This application is based upon and claims the benefit of priority from the corresponding Japanese Patent Application No. 2018-130484 filed on Jul. 10, 2018, the entire contents of which are incorporated herein by reference.
The present disclosure relates to a sheet aligning device, a sheet processing device including the sheet aligning device, and an image processing apparatus including the sheet processing device.
In general, a sheet processing device connected to an image forming apparatus includes a sheet aligning device and a sheet working device, wherein the sheet aligning device aligns a plurality of sheets, and the sheet working device applies working to the aligned plurality of sheets. The image forming apparatus and the sheet processing device connected thereto constitute an image processing apparatus.
The sheet working device is, for example, a sheet folding device that folds a plurality of sheets in two or three, or a staple device that applies a staple process to the plurality of sheets.
The sheet aligning device receives, by an inclined tray, a plurality of sheets with images formed thereon and aligns the leading and rear ends of the plurality of sheets on the inclined tray. The sheet aligning device includes a support member that supports the leading ends of the sheets as the sheets are sequentially conveyed onto the inclined tray.
For example, there is known a technology in which a stopper is provided as the support member, wherein the stopper has a recess in which the leading ends of the sheets enter on the inclined tray.
A sheet aligning device according to an aspect of the present disclosure has an inclined tray held by a frame and aligns a plurality of sheets conveyed onto the inclined tray. The sheet aligning device includes a support member, a support member moving mechanism, a regulation member, a regulation member moving mechanism, and a control unit. The support member is projected on the inclined tray, supported so as to be movable on the inclined tray, and has a support surface that abuts on leading ends of the sheets that are sequentially conveyed onto the inclined tray. The support member supports, at a predetermined reference position, the leading ends of the sheets. The support member moving mechanism moves the support member along the inclined tray. The regulation member is projected from the support surface toward an upstream in a sheet entry direction in which the sheets enter onto the inclined tray, supported so as to be movable on the support surface in a separating direction from or an approaching direction to the inclined tray, and defining a sheet entry space in which the leading ends of the sheets enter. The regulation member moving mechanism moves the regulation member on the support surface. The control unit controls the support member moving mechanism and the regulation member moving mechanism. The control unit controls the regulation member moving mechanism each time a sheet is conveyed onto the inclined tray, to widen the sheet entry space by moving the regulation member in the separating direction from the inclined tray, and then to narrow the sheet entry space by moving the regulation member in the approaching direction to the inclined tray.
A sheet processing device according to another aspect of the present disclosure includes the sheet aligning device and a sheet working device. The sheet aligning device aligns a plurality of sheets with images formed thereon supplied from an image forming apparatus. The sheet working device applies a predetermined working to the plurality of sheets aligned by the sheet aligning device.
An image processing apparatus according to a further aspect of the present disclosure includes an image forming apparatus and the sheet processing device. The image forming apparatus forms an image on a sheet.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description with reference where appropriate to the accompanying drawings. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. Furthermore, the claimed subject matter is not limited to implementations that solve any or all disadvantages noted in any part of this disclosure.
The following describes embodiments of the present disclosure with reference to the accompanying drawings. It should be noted that the following embodiments are examples of specific embodiments of the present disclosure and should not limit the technical scope of the present disclosure.
A sheet processing device 1000 according to a first embodiment of the present disclosure performs predetermined sheet processing to sheets 9 supplied from an image forming apparatus 10. The sheets 9 are prints on which images have been formed. The sheets 9 are sheet-like image formation media such as sheets of paper or resin films.
The image forming apparatus 10 and the sheet processing device 1000 are included in an image processing apparatus 1. That is, the image processing apparatus 1 includes the image forming apparatus 10 and the sheet processing device 1000 connected to the image forming apparatus 10.
As shown in
The plurality of pairs of conveyance rollers 11 convey the sheets 9 with images formed thereon supplied from the image forming apparatus 10, along any of a plurality of sheet conveyance paths 100, 101, 102, and 103.
The plurality of sheet conveyance paths 100, 101, 102, and 103 are a main conveyance path 100, a first conveyance path 101, a second conveyance path 102, and a third conveyance path 103.
The path switching mechanism 12 guides the sheets 9 that have been supplied from the image forming apparatus 10 to the main conveyance path 100, selectively to any one of the first conveyance path 101, the second conveyance path 102, and the third conveyance path 103.
The plurality of pairs of conveyance rollers 11 include a first pair of ejection rollers 11a, a second pair of ejection rollers 11b, and a third pair of ejection rollers 11c.
The first pair of ejection rollers 11a eject the sheets 9 conveyed along the first conveyance path 101, to the first ejection tray 13a. The second pair of ejection rollers 11b eject the sheets 9 conveyed along the second conveyance path 102 and processed by the first sheet aligning device 2, to the second ejection tray 13b. The third pair of ejection rollers 11c eject the sheets 9 conveyed along the third conveyance path 103 and processed by the second sheet aligning device 4 and the sheet folding device 5, to the third ejection tray 13c.
The first sheet aligning device 2 includes a first inclined tray 20, a first support member 21, an alignment rotator 22, and a motor 220 configured to drive the alignment rotator 22. The first inclined tray 20 is formed to be inclined with respect to the horizontal direction and receive a plurality of sheets 9 sequentially conveyed from diagonally above. The first sheet aligning device 2 aligns a plurality of sheets 9 conveyed from the second conveyance path 102 onto the first inclined tray 20.
The first support member 21 is disposed at a lower portion of the first inclined tray 20, and supports the leading ends of the sheets 9 that are sequentially conveyed onto the first inclined tray 20. The alignment rotator 22 is a rubber member that is rotationally driven at a position facing the first inclined tray 20.
The alignment rotator 22, while rotating, contacts the upper surface of the sheets 9 on the first inclined tray 20. The alignment rotator 22 applies, to the sheets 9 on the first inclined tray 20, a diagonally downward force, namely a force that biases the sheets 9 toward the first support member 21.
The first sheet aligning device 2 aligns leading ends 9a of the plurality of sheets 9 on the first inclined tray 20 to a surface of the first support member 21. It is noted that the alignment rotator 22 and the motor 220 configured to drive the alignment rotator 22 are an example of a sheet biasing mechanism.
The staple device 3 performs staple processing to a portion of the plurality of sheets 9 on the first inclined tray 20 aligned by the first sheet aligning device 2, the portion being close to the leading ends 9a of the sheets 9. The staple device 3 is an example of a sheet working device for applying stapling to the sheets 9. It is noted that the staple processing may not be performed to the sheets 9 by the staple device 3.
The second pair of ejection rollers 11b eject the plurality of sheets 9 on the first inclined tray 20 that have been aligned in an overlaid state, to the second ejection tray 13b in one batch.
As shown in
The second sheet aligning device 4 aligns a plurality of sheets 9 conveyed from the third conveyance path 103 onto the second inclined tray 40. The second inclined tray 40 is formed to be inclined with respect to the horizontal direction and receive a plurality of sheets 9 sequentially conveyed from diagonally above. The second inclined tray 40 is held by a frame 7 of the sheet processing device 1000 at a predetermined position (see
The second support member 41 is projected on the second inclined tray 40. The second support member 41 is supported so as to be movable on the second inclined tray 40. The second support member 41 supports the leading ends 9a of the sheets 9 that are sequentially conveyed onto the second inclined tray 40 by the plurality of pairs of conveyance rollers 11. The second support member 41 includes a support surface 41a that abuts on leading ends of the sheets 9. The upper alignment member 42 is provided to face the second support member 41 at an interval on the second inclined tray 40, the upper alignment member 42 being diagonally above the second support member 41.
For example, the second support member 41 and the upper alignment member 42 are provided at the center of the second inclined tray 40 in the width direction thereof. The width direction is perpendicular to a direction in which the sheets 9 are conveyed onto the second inclined tray 40. In
The support member moving mechanism 43 moves the second support member 41 along the second inclined tray 40. The upper alignment member moving mechanism 44 causes the upper alignment member 42 to abut on rear ends 9b of the sheets 9 on the second inclined tray 40 by moving the upper alignment member 42 along the second inclined tray 40.
The upper alignment member moving mechanism 44 applies a diagonally downward force, namely a force that biases the sheets 9 toward the second support member 41, to the sheets 9 on the second inclined tray 40 by causing the upper alignment member 42 to abut on the rear ends 9b of the sheets 9 on the second inclined tray 40.
The second sheet aligning device 4 aligns the leading ends 9a of the plurality of sheets 9 on the first inclined tray 20 to a surface of the second support member 41.
As described above, the upper alignment member 42 is configured to be movable along the second inclined tray 40 so as to align the sheets 9 on the second inclined tray 40 by abutting on the rear ends 9b of the sheets 9 supported by the second support member 41. It is noted that the upper alignment member moving mechanism 44 is an example of the sheet biasing mechanism.
The sheet folding device 5 applies folding to a plurality of sheets 9 aligned by the second sheet aligning device 4. The sheet folding device 5 is an example of the sheet working device. In the present embodiment, the sheet folding device 5 can perform a two-fold working and a three-fold working.
In the two-fold working, the sheet folding device 5 folds the sheets 9 in two by making one fold at the center of the sheets 9.
The sheet folding device 5 includes a blade 51, a blade moving mechanism 52, a first pair of folding rollers 53, a second pair of folding rollers 54, and a path switching mechanism 55. It is noted that the first pair of folding rollers 53 and the second pair of folding rollers 54 share one share roller 53a. Thus the first pair of folding rollers 53 and the second pair of folding rollers 54 are composed of three rollers as a whole.
The blade 51 is a plate-like member configured to strongly push a part of the sheets 9 on the second inclined tray 40 toward a first nip N1 between the first pair of folding rollers 53. The blade moving mechanism 52 moves the blade 51 toward the first nip Ni in a direction crossing the second inclined tray 40.
The first pair of folding rollers 53 hold therebetween the part of the sheets 9 strongly pushed by the blade 51, and convey the sheets 9 to a subsequent stage while making a first fold on the sheets 9.
The path switching mechanism 55 selectively guides the sheets 9 folded in two and fed out from the first pair of folding rollers 53, to the first conveyance path 501 that is directed to the third pair of ejection rollers 11c, or to the second conveyance path 502 that comes to a dead end.
In a case where the path switching mechanism 55 guides the sheets 9 folded in two to the first conveyance path 501, the sheets 9 are ejected while folded in two onto the third ejection tray 13c by the third pair of ejection rollers 11c.
In a case where the path switching mechanism 55 guides the two-fold sheets 9 to the second conveyance path 502, a part of the sheets 9 close to their rear end is guided by the path switching mechanism 55 to a second nip N2 between the second pair of folding rollers 54.
The second pair of folding rollers 54 hold therebetween the part of the two-fold sheets 9 guided to the second nip N2, and convey the sheets 9 to the third conveyance path 503 while making a second fold on the sheets 9. This allows the sheets 9 folded in three to be conveyed to the third conveyance path 503 that is directed to the third pair of ejection rollers 11c, and ejected by the third pair of ejection rollers 11c onto the third ejection tray 13c.
In
The support member moving mechanism 43 includes an endless first belt 43a, a pair of first support rollers 43b, and a first motor 43c. The pair of first support rollers 43b support the first belt 43a such that the first belt 43a can move rotationally in the inclination direction of the second inclined tray 40.
The second support member 41 is fixed to the first belt 43a. A part of the first belt 43a supported by the pair of first support rollers 43b serves as a lower part of the second inclined tray 40.
The first motor 43c rotationally drives one of the pair of first support rollers 43b. The first motor 43c rotationally drives, via the pair of first support rollers 43b, the first belt 43a in a predetermined forward rotation direction or a reverse rotation direction. This allows the second support member 41 to move along the second inclined tray 40 at the lower part of the second inclined tray 40.
The upper alignment member moving mechanism 44 includes an endless second belt 44a, a pair of second support rollers 44b, and a second motor 44c. The pair of second support rollers 44b support the second belt 44a such that the second belt 44a can move rotationally in the inclination direction of the second inclined tray 40. The second inclined tray 40, the first belt 43a, and the second belt 44a form an inclined sheet placement surface on which the sheets 9 are placed.
The upper alignment member 42 is fixed to the second belt 44a. A part of the second belt 44a supported by the pair of second support rollers 44b serves as an upper part of the second inclined tray 40.
The second motor 44c rotationally drives one of the pair of second support rollers 44b. The second motor 44c rotationally drives, via the pair of second support rollers 44b, the second belt 44a in a predetermined forward rotation direction or a reverse rotation direction. This allows the upper alignment member 42 to move along the second inclined tray 40 at the upper part of the second inclined tray 40.
The upper alignment member 42 includes a base portion 42a and a regulation portion 42b. The base portion 42a is configured to contact the rear ends 9b of the sheets 9 on the second inclined tray 40. The regulation portion 42b faces the second inclined tray 40 across a sheet entry space S2 in which the rear ends 9b of the sheets 9 enter.
The control unit 8 controls: motors that drive various roller pairs; the path switching mechanisms 12 and 55; the staple device 3; the motor 220 that drives the alignment rotator 22; the first motor 43c; the second motor 44c; the blade moving mechanism 52 and the like.
A portion of the control unit 8 that controls the motor 220 is a part of the configuration element of the first sheet aligning device 2. In addition, a portion of the control unit 8 that controls the first motor 43c and the second motor 44c is a part of the configuration element of the second sheet aligning device 4.
As shown in
The CPU 80 executes programs that are stored in the secondary storage device 82 in advance. This allows the control unit 8 to execute data processing based on detection results of various sensors, and execute various controls.
The RAM 81 is a computer-readable volatile storage device that primarily stores: the programs executed by the CPU 80; and data that is output and consulted by the CPU 80 during execution of the programs.
The secondary storage device 82 is a computer-readable nonvolatile storage device. The secondary storage device 82 stores the programs and various types of data. For example, either or both of a flash memory and a hard disk drive may be adopted as the secondary storage device 82.
For example, when the sheets 9 are conveyed onto the first inclined tray 20 of the first sheet aligning device 2, the control unit 8 rotates a motor that drives the alignment rotator 22.
In addition, when the sheet folding device 5 applies folding to the sheets 9, the control unit 8 sets a target position on the sheets 9 present on the inclined tray, based on the number of folds to be made on the sheets 9, and the size of the sheets 9.
Furthermore, before the sheets 9 are conveyed onto the second inclined tray 40 of the second sheet aligning device 4, the control unit 8 moves the second support member 41 to a lower reference position P00 corresponding to the target position by controlling the first motor 43c of the support member moving mechanism 43.
That is, the control unit 8 moves the second support member 41 to one lower reference position P00 that corresponds to the size of the sheets 9 on the second inclined tray 40, among a plurality of lower reference positions P00 corresponding to a plurality of sheet sizes.
Furthermore, each time a sheet 9 is conveyed onto the second inclined tray 40, the control unit 8 moves the upper alignment member 42 from a predetermined upper reference position P10 to an upper retreated position P11 that is diagonally upward of the upper reference position P10, and then to the upper reference position P10, by controlling the second motor 44c of the upper alignment member moving mechanism 44.
When the upper alignment member 42 moves from the upper retreated position P11 to the upper reference position P10, the rear ends 9b of the sheets 9 enter the sheet entry space S2 of the upper alignment member 42, and the upper alignment member 42 applies a diagonally downward force to the sheets 9.
Meanwhile, a sheet 9 with an image formed thereon may be curled and conveyed onto the second inclined tray 40 in the state of being curled. To deal with this, the second support member 41 may have a recess into which the leading end 9a of the sheet 9 enters.
However, if an opening of the recess of the second support member 41 is narrow, the leading end 9a of the sheet 9 may come off the recess of the second support member 41. If the leading end 9a of the sheet 9 comes off the recess of the second support member 41, the alignment performance of the sheets 9 is degraded.
On the other hand, when the opening of the recess of the second support member 41 is wide, the leading ends 9a of the plurality of sheets 9 may not be aligned due to varied curls of the sheets 9, and the alignment performance of the sheets 9 may be degraded.
Furthermore, when a diagonally downward force is applied to the sheets 9 on the second inclined tray 40, a portion close to the leading end 9a of the curled sheet 9 may bend in the recess of the second support member 41.
The second sheet aligning device 4 of the sheet processing device 1000 includes a regulation member 45 and a regulation member moving mechanism 6 that are described below. With this configuration, it is possible for the second sheet aligning device 4 to prevent degradation of the alignment performance of the sheets 9 conveyed onto the second inclined tray 40, and prevent the portion close to the leading end 9a of the curled sheet 9 from bending.
As shown in
Each time a sheet 9 is conveyed onto the second inclined tray 40, the regulation member moving mechanism 6 moves the regulation member 45 in a separating direction D1 to widen the sheet entry space S1, and then in an approaching direction D2 to narrow the sheet entry space S1.
In the present embodiment, the control unit 8 causes the second support member 41 to operate as follows by controlling the support member moving mechanism 43. That is, each time a sheet 9 is conveyed onto the second inclined tray 40, the control unit 8 causes the second support member 41 to be held at the lower reference position P00 to receive the sheet 9, moves the second support member 41 from the lower reference position P00 to a lower retreated position P01 that is diagonally downward of the lower reference position P00, and then to the lower reference position P00.
The regulation member moving mechanism 6 moves the regulation member 45 in conjunction with the movement of the second support member 41. That is, the regulation member moving mechanism 6 moves the regulation member 45 in the separating direction D1 in conjunction with the movement of the second support member 41 from the lower reference position P00 to the lower retreated position P01. Furthermore, the regulation member moving mechanism 6 moves the regulation member 45 in the approaching direction D2 in conjunction with the movement of the second support member 41 from the lower retreated position P01 to the lower reference position P00.
As described above, each time a sheet 9 is conveyed onto the second inclined tray 40, the regulation member moving mechanism 6 widens the sheet entry space S1 by moving the regulation member 45 in the separating direction from the second inclined tray 40. Thereafter, the regulation member moving mechanism 6 narrows the sheet entry space S1 by moving the regulation member 45 in an approaching direction to the second inclined tray 40. The following describes a specific configuration of the regulation member moving mechanism 6 according to the present embodiment.
The regulation member moving mechanism 6 includes a guided portion 61, a guiding portion 62, a spring 63, and one or more contact members 64. In the present embodiment, the regulation member moving mechanism 6 includes a plurality of contact members 64 that are respectively disposed at a plurality of lower retreated positions P01 that respectively correspond to a plurality of lower reference positions P00.
The guided portion 61 is integrally formed with the regulation member 45. The guiding portion 62 is formed in the second support member 41. The guiding portion 62 guides the guided portion 61 in the separating direction D1 so that the regulation member 45 is separated from the second inclined tray 40, and in the approaching direction that is reverse to the separating direction D1.
In the example shown in
The spring 63 applies an elastic force in the approaching direction D2 to the guided portion 61. It is noted that the spring 63 is an example of an elastic member. The spring 63 may be replaced with another elastic member such as rubber.
The contact members 64 are held by the frame 7 at predetermined positions and formed to project in the separating direction D1. The contact members 64 include contact surfaces 64a that are inclined with respect to a direction extending along the second inclined tray 40. When the second support member 41 moves from the lower reference position P00 to the lower retreated position P01, the guided portion 61 slides on the contact surfaces 64a.
When the second support member 41 moves from the lower reference position P00 to the lower retreated position P01, the regulation member 45 moves in the separating direction D1 from the proximity position by a pressure applied from the contact surface 64a to the guided portion 61.
Furthermore, when the second support member 41 moves from the lower retreated position P01 to the lower reference position P00, the regulation member 45 moves in the approaching direction D2 by the elastic force of the spring 63 and returns to the proximity position.
The spring 63 and the contact member 64, in conjunction with the movement of the second support member 41 from the lower reference position P00 to the lower retreated position P01, move the guided portion 61 in the separating direction D 1. Furthermore, the spring 63 and the contact member 64, in conjunction with the movement of the second support member 41 from the lower retreated position P01 to the lower reference position P00, move the guided portion 61 in the approaching direction D2.
In the second sheet aligning device 4, the spring 63 and the contact members 64 are an example of an interlocking mechanism configured to move the guided portion 61 in conjunction with a movement of the second support member 41.
The control unit 8 causes the support member moving mechanism 43 to move the second support member 41 from the lower retreated position P01 to the lower reference position P00. This causes the upper alignment member moving mechanism 44 to move the upper alignment member 42 from the upper retreated position P11 to the upper reference position P10 each time the leading end 9a of a sheet 9 is supported by the second support member 41.
The control unit 8 may cause the support member moving mechanism 43 to move the second support member 41 from the lower retreated position P01 to the lower reference position P00, and thereafter, may cause the upper alignment member moving mechanism 44 to move the upper alignment member 42 from the upper retreated position P11 to the upper reference position P10.
When the second sheet aligning device 4 is to receive a sheet 9 on the second inclined tray 40, the second sheet aligning device 4 widens the sheet entry space S1. This prevents the leading end 9a of the sheet 9 from coming off the sheet entry space S1 that is formed by the second support member 41 and the regulation member 45.
Furthermore, after the sheet 9 has been received on the second inclined tray 40, the second sheet aligning device 4 narrows the sheet entry space S1. This prevents the leading ends 9a of a plurality of sheets 9 from not being aligned due to varied curls of the sheets 9.
Similarly, the above-described configuration prevents a portion close to the leading end 9a of the curled sheet 9 from bending in the sheet entry space S1 when the upper alignment member 42 applies a diagonally downward force to the sheets 9 on the second inclined tray 40. With this configuration, even if the sheets 9 are curled, the upper alignment member 42 aligns the rear ends 9b of the sheets 9 while the leading ends 9a of the sheets 9 abut on the second support member 41.
Accordingly, it is possible to prevent the alignment performance of the sheets 9 conveyed onto the second inclined tray 40 from being degraded due to curls of the sheets 9.
The following describes, with reference to
In
In addition, the second sheet aligning device 4A has a configuration where the regulation member moving mechanism 6 in the second sheet aligning device 4 has been replaced with a regulation member moving mechanism 6A.
The following describes differences of the regulation member moving mechanism 6A from the regulation member moving mechanism 6. The regulation member moving mechanism 6A, as is the case with the regulation member moving mechanism 6, includes the guided portion 61 and the guiding portion 62.
The regulation member moving mechanism 6A includes a link mechanism 66 that includes the guided portion 61 and a link member 66a. The link member 66a is connected to a fixed portion 66b in such a way as to pivot around the fixed portion 66b that is held by the frame 7 at a predetermined position.
The link mechanism 66 moves the guided portion 61 in the separating direction D1 in conjunction with the movement of the second support member 41 from the lower reference position P00 to the lower retreated position P01. Furthermore, the link mechanism 66 moves the guided portion 61 in the approaching direction D2 in conjunction with the movement of the second support member 41 from the lower retreated position P01 to the lower reference position P00.
In the second sheet aligning device 4A, the link mechanism 66 is an example of the interlocking mechanism configured to move the guided portion 61 in conjunction with a movement of the second support member 41.
It is noted that in the sheet processing device 1000A, the sheet folding device 5 is configured to perform only either of the two-fold working or the three-fold working on the plurality of sheets 9 aligned by the second sheet aligning device 4A. In addition, in the second sheet aligning device 4A, the lower reference position P00 is a predetermined one position.
The second sheet aligning device 4A produces the same effect as the second sheet aligning device 4.
The following describes, with reference to
In
In addition, the second sheet aligning device 4B has a configuration where the regulation member moving mechanism 6 in the second sheet aligning device 4 has been replaced with a regulation member moving mechanism 6B.
The following describes differences of the regulation member moving mechanism 6B from the regulation member moving mechanism 6. The regulation member moving mechanism 6B, as is the case with the regulation member moving mechanism 6, includes the guided portion 61, the guiding portion 62, and the spring 63.
The regulation member moving mechanism 6B includes an actuator 67 in place of the contact members 64. The actuator 67, in response to a control command from the control unit 8, switches between: a state where it supports the regulation member 45 at the proximity position; and a state where it supports the regulation member 45 at a position farther from the second inclined tray 40 than the proximity position.
In the present embodiment, a moving portion of the actuator 67 abuts on, in the separating direction D1, a supported portion 61a that is a part of the guided portion 61. For example, the actuator 67 is a solenoid. It is noted that the actuator 67 may be realized by a motor and a cam mechanism.
The actuator 67 allows the regulation member 45 to be present at the proximity position by supporting the supported portion 61a at a first position against the elastic force of the spring 63. In
In addition, the actuator 67 allows the regulation member 45 to be present at a position farther from the second inclined tray 40 than the proximity position in the separating direction D1, by supporting the supported portion 61a at a second position against the elastic force of the spring 63. In
That is, the actuator 67, in response to a control command from the control unit 8, switches between: the state where it supports the regulation member 45 at the proximity position; and the state where it supports the regulation member 45 at the position farther from the second inclined tray 40 than the proximity position.
Each time a sheet 9 is conveyed onto the second inclined tray 40, the control unit 8, by controlling the actuator 67, moves the supported portion 61a from the first position to the second position, and then returns the supported portion 61a to the first position.
Accordingly, each time a sheet 9 is conveyed onto the second inclined tray 40, the regulation member 45 moves in the separating direction D1 from the proximity position, and then returns to the proximity position. As such, in the present embodiment, it is not necessary to move the second support member 41 from the lower reference position P00 to the lower retreated position P01 each time a sheet 9 is conveyed onto the second inclined tray 40.
The second sheet aligning device 4B produces the same effect as the second sheet aligning device 4.
The following describes, with reference to
The sheet processing device 1000C has a configuration where a regulation member moving mechanism 6B has been added to the sheet processing device 1000. In the present embodiment, the regulation member moving mechanism 6B is configured to move a regulation member 23 connected to the first support member 21 of the first sheet aligning device 2.
When the sheet processing device 1000C is adopted, the first sheet aligning device 2 produces the same effect as the second sheet aligning device 4.
It is to be understood that the embodiments herein are illustrative and not restrictive, since the scope of the disclosure is defined by the appended claims rather than by the description preceding them, and all changes that fall within metes and bounds of the claims, or equivalence of such metes and bounds thereof are therefore intended to be embraced by the claims.
Number | Date | Country | Kind |
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2018-130484 | Jul 2018 | JP | national |