This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2016-060769 filed Mar. 24, 2016.
The present invention relates to binding process devices and recording-medium processing systems.
According to an aspect of the invention, there is provided a binding process device including an advancing member and a binding process unit. The advancing member advances toward a corner of a recording-medium bundle having multiple edges and having the corner at an intersection position where the edges intersect. The binding process unit performs a binding process on the recording-medium bundle by causing the advancing member to advance toward the corner and is capable of performing the binding process at a first position and at a second position located closer to the intersection position than the first position.
Exemplary embodiments of the present invention will be described in detail based on the following figures, wherein:
An exemplary embodiment of the present invention will be described below with reference to the appended drawings.
The recording-medium processing system 500 according to this exemplary embodiment is provided with an image forming apparatus 1 that forms an image onto a recording medium, such as a sheet P, by, for example, electrophotography and a post-processing apparatus 2 that performs post-processing on multiple sheets P having images formed thereon by the image forming apparatus 1.
The image forming apparatus 1 is of a so-called tandem type and includes four image forming units 100Y, 100M, 100C, and 100K (which may also be collectively referred to as “image forming units 100”) that form images based on image data of respective colors. The image forming apparatus 1 is provided with a laser exposure device 101 that radiates exposure light onto photoconductor drums 107 provided in the individual image forming units 100 so as to form electrostatic latent images on the surfaces of the photoconductor drums 107.
Furthermore, the image forming apparatus 1 is provided with an intermediate transfer belt 102 onto which toner images of the respective colors formed at the image forming units 100 are superposed and transferred, and is also provided with first-transfer rollers 103 that sequentially transfer (first-transfer) the toner images formed at the image forming units 100 onto the intermediate transfer belt 102. Moreover, the image forming apparatus 1 is provided with a second-transfer roller 104 that collectively transfers (second-transfers) the toner images transferred on the intermediate transfer belt 102 onto a sheet P, a fixing device 105 that fixes the second-transferred toner images onto the sheet P, and an apparatus controller 106 that controls the operation of the image forming apparatus 1.
In each image forming unit 100, the photoconductor drum 107 is electrostatically charged, and an electrostatic latent image is formed on the photoconductor drum 107. The electrostatic latent image is developed so that a toner image of the corresponding color is formed on the surface of the photoconductor drum 107.
The toner images formed on the surfaces of the individual photoconductor drums 107 are sequentially transferred onto the intermediate transfer belt 102 by the first-transfer rollers 103. Then, as the intermediate transfer belt 102 moves, the toner images are transported to a position where the second-transfer roller 104 is disposed.
The image forming apparatus 1 has sheet accommodation sections 110A to 110D that accommodate therein sheets P of different sizes and different types. For example, a sheet P is picked up from the sheet accommodation section 110A by a pickup roller 111, and this sheet P is transported to a registration roller 113 by a transport roller 112.
Then, in accordance with a timing at which the toner images on the intermediate transfer belt 102 are transported to the second-transfer roller 104, the sheet P is fed from the registration roller 113 toward an opposing section (i.e., a second-transfer section) where the second-transfer roller 104 and the intermediate transfer belt 102 face each other.
The toner images on the intermediate transfer belt 102 are then collectively electrostatically transferred (second-transferred) onto the sheet P due to the effect of a transfer electric field generated by the second-transfer roller 104.
Subsequently, the sheet P having the toner images transferred thereon is separated from the intermediate transfer belt 102 and is transported toward the fixing device 105. The fixing device 105 performs a fixing process by using heat and pressure so as to fix the toner images onto the sheet P, whereby an image is formed on the sheet P.
Then, the sheet P having the image formed thereon is output from a sheet output section T of the image forming apparatus 1 by a transport roller 114 and is fed to the post-processing apparatus 2 connected to the image forming apparatus 1.
The post-processing apparatus 2 is disposed downstream of the sheet output section T of the image forming apparatus 1 and performs post-processing, such as a hole-punching process and a binding process, on the sheet P having the image formed thereon.
As shown in
The post-processing apparatus 2 also includes a sheet processing controller 23 that controls each functional unit of the post-processing apparatus 2. The sheet processing controller 23 is connected to the apparatus controller 106 (see
Furthermore, the post-processing apparatus 2 includes a stacker section 80 on which sheets P (i.e., a sheet bundle B) that have undergone a process performed by the post-processing apparatus 2 are stacked.
Although the sheet processing controller 23 is provided within a housing of the finisher unit 22 in the post-processing apparatus 2 according to this exemplary embodiment, the sheet processing controller 23 may alternatively be provided within a housing of the image forming apparatus 1 (see
As shown in
Moreover, the transport unit 21 is provided with multiple transport rollers 211 that transport the sheet P having the image formed thereon in the image forming apparatus 1 toward the finisher unit 22.
The finisher unit 22 is provided with a binding process device 600 that performs a binding process on a sheet bundle B as an example of a recording-medium bundle. Specifically, the binding process device 600 according to this exemplary embodiment binds a sheet bundle B together without using staples.
The binding process device 600 is provided with a sheet accumulation section 60 that supports sheets P from below and accumulates a predetermined number of sheets P so as to form a sheet bundle B. The binding process device 600 is also provided with a binding unit 50 that binds the sheet bundle B together.
In this exemplary embodiment, the binding process performed on the sheet bundle B involves pressing advancing members (to be described later) provided in the binding unit 50 against the sheet bundle B from opposite faces of the sheet bundle B so as to bring the sheets P constituting the sheet bundle B into pressure contact with each other (i.e., to cause the fibers constituting the sheets P to entwine).
Furthermore, the binding process device 600 is provided with a transport roller 61 and a movable roller 62. The transport roller 61 rotates clockwise in
The movable roller 62 is provided in a movable manner about a rotation shaft 62a and is located at a receded position from the transport roller 61 when sheets P are to be accumulated on the sheet accumulation section 60. When delivering the created sheet bundle B toward the stacker section 80, the movable roller 62 is pressed against the sheet bundle B on the sheet accumulation section 60.
A process performed in the post-processing apparatus 2 will now be described.
In this exemplary embodiment, a command signal indicating that a process is to be executed on a sheet P is output from the apparatus controller 106 to the sheet processing controller 23. The sheet processing controller 23 receives this command signal so that the post-processing apparatus 2 executes the process on the sheet P.
In the process performed in the post-processing apparatus 2 (see
If there is no hole-punching command from the sheet processing controller 23, the sheet P is delivered to the finisher unit 22 without undergoing the hole-punching process by the punching functional unit 30.
The sheet P delivered to the finisher unit 22 is transported to the sheet accumulation section 60 provided in the binding process device 600. Then, the sheet P slides on the sheet accumulation section 60 in accordance with an inclination angle given to the sheet accumulation section 60 so as to abut on sheet regulation sections 64 provided at an end of the sheet accumulation section 60.
Thus, the sheet P stops moving. In this exemplary embodiment, the sheet P abuts on the sheet regulation sections 64 so that a sheet bundle B having sheets P with aligned trailing edges is created on the sheet accumulation section 60. In this exemplary embodiment, a rotating paddle 63 that moves the sheet P toward the sheet regulation sections 64 is further provided.
The opposite widthwise edges of the sheet accumulation section 60 are provided with first movable members 81.
The first movable members 81 are pressed against the edges of sheets P constituting the sheet bundle B so as to positionally align the edges of the sheets P constituting the sheet bundle B. Moreover, the first movable members 81 move in the width direction of the sheet bundle B so as to move the sheet bundle B in the width direction of the sheet bundle B.
In detail, in this exemplary embodiment, when sheets P are to be accumulated on the sheet accumulation section 60, the first movable members 81 are pressed against the edges of the sheets P so as to positionally align the edges of the sheets P.
If the binding position of the sheet bundle B is to be changed, which will be described later, the first movable members 81 press against the sheet bundle B so as to move the sheet bundle B in the width direction of the sheet bundle B.
Furthermore, the binding process device 600 according to this exemplary embodiment is provided with a second movable member 82.
The second movable member 82 moves in the vertical direction in
Moreover, movement motors M1 for moving the first movable members 81 and the second movable member 82 are provided in this exemplary embodiment.
As indicated by an arrow 4A in
Moreover, the binding unit 50 moves to position C in
The binding unit 50 moves linearly between position A and position B, whereas the binding unit 50 moves while rotating by, for example, 45° between position A and position C.
In this exemplary embodiment, the binding unit 50 performs the binding process in an area where the sheet regulation sections 64 and the second movable member 82 are not provided.
In detail, as shown in
As shown in
Furthermore, in this exemplary embodiment, when the binding unit 50 is to move, the second movable member 82 moves to a position indicated by a reference sign 4B in FIG. 3. Thus, interference between the binding unit 50 and the second movable member 82 may be avoided.
As shown in
The first driver 51 is provided with a driving piece 511. The driving piece 511 is plate-shaped and has a first end at the sheet bundle B side and a second end opposite from the first end.
In this exemplary embodiment, a first advancing member 512 is attached to the first end of the driving piece 511. The first advancing member 512 advances toward the sheet bundle B from one face of the sheet bundle B so as to press against this sheet bundle B. Furthermore, the driving piece 511 is provided with a protrusion 511B that protrudes toward the second driver 52. The protrusion 511B has a through-hole 511A.
As shown in
The driving piece 521 is plate-shaped and has a first end at the sheet bundle B side and a second end opposite from the first end. In this exemplary embodiment, a second advancing member 522 is attached to the first end of the driving piece 521. The second advancing member 522 advances toward the other face of the sheet bundle B so as to press against the sheet bundle B.
The driving piece 521 is also provided with a protrusion 521B that protrudes toward the first driver 51. The protrusion 521B has a through-hole (which is not shown but is provided at a position behind the through-hole 511A of the first driver 51).
Furthermore, in this exemplary embodiment, a pin PN extends through the through-hole 511A provided in the first driver 51 and the through-hole (not shown) provided in the second driver 52. In this exemplary embodiment, the driving piece 511 and the driving piece 521 rotate about the pin PN.
Moreover, in this exemplary embodiment, the first advancing member 512 and the second advancing member 522 are provided at the sheet bundle B side relative to the pin PN, and the cam 53 is provided at the side opposite from the side provided with the sheet bundle B with the pin PN interposed therebetween.
As shown in
The second advancing member 522 has a rectangular prismatic base 522A. An upper surface 522B of this base 522A is provided with projections and depressions. More specifically, the upper surface 522B of the base 522A is provided with multiple projections 522D. The projections 522D are arranged in the left-right direction in
This binding process performed on the corner of the sheet bundle B involves causing the first advancing member 512 and the second advancing member 522 to advance toward this corner.
In this exemplary embodiment, this corner binding process may be performed at either a first binding position 8A or a second binding position 8B, which is located closer to an edge intersection position than the first binding position 8A.
In detail, the sheet bundle B according to this exemplary embodiment has a rectangular shape when viewed from the front and has first to fourth edges 41 to 44.
Furthermore, the sheet bundle B according to this exemplary embodiment has four corners 46 at the position where the first edge 41 and the second edge 42 intersect, the position where the second edge 42 and the third edge 43 intersect, the position where the third edge 43 and the fourth edge 44 intersect, and the position where the fourth edge 44 and the first edge 41 intersect, respectively.
In this exemplary embodiment, the binding process is performed on the corner 46 (which will be referred to as “first corner 461” hereinafter) located at the intersection position where the first edge 41 and the second edge 42 intersect (which will be referred to as “first intersection position 55” hereinafter). This binding process for the first corner 461 may be performed at either the first binding position 8A, which is closer toward a center C of the sheet bundle B, or the second binding position 8B, which is closer to the first intersection position 55 than the first binding position 8A.
More specifically, in this exemplary embodiment, if the number of sheets P constituting the sheet bundle B is smaller than or equal to a predetermined value, the binding process is performed at the first binding position 8A. If the number of sheets P constituting the sheet bundle B exceeds the predetermined value, the binding process is performed at the second binding position 8B.
The load acting on the bound section of the sheet bundle B (i.e., load that may cause the bound section to be unbound) varies depending on the number of sheets P constituting the sheet bundle B.
As shown in
In contrast, as shown in
In this case, the turned sheets P have a certain angle relative to the unturned sheets P at the bound section, so that the load that may cause the bound section to be unbound is likely to act on the bound section.
When the number of sheets P constituting the sheet bundle B is large in this manner, the load acting on the bound section increases (i.e., the bound section is likely to become unbound easily). Therefore, in this exemplary embodiment, if the number of sheets P constituting the sheet bundle B is large, the binding process is performed at the binding position where the load acting on the bound section is smaller. In detail, the binding process is performed at the second binding position 8B that is located closer to the first intersection position 55 (see
In contrast, if the load acting on the bound section is small due to a small number of sheets P constituting the sheet bundle B, the binding process is performed at the first binding position 8A.
Specifically,
If sheets P in the sheet bundle B shown in
In contrast, if sheets P in the sheet bundle B shown in
Accordingly, in this exemplary embodiment, if the number of sheets P constituting the sheet bundle B exceeds the predetermined value, the binding position is changed to a position closer to the first intersection position 55. Thus, the bound section becomes less likely to be unbound.
If the number of sheets P constituting the sheet bundle B is small, the bound section is formed at a position closer toward the center C (see
In the above description, the switching between the binding process at the first binding position 8A and the binding process at the second binding position 8B is performed based on the number of sheets P constituting the sheet bundle B. Alternatively, for example, this switching may be performed based on a command from the user.
In detail, for example, if the user inputs a command for changing the binding position via an operation panel (not shown), the binding position is changed from, for example, the first binding position 8A to the second binding position 8B or from the second binding position 8B to the first binding position 8A.
For example, the number of sheets P constituting the sheet bundle B is ascertained based on information input by the user via the operation panel (not shown).
When the user inputs the information related to the number of sheets P via the operation panel (not shown), the sheet processing controller 23 (see
In this exemplary embodiment, the switching between the binding process at the first binding position 8A and the binding process at the second binding position 8B is performed by moving the sheet bundle B.
In detail, the sheet bundle B is moved by using the first movable members 81 and the second movable member 82 shown in
In this exemplary embodiment, if the binding process is to be performed at the first binding position 8A (see
In contrast, if the binding process is to be performed at the second binding position 8B (see
Thus, the second movable member 82 moves upward in
In this exemplary embodiment, for example, the sheet processing controller 23, the movement motors M1, and the binding unit 50 function as a binding process unit. With this binding process unit, the first advancing member 512 (see
Although the binding position is changed by moving the sheet bundle B in this exemplary embodiment, the binding position may alternatively be changed by moving the binding unit 50. As another alternative, the binding position may be changed by moving both of the sheet bundle B and the binding unit 50.
The binding unit 50 may be moved in accordance with a known technique. For example, the binding unit 50 may be moved by using a rack gear 551 that operates in conjunction with the binding unit 50, a pinion gear 552 that engages with the rack gear 551, and a pinion motor (not shown) that rotates the pinion gear 552, as indicated by a reference sign 4E in
In the above description, the binding position is changed by moving the sheet bundle B in both the direction in which the first edge 41 (see
In this example, when the sheet bundle B is in a state indicated by a reference sign 12A, the binding position is set to the first binding position 8A. When the sheet bundle B changes to a state indicated by a reference sign 12B as a result of the sheet bundle B moving upward in
Furthermore, as shown in
In this case, when the sheet bundle B is in a state indicated by a reference sign 12C, the binding position is set to the first binding position 8A. When the sheet bundle B changes to a state indicated by a reference sign 12D as a result of the sheet bundle B moving leftward in
Although the sheet bundle B is moved in
Furthermore, the binding position may be changed by moving both of the sheet bundle B and the binding unit 50 along one of the first edge 41 and the second edge 42.
Moreover, as shown in
As an alternative to rotating the binding unit 50, the sheet bundle B may be rotated about a predetermined rotation axis.
The binding unit 50 or the sheet bundle B may be rotated in accordance with a known technique. For example, the binding unit 50 or the sheet bundle B may be rotated by using a rotating member that rotates about a predetermined rotation axis attached to the binding unit 50 or the sheet accumulation section 60 and a rotation motor that rotates this rotating member.
Furthermore, as shown in
In the examples shown in
Furthermore, in this exemplary embodiment, the first advancing member 512 and the second advancing member 522 may extend in a direction intersecting a diagonal line TL of the sheet bundle B and may be caused to advance toward the sheet bundle B so as to bind the sheet bundle B together, as shown in
In the processing example shown in
Then, in the binding process shown in
In the binding process shown in
In contrast, in the binding process shown in
Similar to the above description, the switching between the binding process shown in
Furthermore, the switching between the binding process shown in
For example, the binding unit 50 is moved and rotated by using a rotating member to which the binding unit 50 is attached, a rotation motor that rotates this rotating member, and a movement motor that linearly moves this rotating member.
Furthermore, the switching between the binding process shown in
In the exemplary embodiment described above, the binding position is changed by moving at least one of the sheet bundle B and the pair of advancing members (i.e., the first advancing member 512 and the second advancing member 522). Alternatively, for example, two pairs of advancing members installed at different positions from each other may be provided, and the binding position may be changed by switching between the pairs of advancing members to be used.
Furthermore, although two advancing members, namely, the first advancing member 512 and the second advancing member 522, are provided in the above description, for example, the second advancing member 522 may be eliminated and be replaced with a support base that supports the sheet bundle B from below.
Furthermore, although the binding process is performed by pressing the first advancing member 512 and the second advancing member 522 against the sheet bundle B in the above description, the binding process may be performed by using a method other than such a pressing method.
For example, at least one of or each of the first advancing member 512 and the second advancing member 522 may be provided with a cutting section. By using this cutting section, a through-hole and a flake-shaped portion to be fitted in this through-hole may be formed in the sheet bundle B. This flake-shaped portion is fitted into the through-hole. Thus, the sheets P constituting the sheet bundle B are bound together, so that a sheet bundle B in a bound state is created.
The foregoing description of the exemplary embodiments of the present invention has been provided for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations will be apparent to practitioners skilled in the art. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, thereby enabling others skilled in the art to understand the invention for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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2016-060769 | Mar 2016 | JP | national |