquisition unit 2002. The drive control unit 2001 may be hardware independent from the CPU 101, a combination of the CPU 101 and software, or a combination of a processor and software different from the CPU 101. For example, the drive control unit 2001 may be realized by the CPU 101 executing a program stored in the MEMORY 103, but is not limited thereto.

  As in the case of the above-described embodiment, the assist roller 42 (alignment roller) can be brought into contact with and separated from the sheet surface of the sheet held by the stacker 2, and the rotating roller surface is brought into contact with the sheet. Thus, the sheet is brought into contact with a reference position in the stacker 2 and aligned.

  The drive control unit 2001 rotationally drives the conveyance motor 40 when moving the sheet bundle S ′ subjected to the stapling process in the direction in which it is retracted from the stapler 5 by the stacker 2 (the direction of moving to the position where the folding process is performed). Then, the assist roller 42 is given a conveying force, and the assist roller solenoid 422 is turned on to bring the assist roller 42 into contact with the sheet bundle S ′ held by the stacker 2 to assist the movement of the sheet bundle S ′.

  The information acquisition unit 2002 is information regarding the number of sheets constituting the sheet bundle to be stapled by the stapler 5 (for example, obtained from the image forming apparatus 1P), and the sheets constituting the sheet bundle to be stapled by the stapler 5 Information on the thickness of the sheet (for example, obtained from the discharge roller sensor 41) and information on the size in the moving direction of the stacker 2 of the sheets constituting the sheet bundle to be stapled by the stapler 5 (for example, obtained from the image forming apparatus 1P) ) Get at least one of the following.

  The drive control unit 2001 moves the assist roller 42 to the stacker 2 when moving the stacker 2 in the retreat direction from the stapler 5 when the number of sheets constituting the sheet bundle to be stapled is equal to or greater than a predetermined number. The sheet bundle held in contact. Generally, when the number of sheets constituting a sheet bundle is large, the thickness of the entire sheet bundle increases, and the frictional force between the wall surface of the stack tray or the like and the sheet bundle tends to increase (the conveyance resistance of the sheet bundle increases). is there. Therefore, when the number of sheets constituting the sheet bundle is large, the conveyance of the sheet bundle in the direction in which it is retracted from the stapler 5 can be stably performed by assisting the conveyance with the assist roller.

  Further, the drive control unit 2001 moves the stapled sheet bundle in the direction in which it is retracted from the stapler 5 by the stacker 2 as the thickness of the sheet constituting the sheet bundle to be stapled increases. Further, it is possible to increase the time for which the assist roller 42 is brought into contact with the sheet bundle held by the stacker 2.

  This is because if the thickness of the sheets constituting the sheet bundle is large, the thickness of the entire sheet bundle also increases, and the frictional force between the wall surface of the stack tray or the like and the sheet bundle increases (the sheet bundle conveyance resistance increases). ), The time for assisting the conveyance of the sheet bundle by the assist roller 42 is lengthened.

  In addition, the drive control unit 2001 retreats the stapled sheet bundle from the stapler 5 by the stacker 2 (that is, the direction in which the sheet bundle is conveyed toward the sheet standby position when the folding process is performed). When the sheet is moved, it is desirable that the assist roller 42 is brought into contact with the sheet bundle held by the stacker 2 at an earlier timing as the size of the sheet constituting the sheet bundle to be stapled is larger. When the size of the sheets constituting the sheet bundle is large, the lower end of the sheet held by the stack tray is positioned lower than the small-sized sheet, so that the timing for bringing the assist roller 42 into contact with the sheet bundle is advanced. It is preferable.

  Further, the drive control unit 2001 holds the assist roller 42 on the stacker 2 until a timing later than the completion of the retracting operation in the retracting direction from the stapler 5 by the stacker 2 of the stapled sheet bundle. Abut. Thereby, the sheet bundle end portion can be reliably aligned at the reference position of the stacker 2 when the retracting operation is completed.

  In addition, the drive control unit 2001 causes the assist roller 42 to contact the sheet bundle held by the stacker 2, and then separates the assist motor 42 from the sheet bundle while rotating the assist roller 42. And the assist roller solenoid 422 is controlled. As a result, the escape of the sheet that has been assisted by the assist roller 42 can be secured, and the occurrence of wrinkles and buckling in the sheet bundle can be prevented.

  Further, the drive control unit 2001 moves the assist roller 42 that abuts against the sheet bundle from the retracting speed of the stacker 2 when the stapled sheet bundle is moved in the direction of retracting from the stapler 5 by the stacker 2. However, it is preferable to rotate at a high peripheral speed. By doing so, when the conveying speed by the assist roller 42 is slower than the retracting speed of the stacker 2 (the speed at which the sheet bundle is moved), the assist roller 42 obstructs the conveyance of the sheet bundle by the stacker 2. The situation can be avoided.

  Note that the assist roller 42 in the present embodiment is configured to retract the sheet bundle held by the stacker at a timing when the stacker 2 of the sheet bundle subjected to the stapling process starts the retracting operation from the stapler 5 in the retracting direction. It is preferable that it is arrange | positioned in the position which can contact | abut to a downstream position rather than the center in. This is because if the assist roller 42 abutted on the upstream side in the retracting direction assists the movement of the sheet bundle, the sheet bundle whose rear end is pushed may be bent.

  As described above, according to the second embodiment of the present invention, even when the number of sheets constituting the sheet bundle is large or when the conveyance of the sheet bundle is difficult due to the influence of static electricity or the like, the staple is stapled. When the processed sheet bundle is moved by the stacker in a direction in which it is retracted from the stapler, the sheet bundle can be normally conveyed.

  Furthermore, according to the second embodiment of the present invention, for example, a sheet processing apparatus having the following configuration can be provided.

(1). In the sheet processing apparatus configured as described above,
A folding processing unit that is located on the movement path of the stacker and that performs a folding process on the sheet bundle conveyed to a predetermined folding position;
The drive control unit causes the alignment roller to contact the sheet bundle held by the stacker when the stapled sheet bundle is moved from the predetermined position to the predetermined folding position by the stacker. A sheet processing apparatus for assisting movement of the sheet bundle.
(2). In the sheet processing apparatus configured as described above,
A folding processing means for performing folding processing on the sheet bundle positioned on the movement path of the stacker and conveyed to a predetermined folding position;
The drive control unit causes the alignment roller to contact the sheet bundle held by the stacker when the stapled sheet bundle is moved from the predetermined position to the predetermined folding position by the stacker. A sheet processing apparatus for assisting movement of the sheet bundle.
(3). In the sheet processing method configured as described above,
The sheet processing apparatus further includes a folding processing unit for performing a folding process on the sheet bundle positioned on the movement path of the stacker and conveyed to a predetermined folding position.
When the stapled sheet bundle is moved from the predetermined position to the predetermined folding position by the stacker, the alignment roller is brought into contact with the sheet bundle held by the stacker to move the sheet bundle. Sheet processing method to assist.

  As described above, according to the present embodiment, the operation of retracting the sheet bundle after the stapling process from the stapler can be stably performed regardless of the number of sheets constituting the sheet bundle, the conveyance resistance, and the like. Technology can be provided.

(Third embodiment)
Subsequently, a third embodiment of the present invention will be described.

  The present embodiment is a modification of the above-described embodiments. In the following, parts having the same functions as those already described in the above embodiment are given the same reference numerals, and the description thereof is omitted.

(An elastic sheet prevents paper jam in the vicinity of the staple unit)

  In general, it is preferable that the stapler 5 that performs the stapling process on the sheet bundle and the pair of folding rollers 89 are close to each other from the viewpoint of reducing the size of the apparatus.

  In such a configuration in which the two are close to each other, it is difficult to provide a conveyance guide or a shutter that constitutes the wall surface of the sheet conveyance path between the stapler 5 and the folding roller pair 89, and between the conveyance surface and the stapler. Jam is very likely to occur during sheet conveyance.

  Therefore, the sheet processing apparatus according to the third embodiment of the present invention employs the following configuration in order to solve such a problem.

  25 and 26 are diagrams showing details of the configuration in the vicinity of the folding roller pair 89 in the third embodiment of the present invention.

  The stapler 5 in the sheet processing apparatus according to this embodiment includes a clincher (pressing portion) 5b and a driver (receiving portion) 5a.

  The clincher 5b has a function of pressing the sheet surface of the sheet bundle toward the sheet stacking reference surface of the driver 5a when the stapling process is performed, and bending the tip of a needle driven into the sheet bundle by the driver 5a.

  The driver 5a is disposed so as to face the inside of the sheet conveying path from an opening provided in the inner wall of the sheet conveying path, and has a role of elastically receiving the sheet bundle pressed by the clincher 5b and supplying staples. is doing.

  In this way, the staple process is performed on the sheet bundle by the cooperation of the clincher 5b and the driver 5a.

  In the sheet processing apparatus according to the present embodiment, a flexible elastic sheet (corresponding to an elastic member) is used to guide the leading end of the sheet conveyed toward the stapler 5 to the sheet stacking reference surface of the driver 5a. 51 is provided. The elastic sheet 51 is formed from, for example, a resinous film-like member.

  The elastic sheet 51 is supported at one end by a holding member 52 made of a highly rigid material (for example, metal or resin) fixed to the driver 5a, and is provided on the side where the driver 5a of the sheet conveyance path is provided. Inclined toward the inner wall or the pair of folding rollers 89, it extends upstream in the sheet conveying direction (at least to a position covering the vicinity of the downstream end of the roller surface of the folding roller in the sheet conveying direction).

  By arranging the elastic sheet 51 in this way, the elastic sheet in the case where the sheet bundle subjected to the staple processing by the stapler 5 is lowered to the folding position by the folding roller pair 89 (folding processing unit) by the stacker 2. It is possible to prevent the sheet bundle or staple from being caught on the sheet 51. Further, by covering the gap between the stapler 5 and the pair of folding rollers 89 with the elastic sheet 51, it is possible to avoid a jam from occurring due to the sheet entering the gap.

  Further, in the sheet processing apparatus according to the present embodiment, when sheets conveyed in the conveyance path A are stacked on the stack tray 1, folding is performed in order to prevent the leading end of the sheet from interfering with the folding roller pair 89. A shutter 88 that can cover the roller pair 89 is provided. The elastic sheet 51 fixed to the driver 5a scoops the leading edge of the sheet that has passed through the upper surface of the shutter 88, and guides the leading edge of the sheet to the sheet stacking reference surface of the driver 5a.

  The driver 5a in the present embodiment can move 10 mm in the direction of retreating from the sheet conveyance path during stapling, and the elastic sheet 51 indicates the stacking state of the sheet bundle positioned on the sheet stacking reference surface of the driver 5a. The driver 5a follows the movement of the driver 5a without being disturbed, and deforms along the outer shape of the folding roller 89b.

  As described above, according to the third embodiment of the present invention, the folding roller pair 89 for folding processing and the stapler 5 for stapling processing are arranged close to each other while avoiding occurrence of sheet jamming. Can contribute to the improvement of productivity.

  In addition, by adopting an elastic sheet as a member for guiding the sheet up to the sheet stacking reference surface of the driver 5a, it is possible to respond flexibly regardless of whether the sheet to be stapled is thick or thin. Thus, it is possible to realize a stapling process that does not adversely affect the deformation of the sheet during the stapling process.

(Fourth embodiment)
Subsequently, a fourth embodiment of the present invention will be described.

  The present embodiment is a modification of the above-described embodiments. In the following, parts having the same functions as those already described in the above embodiment are given the same reference numerals, and the description thereof is omitted.

(Control of sheet bundle conveyance speed by folding roller pair during folding process)

  In the sheet processing apparatus that performs the folding process with the folding roller pair 89 and the folding blade 100 on the sheet bundle, the folding process by the folding roller pair 89 is completed after the sheet bundle to be folded is pushed into the folding roller pair 89. In the meantime, a large rotational load is applied to the folding roller pair 89. Therefore, in order to exert a strong torque in the pair of folding rollers 89, the rotational speed of the motor is reduced by the gear train, and the pair of folding rollers 89 is only in the state of the reduced rotational speed (the state of low torque and high torque). In general, it was driven to rotate.

  However, the sheet bundle folding process requires a very large torque only after the sheet bundle to be folded is pushed into the folding roller pair 89 until the folding process by the folding roller pair 89 is completed. In addition, the rotational driving of the folding roller pair 89 during other periods does not necessarily require high torque as in the case of conveying the sheet bundle after the folding process to the downstream side.

  Therefore, driving the pair of folding rollers 89 at a low-speed rotation for exerting a high torque is problematic from the viewpoint of throughput until simple sheet bundle conveyance where high torque is not required.

  Hereinafter, the drive control of the folding roller pair 89 in the sheet processing apparatus according to the present embodiment will be described in detail.

  FIG. 27 is a functional block diagram of a sheet processing apparatus according to the fourth embodiment of the present invention, and FIGS. 28 and 29 are drives for rotationally driving the folding roller pair 89 according to the fourth embodiment of the present invention. FIG. 30 is a structural diagram for explaining the mechanism, and FIG. 30 is a timing chart for explaining drive control in the rotational drive of the folding roller pair 89 in the fourth embodiment of the present invention.

  First, functional blocks of the sheet processing apparatus according to the present embodiment will be described.

  The sheet processing apparatus 1Fc according to the present embodiment includes an information acquisition unit 4001 and a conveyance control unit 4002. Note that the transfer control unit 4002 may be hardware independent of the CPU 101, a combination of the CPU 101 and software, or a combination of a processor and software different from the CPU 101. For example, the conveyance control unit 4002 may be realized by the CPU 101 executing a program stored in the MEMORY 103, but is not limited thereto.

  The information acquisition unit 4001 acquires information (for example, acquired from the image forming apparatus 1P) regarding the number of sheets constituting the sheet bundle to be folded by the folding blade 100, and the sheet bundle to be folded by the folding blade 100. Information about the thickness of the sheet to be configured (for example, acquired from the discharge roller sensor 41) is acquired.

  The conveyance control unit 4002 starts the returning operation to the standby position after the folding blade 100 finishes pushing the sheet bundle, and then the trailing end of the sheet bundle pushed into the nip portion of the folding roller pair 89 by the folding blade 100. By the folding roller pair 89 at a predetermined timing until it passes through the nip of the folding roller pair 89 (preferably, after the return operation is started and until the folding blade 100 stops at a predetermined standby position). The folding motor 800 is controlled so that the sheet conveyance speed is switched from the first conveyance speed to the second conveyance speed.

  The drive control of the folding motor 800 by the conveyance control unit 4002 is performed based on information such as a data table, a timing chart, and a function held by the conveyance control unit 4002 or the MEMORY 103, for example.

  Next, details of drive control of the folding roller pair 89 in the sheet processing apparatus according to the present embodiment will be described.

  A one-way clutch 802 is connected to a gear 803 b that transmits drive from the folding motor 800 to the pair of folding rollers 89.

  For example, the folding motor 800 is rotated in the direction of arrow E shown in FIG. Then, the gear 803b rotates in the arrow H direction via the timing belt 801, the gear 803a, and the electromagnetic clutch 900. If the gear 803b rotates in the arrow H direction, the drive is transmitted to the gear 803c, and the driving side folding roller 89a is rotationally driven in the arrow J direction via the gear 803d and the gear 803e.

  Thus, by rotating the folding motor 800 in the direction of arrow E, the driving force is transmitted through the gear train using the gear 803c having a large reduction ratio, whereby the folding roller 89 is rotated at a low speed (first speed). It can be rotated at a high torque.

  On the other hand, when the folding motor 800 is rotated in the direction of arrow F shown in FIG. 29, the timing belt 801, the gear 803a, and the electromagnetic clutch 900 are driven in a direction opposite to the rotational direction shown in FIG. And the gear 803b rotates in the direction of arrow I through the electromagnetic clutch 900. If the gear 803b rotates in the direction of arrow I, the drive is transmitted to the gears 803f and 803g, and the drive side folding roller 89a is rotationally driven in the direction of arrow J through the gears 803d and 803e.

  Thus, by rotating the folding motor 800 in the direction of arrow F, the folding roller 89 is rotated at a high speed by transmitting the driving force through the gear train using the gears 803f and 803g having a small reduction ratio. (Second transport speed).

  28 and 29, the drive side folding roller 89a is always moved to the arrow J not only when the folding motor 800 is rotated in the E direction but also when the folding motor 800 is rotated in the F direction. Therefore, the sheet bundle conveying direction by the folding roller pair 89 can be the same direction.

  With such a mechanism, during folding processing, the folding motor 800 is rotated in the direction of arrow E, which is the direction of rotation with a high reduction ratio, so that it is driven at a low speed and with high torque, and from the standby position toward the nip of the roller pair. By the folding blade 100 that moves, the sheet bundle to be folded is pushed into the nip of the roller pair driven at the first conveyance speed. Then, after the folding process of the sheet bundle is completed, the folding motor 800 is stopped once, and the sheet motor can be conveyed at high speed by rotating the folding motor 800 in the arrow F direction which is the reverse direction when conveying the sheet bundle.

  Specifically, the conveyance control unit 4002 folds the tip of the folding blade 100 that has started moving to the standby position after the folding blade 100 has finished pushing the sheet bundle and started returning to the standby position. The folding roller pair at a predetermined timing until it passes through the downstream end position of the folding roller pair 89 in the moving direction during the returning operation of the blade 100 (the tangential plane that contacts the roller surface of the folding roller pair 89). The sheet conveying speed by 89 is switched from the first conveying speed V1 to the second conveying speed V2. Thus, as soon as the folding process is completed, switching from the first conveyance speed to the second conveyance speed as soon as possible can contribute to an improvement in throughput of the entire apparatus.

  Further, the conveyance control unit 4002 increases the sheet conveyance speed by the pair of folding rollers 89 as the number of sheets constituting the sheet bundle to be folded becomes larger and as the sheet constituting the sheet bundle to be folded becomes thicker. It is desirable to delay the timing for switching from the first transport speed to the second transport speed.

  As described above, when a sheet bundle that requires a high torque to perform the folding process is a target, the folding process is performed by maintaining a long time for conveying the sheet bundle at the first conveyance speed (low speed and high torque). Can be performed reliably.

  In addition, when the number of sheets constituting the sheet bundle to be folded is smaller than a predetermined number, the conveyance control unit 4002 finishes the pushing operation of the sheet bundle and starts the return operation to the standby position. Until the rear end of the sheet bundle pushed into the nip portion of the folding roller pair 89 by the folding blade 100 passes through the nip of the folding roller pair 89, the folding roller pair 89 is moved at the second conveyance speed. It is preferable to drive by.

  In general, when the number of sheets constituting the sheet bundle to be folded is smaller than a predetermined number, a large torque is not required for rotational driving of the pair of folding rollers 89, and the sheet bundle is sandwiched between the pair of folding rollers 89. By conveying at a high speed and a low torque from the indenting stage, it is possible to contribute to an improvement in throughput.

  Next, acceleration control in driving the folding roller pair 89 by the conveyance control unit 4002 will be described.

  In general, when the sheet bundle is nipped and conveyed by the pair of folding rollers 89, if the conveyance speed is changed rapidly, the sheet bundle to be folded may be wrinkled or the sheet itself may be damaged. .

  Therefore, the conveyance control unit 4002 according to the present embodiment performs the PWM control with the motor step signal of the folding motor 800 as the number of sheets constituting the sheet bundle to be folded becomes larger. The acceleration A2 at the time of switching from the first conveying speed to the second conveying speed of the sheet conveying speed is reduced. This is because, when the number of sheets constituting the sheet bundle to be folded is large, wrinkles are likely to come close to the sheet bundle when the folding roller pair 89 is accelerated rapidly.

  On the other hand, the conveyance control unit 4002 performs the PWM control with the motor step signal of the folding motor 800 as the sheet constituting the sheet bundle to be folded becomes thicker, so that the sheet conveyance speed of the folding roller pair 89 is increased. The acceleration at the time of switching from the first transport speed to the second transport speed is increased. This is because if the sheets constituting the sheet bundle to be folded are thin, rapid acceleration of the pair of folding rollers 89 may cause the sheet bundle to break. This is to endure.

  Furthermore, according to the fourth embodiment of the present invention, for example, a sheet processing apparatus having the following configuration can be provided.

(1). In the sheet processing apparatus configured as described above,
Comprising information acquisition means for acquiring information relating to the thickness of the sheets constituting the sheet bundle to be folded by the folding blade;
The conveyance control means increases the acceleration when the sheet conveyance speed is switched from the first conveyance speed to the second conveyance speed by the roller pair as the sheets constituting the sheet bundle to be folded are thicker. Sheet processing device to increase the size.

  As described above, according to the present embodiment, after the folding process is performed on the sheet bundle, the throughput when the folded sheet bundle is conveyed downstream can be significantly improved. Occurrence of wrinkling of the sheet bundle at the time can be prevented.

(Fifth embodiment)
Subsequently, a fifth embodiment of the present invention will be described.

  The present embodiment is a modification of the above-described embodiments. In the following, parts having the same functions as those already described in the above embodiment are given the same reference numerals, and the description thereof is omitted.

(Correction based on the detection result of the position where the stack of sheets is kept waiting by the stacker)

  In general, when a stapling process or a folding process is performed on a sheet bundle, the size in the conveyance direction of the sheets constituting the sheet bundle to be processed is a prescribed value of the sheet size (for example, A3, A4, B4, B5, etc.). When it is calculated and it is determined that the sheet size is deviated from the specified value, an error notification is performed.

  In a conventional sheet processing apparatus, when a user supplies a sheet having an unspecified size as a target for stapling or folding, there are cases where these processes cannot be executed.

  Hereinafter, drive control of the stacker 2 in the stapling process and the folding process in the sheet processing apparatus according to the present embodiment will be described in detail.

  FIG. 31 is a functional block diagram of a sheet processing apparatus according to the fifth embodiment of the present invention.

  The sheet processing apparatus 1Fd according to the present embodiment includes a size calculation unit 5001 and a processing position adjustment unit 5002. The processing position adjustment unit 5002 may be hardware independent of the CPU 101, a combination of the CPU 101 and software, or a combination of a processor and software different from the CPU 101. For example, the processing position adjustment unit 5002 may be realized by the CPU 101 executing a program stored in the MEMORY 103, but is not limited thereto.

  The size calculation unit 5001 calculates the size of the sheet passing through the discharge roller sensor 41 in the conveyance direction based on the detection result of the discharge roller sensor 41. Specifically, the size calculation unit 5001 calculates the sheet length based on the number of driving steps of the conveyance motor 40 between the detection of the leading edge of the sheet and the detection of the trailing edge of the sheet by the discharge roller sensor 41.

  The processing position adjustment unit 5002 adjusts the position at which the stapling process or the folding process is performed on the sheet bundle that is the target of the stapling process or the folding process, based on the sheet size calculated by the size calculation unit 5001.

  Hereinafter, adjustment of the processing position of the sheet bundle in the present embodiment will be described in detail.

  The distance from the staple position in the original stapler 5 to the standby position of the stacker claw 21 is L0, the theoretical value of the length of the designated sheet size in the conveyance direction is L1, and the distance from the staple position to the folding position is L2.

  When the sheet length (actually measured value) calculated by the size calculating unit 5001 is L4, for example, when the actually measured value L4 is “L4> L1”, the processing position adjusting unit 5002 displays “(L1− The stacker motor 20 is driven by the distance L4) / 2 "to lower the stacker claw 21.

  After stacking up to the last sheet on the stack tray 1 at the above position and performing stapling on the stacked sheet bundle, the stacker claw 21 is driven by “L2” to perform folding processing. Discharge.

  On the other hand, for example, when the sheet length calculated by the size calculation unit 5001 is L4, and the actual measurement value L4 is “L4 <L1”, the processing position adjustment unit 5002 displays “(L1-L4). ) / 2 ″ to drive the stacker motor 20 and raise the stacker claw 21 by the distance of 2 ″.

  By adopting such a configuration, even when the designated sheet size is different from the actual measured value of the sheet actually supplied from the image forming apparatus 1P, the processing position is adjusted, thereby achieving high accuracy. Staple processing and folding processing can be performed.

  In this way, the stacker claw 21 is kept at a position corresponding to the sheet size for the time being, and it is only necessary to correct the error, so that the error can be corrected in a short time, and also in terms of throughput. preferable.

  Here, the configuration in which the size of the sheet to be subjected to the stapling process and the folding process is calculated based on the detection result in the discharge roller sensor 41 is not limited to this. A sheet edge detection sensor (not shown) that detects the edge of the sheet to be moved may be provided, and the sheet length may be calculated based on the detection result of the sensor.

  For example, the processing position of the sheet bundle is corrected according to the following processing flow.

  First, the processing position adjustment unit 5002 drives the stacker motor 20 to move the stacker claw 21 to the sheet waiting position, and waits for the number of sheets to be processed to be aligned.

  Subsequently, the processing position adjustment unit 5002 raises the stacker claw 21 until the sheet end detection sensor is turned on.

here,
L0 = distance from the stapling position to the stacker claw 21 waiting for the sheet L1 = theoretical value of the sheet length (standard value)
L2 = distance from the sheet edge detection sensor to the stacker claw 21 waiting for the sheet L3 = when the distance from the position where the stapling process is performed to the position where the folding process is performed
The actual measured length of the sheet can be obtained from the timing when the sheet end detection sensor is turned on.

L0 = L1 / 2 + (maximum sheet length-theoretical sheet length)
L2 = L1 + (maximum sheet length-theoretical sheet length)
In the case of
Sheet length = L2−sheet end detection moving step number × 1 step moving distance.

  The size calculation unit 5001 calculates the actually measured length of the sheet to be processed based on the above calculation formula.

  The processing position adjustment unit 5002 moves the central position in the sheet conveyance direction to the staple position based on the following calculation formula.

Staple position moving step number = (number of sheet edge detection moving steps− (maximum sheet length−sheet length theoretical value) / 1 step moving distance) / 2
(If the calculation result here is positive, it will increase, and if it is negative, it will decrease.)

  As described above, according to the present embodiment, when performing sheet folding processing and stapling processing, even if the dimensional accuracy (length) of the sheet to be used is not sufficient, high-precision stapling is performed on the sheet. Processing and folding processing can be performed.

(Sixth embodiment)
Subsequently, a sixth embodiment of the present invention will be described.

  The present embodiment is a modification of the above-described embodiments. In the following, parts having the same functions as those already described in the above embodiment are given the same reference numerals, and the description thereof is omitted.

(Sheet processing device that enables the saddle unit to be pulled out as a unit)

  In a conventional sheet processing apparatus that performs stapling processing and folding processing, a stapler that performs stapling processing on a sheet, a pair of folding rollers and a folding blade that performs folding processing on the sheet, and a sheet for conveying the sheet to the pair of staplers and folding rollers. A configuration including a switchback transport unit is known.

  In such a conventional sheet processing apparatus, a sheet conveyance path for holding a sheet when a predetermined process is performed by a pair of a stapler and a folding roller or the like for sheet removal and maintenance when a paper jam (sheet jam) occurs. There are known a configuration in which only a portion of the conveyance guide to be configured can be pulled out of the sheet processing apparatus, and a configuration in which only the vicinity of the pair of folding rollers can be pulled out of the sheet processing apparatus. In a conventional sheet processing apparatus having such a configuration, for example, a conveyance guide that constitutes a conveyance path that performs switchback conveyance removes a jammed sheet by developing it while remaining in the sheet processing apparatus. It was common to do.

  However, even if the conveyance guide is opened in the sheet processing apparatus, it cannot be said that it is sufficient as a space for removing the sheet, and it is often difficult to remove the sheet.

  Therefore, the sheet processing apparatus according to the sixth embodiment of the present invention employs the following configuration in order to solve the above problem.

  FIGS. 32 to 37 are views for explaining the drawer structure of each unit in the sheet processing apparatus 1Fe according to the sixth embodiment of the present invention.

  A saddle unit 3000 that performs stapling and folding in the sheet processing apparatus 1Fe has rail portions 3001a and 3001b fixedly connected to the saddle unit 3000 shown in FIG. The rail portions 3001a and 3001b are supported on the main body frame of the post-processing device by a guide portion 3400 so as to be slidable in the front direction perpendicular to the paper surface in FIG. As shown in FIG. 34, the entire range is drawn to the front side of the sheet processing apparatus 1Fe. Here, the rail unit 3001a, the rail unit 3001b, the guide unit 3400, and the frame (for example, see FIG. 33) that integrally supports the stapler 5, the folding roller pair 89, and the like correspond to the slide unit.

  Here, the first sheet conveying path is for conveying a sheet to be processed or stapled toward the processing position, and the second sheet conveying path is the first sheet conveying path. The sheet conveyed inside is switched back and conveyed in order to perform stapling and folding processing. Note that the second sheet conveyance path here has an opening, a protrusion, and a recess (a shape portion where the sheet is easily caught) in the vicinity of the joining position (see FIG. 32) with the first sheet conveyance path in the conveyance path. ) At least one of the above. In general, among the conveyance guides constituting the second sheet conveyance path, the sheet jam is particularly caused when the conveyance guide on the downstream side in the sheet traveling direction in the first sheet conveyance path has a shape portion that easily catches the sheet. It is easy to generate.

  Here, the amount of the saddle unit 3000 to be pulled out of the sheet processing apparatus 1Fe is set to an amount that allows at least the entire mechanical unit of the saddle unit 3000 to be pulled out of the sheet processing apparatus 1Fe. For example, when the size of the image forming apparatus 1P in the depth direction is large and there is a difference by a distance Y between the front surface of the sheet processing apparatus 1Fe and the front surface of the image forming apparatus 1P (see FIG. 34), A structure in which the saddle unit can be pulled out of the sheet processing apparatus 1Fe by an amount including the distance Y is adopted. As described above, the slide unit according to the present embodiment includes the first conveyance guide and the second conveyance guide to a position where development of a first conveyance guide and a second conveyance guide, which will be described later, is not hindered by the image forming apparatus 1P. Can be pulled out.

  In the saddle unit 3000 in a state of being pulled out of the sheet processing apparatus 1Fe, the first guide 3110 constituting the outer wall surface in the radius direction of curvature of the first sheet conveyance path is provided with a pull-out knob 3111, with the lower end as a fulcrum. It has a rotatable structure. The first guide 3110 can be unfolded as shown in FIG. 35 by pulling the drawer knob 3111 forward. The main body frame of the saddle unit 3000 is provided with conveyance guide support members 3200a and 3200b, and normally supports the first conveyance guide 3110 in a closed state as shown in FIG.

  Further, the second conveyance guide 3120 that constitutes the inner wall surface in the radius direction of curvature of the first sheet conveyance path is also rotatable about the lower end as a fulcrum, like the first conveyance guide 3110. As shown in FIG. 36, the structure can be developed.

  The first conveyance guide 3110 and the second conveyance guide 3120 are connected by a connecting member 3300, and the first state shown in FIG. 35 in which the first conveyance guide 3110 is developed by a predetermined angle; After the first conveyance guide 3110 is further expanded from the first state, the first conveyance guide 3110 as shown in FIGS. 36 and 37 has a second state in which the first conveyance guide 3110 is further expanded.

  In the sheet processing apparatus according to the present embodiment, the second conveyance guide 3120 is interlocked with the development of the first conveyance guide 3110 from the first state to the second state by the action of the connecting member 3300. It has a structure that expands.

  As described above, by adopting a structure in which the first conveyance guide 3110 and the second conveyance guide 3120 can be developed in stages, the sheet removal in the sheet conveyance path becomes easy, as well as FIG. As shown in FIG. 4, the sheet can be easily removed from the switchback portion and the vicinity of the pair of folding rollers 89 located closer to the inside of the apparatus than the first sheet conveying path.

  In this embodiment, a material with high transparency is used for the first conveyance guide 3110, a material with low transparency is used for the second conveyance guide 3120, and the color is close to black. By doing so, it is possible to improve the visibility of the sheet remaining in the sheet conveyance path in a state where the conveyance guide is unfolded with the saddle unit 3000 pulled out of the apparatus. Note that the form of the first conveyance guide 3110 is not necessarily limited to the above configuration. For example, an opening may be formed in the first conveyance guide 3110 so that a jammed sheet can be confirmed through the opening. In this case, the opening formed in the first conveyance guide 3110 is preferably a long hole extending in the sheet conveyance direction, for example. As a result, a wide range in the sheet conveyance direction can be visually recognized from the outside of the first conveyance guide 3110 between the first conveyance guide 3110 and the second conveyance guide 3120, which can contribute to improvement in maintainability. . Of course, it goes without saying that a material having high transparency is used for the first conveyance guide 3110 and that the opening is formed, thereby contributing to further improvement in maintainability.

  Here, the first sheet conveying path, the second sheet conveying path, the stapler 5, the folding roller pair 89, and the folding blade 100 can be integrally pulled out of the sheet processing apparatus 1Fe by the slide portion. However, the present invention is not necessarily limited to this.

  When the folding blade 100 for folding processing and the folding roller pair 89 are arranged near the switchback position (merging position) for downsizing, jamming near the folding roller pair 89 is likely to occur.

  Therefore, in such a case, the slide unit is configured such that at least the first sheet conveyance path, the second sheet conveyance path, and the folding roller pair 89 can be integrally pulled out of the sheet processing apparatus 1Fe. Thus, it is possible to easily deal with a jam that occurs near the folding roller pair 89.

  On the other hand, when the stapler 5 is disposed in the vicinity of the switchback position (merging position) for miniaturization, jamming in the vicinity of the stapler 5 is likely to occur.

  Therefore, in such a case, the slide unit is configured so that at least the first sheet conveyance path, the second sheet conveyance path, and the stapler 5 can be integrally pulled out of the sheet processing apparatus 1Fe, so that the stapler can be pulled out. It is possible to easily deal with a jam occurring in the vicinity of 5.

  Further, the sheet processing apparatus 1Fe according to the present embodiment extends at least in the sliding direction of the slide part, and at least a part of the unit that can be pulled out of the sheet processing apparatus 1Fe by the slide part is orthogonal to the sliding direction of the slide part. The plate-shaped member 3500 which covers the outer side is provided.

  Thus, by covering the outside of the saddle unit in the direction orthogonal to the slide direction with the plate-like member 3500 extending in the slide direction, the member, clothes, etc. are caught when the saddle unit is stored in the sheet processing apparatus 1Fe. Can be prevented. Here, the plate-like member 3500 is the ceiling portion of the saddle unit, but is not limited to this, and may be disposed, for example, on the side wall portion of the saddle unit or on the bottom surface portion. Also good.

Furthermore, according to the sixth embodiment of the present invention, for example, a sheet processing apparatus having the following configuration can be provided.
(1). In the sheet processing apparatus configured as described above,
The sheet processing apparatus in which the second guide is developed in conjunction with the developing operation of the first guide.
(2). In the sheet processing apparatus configured as described above,
The sheet processing apparatus, wherein the first guide is formed with at least one opening that allows the inside of the first sheet conveyance path to be visually recognized from the outside when the first guide is not unfolded.
(3). In the sheet processing apparatus configured as described above,
A plate-like member extending at least in the sliding direction of the sliding means, and covering at least a part of a unit that can be pulled out of the sheet processing apparatus by the sliding means in a direction perpendicular to the sliding direction of the sliding means. A sheet processing apparatus including a plate member.
(4). In the sheet processing apparatus configured as described above,
The sheet processing apparatus in which the second guide is developed in conjunction with the developing operation of the first guide.
(5). In the sheet processing apparatus configured as described above,
The sheet processing apparatus, wherein the first guide is formed with at least one opening that allows the inside of the first sheet conveyance path to be visually recognized from the outside when the first guide is not unfolded.
(6). In the sheet processing method configured as described above,
The sheet processing method in which the second guide is developed in conjunction with the developing operation of the first guide.
(7). In the sheet processing method configured as described above,
The sheet processing method, wherein the first guide is formed with at least one opening that allows the inside of the first sheet conveyance path to be visually recognized from the outside in a state where the first guide is not expanded.

  As described above, according to the present embodiment, it is possible to contribute to improvement in maintainability when a sheet jam or the like occurs in the vicinity of the switchback position.

(Seventh embodiment)
Subsequently, a seventh embodiment of the present invention will be described.

  The present embodiment is a modification of the above-described embodiments. In the following, parts having the same functions as those already described in the above embodiment are given the same reference numerals, and the description thereof is omitted.

(Control of movement timing of stacker and lateral alignment plate to standby position)

  Conventionally, when performing stapling and folding, the horizontal alignment plate that aligns the end in the direction orthogonal to the sheet conveyance direction and the stacker claw that abuts and positions the end in the sheet conveyance direction are selected. Until all the processes were completed, the position was managed based on the number of pulses of the stepping motor, and it did not return to the home position.

  Therefore, the position of the lateral alignment plate or the stopper is likely to be shifted due to the influence of individual differences of parts, individual differences during assembly of the apparatus, and the like. Therefore, for example, when processing is performed on a large number of sheets or when a plurality of different processes are successively performed on sheets, the above-described misregistration accumulates, resulting in a large misalignment. May occur.

  In view of the above problems, there is also known a control method in which a sheet bundle to be stapled or folded is returned to the home position once by the movement of the stacker, and the position accuracy is obtained. Therefore, if the timing for returning to the home position is wrong, there is a problem that the accuracy of the folding position may be distorted. In addition, if driving of the lateral alignment plate and the stacker claw is started after the folding process is finished, there is a problem that a wasteful waiting time is generated and the processing time is increased.

  Therefore, the sheet processing apparatus according to the present embodiment employs the following configuration. FIG. 38 is a view for explaining a sheet processing apparatus according to the seventh embodiment of the present invention.

  In the sheet processing apparatus according to the present embodiment, the lateral alignment plates 31a and 31b for aligning the end portions in the direction orthogonal to the sheet conveyance direction of the sheet bundle, and the end portions in the sheet conveyance direction of the sheet bundle are abutted, and the sheet size is classified The stacker claw 21 for matching the staple position and the folding position is positioned in the sheet conveying direction and guided in the width direction until the folding roller pair 89 nips the sheet bundle in the folding process by the folding roller pair 89. (See, eg, FIGS. 4 and 5).

  In order to perform a folding process on the sheet bundle that has been subjected to the folding process by the folding roller pair 89, the sheet is fed by a folding position detection sensor 71 for detecting the position of the sheet bundle discharged from the folding roller pair 89. After the detection, the lateral alignment plates 31a and 31b and the stacker claw 21 are moved to the home position.

  When determining whether or not the sheet bundle is nipped by the folding roller pair 89 based on the drive pulse when driving the folding blade 100, the moving distance until the sheet bundle is actually nipped by the folding roller pair 89 Because it depends on, the variation is large.

  On the other hand, if the detection result of the folding position detecting sensor 71 arranged on the downstream side in the conveyance direction of the folding roller pair 89 is used, it is reliably determined whether the sheet bundle is nipped by the folding roller pair 89. be able to.

  As described above, after the sheet is detected by the folding position detecting sensor 71, the lateral alignment plates 31a and 31b and the stacker claw 21 are moved to the home position, so that the sheet bundle is aligned with the lateral alignment plates 31a and 31b. The stacker claws 21 can be aligned at an appropriate position, which can contribute to improvement in accuracy of the folding position and the stapling position.

(Eighth embodiment)
Subsequently, an eighth embodiment of the present invention will be described.

  The present embodiment is a modification of the above-described embodiments. In the following, parts having the same functions as those already described in the above embodiment are given the same reference numerals, and the description thereof is omitted.

(Control of movement timing of stacker and lateral alignment plate to next sheet receiving position)

  In a conventional sheet processing apparatus that performs stapling or folding, a lateral alignment plate that aligns ends in a direction orthogonal to the sheet conveying direction and an end in the sheet conveying direction when performing stapling or folding. The stacker claws that are positioned by abutting are moved to the receiving position of the sheet to be processed next after the stapling or folding process is completed.

  However, starting the lateral alignment plate and stacker claw to start the alignment of the next sheet after the folding process into the sheet bundle is actually completed causes a wasteful waiting time, and in terms of throughput. There's a problem.

  On the other hand, if the movement of the lateral alignment plate or the stacker claw is started before the folding process into the sheet bundle is completed, for example, after the folding process is performed on the large sheet bundle, When the folding process is performed, the lateral alignment plate or stacker claw that has started to move early interferes with the sheet bundle being folded, causing a problem with the sheet bundle being folded. is there.

  Therefore, the sheet processing apparatus according to the present embodiment employs the following configuration.

  39 and 40 are diagrams for explaining a sheet processing apparatus according to an eighth embodiment of the present invention.

  In general, since the folding process for the sheet bundle requires a great amount of torque, the folding roller pair 89 is rotationally driven at a low speed during the folding process by the folding roller pair 89. Further, if the sheet bundle that has passed through the pair of folding rollers 89 is stopped in order to further fold the sheet bundle, the stacker claw 21 is moved to a position for receiving a sheet to be processed next. The stacker claw 21 comes into contact with the rear end of the sheet bundle being folded.

  For this reason, the timing at which the stacker claw 21 starts to move from the home position position or the stop position where the folding process is performed to the position for receiving the next sheet to be processed is conveyed after the sheet bundle being folded and the folding process. It is preferable to set the timing so as not to contact the rear end of the sheet bundle in the middle.

  Specifically, in the present embodiment, the folding motor 800 is stopped after the folding process into the sheet bundle, and after the start of the folding process for driving the folding roller 7 until the stop, The movement of the lateral alignment plate and the stacker claw to the position to receive the sheet to be processed is started.

  Further, for example, if the stacker claw 21 starts driving at the timing when the folding blade 100 comes into contact with the sheet bundle and moves at the same movement speed as the sheet bundle conveyance speed of the folding roller pair 89, the folding blade 100 is moved. The end of the sheet bundle can be supported by the stacker claw 21 until the sheet bundle is nipped by the folding roller pair 89.

  On the other hand, regarding the lateral alignment plates 31a and 31b, when a large sheet is folded, and the sheet bundle to be processed next is a small size, the sheet bundle is placed on the stack tray 1 as shown in FIG. If there is a horizontal alignment plate, the horizontal alignment plate cannot be moved from the alignment position Q of the previous sheet bundle to the receiving position T which is the standby position. Therefore, it is necessary to move the lateral alignment plates 31a and 31b to the receiving position of the sheet to be processed next after the timing when the sheet bundle is discharged from the stack tray 1.

  Therefore, the timing at which the lateral alignment plates 31a and 31b move from the home position position or the stop position when the folding process is performed to the receiving position of the sheet bundle to be processed next is the rear end of the sheet bundle subjected to the folding process. It is desirable to set the timing at which it passes near the center of the nip of the pair of folding rollers 89 (see the broken line shown in FIG. 40).

  Each step in the processing (sheet processing method) in the above-described sheet processing apparatus is realized by causing the CPU 101 to execute a sheet processing program stored in the MEMORY 103.

  In this embodiment, the function for implementing the invention is recorded in advance in the apparatus. However, the present invention is not limited to this, and the same function may be downloaded from the network to the apparatus, and the same function is recorded. What is stored in the medium may be installed in the apparatus. The recording medium may be any form as long as the recording medium can store the program and can be read by the apparatus, such as a CD-ROM. Further, the function obtained by installing or downloading in advance may be realized in cooperation with an OS (operating system) or the like inside the apparatus.

  Although the present invention has been described in detail according to particular embodiments, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit and scope of the invention.

It is a figure for demonstrating schematic structure of the sheet processing apparatus 1F by the 1st Embodiment of this invention, and the image processing apparatus M provided with the same. It is a longitudinal cross-sectional view which shows the basic composition of the sheet processing apparatus 1F by the 1st Embodiment of this invention. FIG. 5 is a structural diagram for explaining an operation until a sheet conveyed in a conveyance path A is abutted against a stacker claw of the stacker 2 and aligned. FIG. 5 is a configuration diagram for explaining a lateral alignment portion that aligns sheet side edges in the stack tray 1. 2 is a perspective view for explaining a configuration in the vicinity of a stack tray 1. FIG. 2 is a perspective view for explaining a configuration in the vicinity of a stack tray 1. FIG. It is a figure for demonstrating the detail of the sheet folding mechanism in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the detail of the sheet folding mechanism in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the detail of the sheet folding mechanism in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the flow of operation | movement in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the flow of operation | movement in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the flow of operation | movement in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the flow of operation | movement in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the flow of operation | movement in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the flow of operation | movement in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating the flow of operation | movement in the sheet processing apparatus by the 1st Embodiment of this invention. It is a figure for demonstrating in detail the said problem in the folding process of a sheet bundle. It is a figure for demonstrating in detail the said problem in the folding process of a sheet bundle. It is a figure for demonstrating in detail the said problem in the folding process of a sheet bundle. It is a figure for demonstrating in detail the said problem in the folding process of a sheet bundle. 1 is a functional block diagram of a sheet processing apparatus according to a first embodiment of the present invention. It is a functional block diagram in the sheet processing apparatus by the 2nd Embodiment of this invention. It is a figure for demonstrating the operation | movement in the 2nd Embodiment of this invention. It is a timing chart which shows drive timing, such as an assist roller. It is a figure which shows the detail of a structure of the folding roller pair 89 vicinity in the 3rd Embodiment of this invention. It is a figure which shows the detail of a structure of the folding roller pair 89 vicinity in the 3rd Embodiment of this invention. It is a functional block diagram of the sheet processing apparatus by the 4th Embodiment of this invention. It is a structural diagram for demonstrating the drive mechanism which rotationally drives the folding roller pair 89 in the 4th Embodiment of this invention. It is a structural diagram for demonstrating the drive mechanism which rotationally drives the folding roller pair 89 in the 4th Embodiment of this invention. It is a timing chart for demonstrating the drive control by the rotational drive of the folding roller pair 89 in the 4th Embodiment of this invention. It is a functional block diagram in the sheet processing apparatus by the 5th Embodiment of this invention. It is a figure for demonstrating the drawer structure of each unit in the sheet processing apparatus 1Fe by the 6th Embodiment of this invention. It is a figure for demonstrating the drawer structure of each unit in the sheet processing apparatus 1Fe by the 6th Embodiment of this invention. It is a figure for demonstrating the drawer structure of each unit in the sheet processing apparatus 1Fe by the 6th Embodiment of this invention. It is a figure for demonstrating the drawer structure of each unit in the sheet processing apparatus 1Fe by the 6th Embodiment of this invention. It is a figure for demonstrating the drawer structure of each unit in the sheet processing apparatus 1Fe by the 6th Embodiment of this invention. It is a figure for demonstrating the drawer structure of each unit in the sheet processing apparatus 1Fe by the 6th Embodiment of this invention. It is a figure for demonstrating the sheet processing apparatus by the 7th Embodiment of this invention. It is a figure for demonstrating the sheet processing apparatus by the 8th Embodiment of this invention. It is a figure for demonstrating the sheet processing apparatus by the 8th Embodiment of this invention.

Explanation of symbols

1F, 1Fb Sheet processing device, 1A image reading device, 1P image forming device, 2 stacker, 2001 drive control unit, 2002 information acquisition unit, 42 assist roller, 101 CPU, 103 MEMORY, 5 staple, M image processing device.

Claims (18)

A stacker that holds the sheet bundle and is movable substantially parallel to the sheet surface of the sheet bundle;
Alignment that can be brought into contact with and separated from the sheet surface of the sheet held by the stacker and abuts against the reference position in the stacker by bringing the rotating roller surface into contact with the sheet. Laura,
A stapler for performing a stapling process on the sheet bundle aligned by the alignment roller and moved to a predetermined position by the stacker;
A control unit for bringing the rotating alignment roller into contact with the sheet bundle held by the stacker when moving the sheet bundle subjected to the stapling process in the direction of retreating from the stapler by the stacker;
A sheet processing apparatus comprising: An information acquisition unit that acquires information on the number of sheets constituting the sheet bundle;
The control unit holds the alignment roller in the stacker when moving the sheet bundle in a direction in which the sheet bundle is retracted from the stapler by the stacker when the number of sheets constituting the sheet bundle is a predetermined number or more. The sheet processing apparatus according to claim 1, wherein the sheet processing apparatus is brought into contact with the sheet bundle.   The sheet processing apparatus according to claim 1, wherein the aligning roller is disposed at a position where the stapler can contact a lower side than a center in a vertical direction of the sheet bundle when the stapler performs the stapling process.   2. The sheet processing apparatus according to claim 1, wherein the alignment roller contacts the sheet bundle moving downward from the predetermined position and rotates at a peripheral speed faster than a moving speed of the stacker.   The sheet processing apparatus according to claim 1, wherein the aligning roller contacts the sheet bundle until a timing later than the completion of the movement of the stacker. An information acquisition unit for acquiring information on the thickness of the sheets constituting the sheet bundle;
The control unit is configured to hold the alignment roller in the stacker when the stacker moves the bundle of sheets subjected to the stapling process in a direction in which the stacker is retracted from the stapler as the thickness of the sheet increases. The sheet processing apparatus according to claim 1, wherein a time for contacting the bundle is increased. An information acquisition unit that acquires information about the size of the sheets constituting the sheet bundle in the moving direction of the stacker;
When the control unit moves the sheet bundle subjected to the stapling process in the direction of retreating from the stapler by the stacker, the larger the size of the sheet constituting the sheet bundle to be stapled, The sheet processing apparatus according to claim 1, wherein the alignment roller is brought into contact with the sheet bundle held by the stacker at an early timing.   The sheet processing apparatus according to claim 1, wherein the aligning roller is in contact with the sheet bundle and then is separated from the sheet bundle while being rotated. With Laura pair,
A folding blade for pushing the sheet bundle moved by the stacker into the nip of the roller pair by moving from the standby position toward the nip of the roller pair;
The folding blade is after the sheet bundle is moved to a predetermined folding position by the stacker and after the alignment roller is separated from the sheet bundle, the sheet bundle is pushed into a nip of the roller pair. The sheet processing apparatus according to 1. A stacker that holds the sheet bundle and can move substantially parallel to the sheet surface of the sheet bundle, and can contact and separate from the sheet surface of the sheet held by the stacker. A stapling process is performed on the aligning roller that abuts the sheet to a reference position in the stacker and aligns the sheet, and the sheet bundle that is aligned by the aligning roller and moved to a predetermined position by the stacker. A sheet processing method in a sheet processing apparatus comprising a stapler,
A sheet processing method in which the rotating alignment roller is brought into contact with the sheet bundle held by the stacker when the stapled sheet bundle is moved by the stacker in a direction in which it is retracted from the stapler. Obtaining information on the number of sheets constituting the sheet bundle;
When the number of sheets constituting the sheet bundle is equal to or larger than a predetermined number, the alignment roller is brought into contact with the sheet bundle held by the stacker when the sheet bundle is moved by the stacker in a direction in which it is retracted from the stapler. The sheet processing method according to claim 10.   The sheet processing method according to claim 10, wherein the aligning roller is disposed at a position where the stapler can contact below a center in a vertical direction of the sheet bundle when the stapler performs the stapling process on the sheet bundle.   The sheet processing method according to claim 10, wherein the alignment roller contacts the sheet bundle moving downward from the predetermined position and rotates at a peripheral speed faster than a moving speed of the stacker.   The sheet processing method according to claim 10, wherein the alignment roller contacts the sheet bundle until a timing later than the completion of the movement of the stacker. Obtaining information on the thickness of the sheets constituting the sheet bundle;
As the thickness of the sheet increases, the alignment roller is brought into contact with the sheet bundle held by the stacker when the stapled sheet bundle is moved by the stacker in a direction in which it is retracted from the stapler. The sheet processing method according to claim 10, wherein the time is increased. Obtaining information on the size of the sheets constituting the sheet bundle in the moving direction of the stacker;
When the sheet bundle that has been subjected to the stapling process is moved by the stacker in a direction in which it is retracted from the stapler, the aligning roller is moved toward the stacker as the size of the sheet constituting the sheet bundle to be stapled increases. The sheet processing method according to claim 10, wherein the sheet is held in contact with the sheet bundle held at a fast timing.   The sheet processing method according to claim 10, wherein the alignment roller is separated from the sheet bundle while being rotated after contacting the sheet bundle. The sheet processing apparatus further includes a roller pair, and a folding blade that pushes the sheet bundle moved by the stacker into the nip of the roller pair by moving from the standby position toward the nip of the roller pair. And
The folding blade is after the sheet bundle is moved to a predetermined folding position by the stacker and after the alignment roller is separated from the sheet bundle, the sheet bundle is pushed into a nip of the roller pair. The sheet processing method according to 10.

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