Embodiments described herein relate generally to an image forming system, a sheet processing device, and a control method of the sheet processing device.
A sheet processing device is used to staple a sheet which is conveyed from an image forming device. The sheet processing device performs the stapling on the sheet which is placed in a process tray. The sheet processing device discharges the stapled sheet from a sheet discharging port.
When a foreign matter permeates the process tray from the sheet discharging port, the foreign matter may be stapled. There is a need for a sheet processing device which can avoid stapling a foreign matter.
In general, according to one embodiment, an image forming system includes an image forming device, a stapler, a process tray, a first sensor, a second sensor, and a control unit. The image forming device forms an image on a sheet. The stapler performs stapling on the sheet. The process tray places the sheet to be stapled on the upper surface. The first sensor is disposed on the upper side of the process tray. The first sensor outputs a first signal corresponding to a first distance to an object which is disposed at a first position of a sheet placement region of the upper surface of the process tray or a first thickness of the object which is disposed at the first position. The second sensor is disposed on the upper side of the process tray. The second sensor outputs a second signal corresponding to a second distance to the object which is disposed at a second position on the downstream side in a sheet discharge direction from the first position of the sheet placement region of the upper surface of the process tray or a second thickness of the object which is disposed at the second position. The control unit is provided in the image forming device. The control unit controls the stapling using the first signal and the second signal.
Hereinafter, the image forming system, a sheet processing device, and the control method of the sheet processing device of the embodiment will be described with reference to the drawings.
In this disclosure, an X direction, a Y direction, and a Z direction of an orthogonal coordinate system are defined as follows. The X direction and the Y direction are directions parallel to the upper surface of the process tray. The X direction is a direction of discharging the sheet placed in the process tray, and a +X direction indicates the downstream side in the discharge direction. The Y direction is a width direction of the sheet placed in the process tray, and is a direction perpendicular to the X direction. The Z direction is a normal direction of the upper surface of the process tray, and the +Z direction is a direction of placing a sheet with respect to the upper surface of the process tray.
The image forming system will be described.
As illustrated in
The image forming device 2 includes a control panel 11, a scanner unit 12, a printer unit 13, a sheet supply unit 14, a sheet conveyance unit 15, and an image forming control unit (control unit) 16.
The control panel 11 includes an operation unit and a display unit. The operation unit receives a user's operation. For example, the operation unit includes various types of keys and a touch panel. The display unit displays various types of information.
The control panel 11 receives an input related to the selection of a staple mode. The staple mode is a processing mode in which binding (stapling) is performed using a staple. The control panel 11 may receive an input related to the size of the sheet S to be stapled if the selection of the staple mode is received. The control panel 11 may receive an input related to the number of the sheets S to be stapled if the selection of the staple mode is received. The image forming control unit 16 described below transmits information related to the post processing received by the control panel 11 to a post-processing control unit 25.
The scanner unit 12 reads image information of a copy object as brightness and darkness of light.
The printer unit 13 forms an output image (hereinafter, referred to as “toner image”) by a developer such as a toner on the basis of the image information which is received from the scanner unit 12 or an external device. The printer unit 13 transfers the toner image to the surface of the sheet S. The printer unit 13 heats and presses the toner image of the surface of the sheet S to fix the toner image to the sheet S. The printer unit 13 sends the sheet S with the toner image fixed thereto to the sheet conveyance unit 15.
The sheet supply unit 14 supplies the sheet S one by one to the printer unit 13 in synchronization with the timing when the printer unit 13 forms the toner image. The sheet supply unit 14 includes a plurality of sheet cassettes. The plurality of sheet cassettes store the sheets S of the size and type which are set in advance. The sheet cassette includes a pickup roller. The pickup roller takes out the sheet S one by one from the sheet cassette and sends the sheet to the printer unit 13.
The sheet conveyance unit 15 conveys the sheet S received from the printer unit 13 to the sheet processing device 3.
As illustrated in
The CPU 91 serves as the image forming control unit (control unit) 16 when the program stored in the memory 92 and the auxiliary memory device 93 is executed. The image forming control unit 16 controls various types of operations of the units of the image forming device 2 and the sheet processing device 3.
The auxiliary memory device 93 includes a storage device such as a magnetic hard disk device and a semiconductor memory device. The auxiliary memory device 93 stores information.
The communication unit 19 is configured to include a communication interface to be connected to an external device. The communication unit 19 communicates with an external device through the communication interface.
The sheet processing device 3 will be described.
The conveyance unit 24 supplies the sheet S supplied from the image forming device 2 to the standby unit 21.
The standby unit 21 includes a standby tray 41. The standby tray 41 includes a pair of tray members. The pair of tray members moves in an opposite direction to each other along the Y direction. The pair of tray members approaches to each other and supports the sheet S to the upper surface if the sheet S is set in standby in the standby tray 41. The pair of tray members moves in a direction away from each other if the sheet S falls down from the standby tray 41 toward the processing unit 22 to release the supporting of the sheet S.
The processing unit 22 includes a process tray 51, a pair of horizontal alignment plates 52, a stapler 55, an ejector 56, a bundle pawl 57, and conveyance rollers 59a and 59b.
The process tray 51 is formed in a plate shape. The process tray 51 is disposed in the −Z direction of the standby tray 41 in parallel to the standby tray 41. The upper surface of the process tray 51 is inclined to the lower direction from the +X side to the −X side.
The pair of horizontal alignment plates 52 moves in the opposite direction to each other along the Y direction. The pair of horizontal alignment plates 52 approaches each other to pinch the sheet S from both sides in the Y direction so as to horizontally align the sheet S in the Y direction. The pair of horizontal alignment plates 52 moves in a direction away from each other when discharging the sheet S from the process tray 51.
The stapler 55 is disposed in a −X direction of the process tray 51. The stapler 55 performs the stapling (binding) to a bundle of the plurality of the sheets S.
As illustrated in
The ejector 56 is formed in a hook shape when viewed from the Y direction as illustrated in
The bundle pawl 57 presses and moves the sheet S of the process tray 51 in the +X direction. The bundle pawl 57 is formed in a hook shape when viewed from the Y direction. The bundle pawl 57 is fixed to a bundle pawl belt 58. The bundle pawl belt 58 is suspended on a pair of belt rollers 58a and 58b which are separately disposed in the X direction. The bundle pawl 57 moves from the lower surface side to the upper surface side of the process tray 51 as the bundle pawl belt 58 rotates. The bundle pawl 57 receives the sheet S from the ejector 56 in the upper surface side of the process tray 51. The bundle pawl 57 presses the sheet S in the +X direction, and discharges the sheet from a sheet discharging port 23a.
The first conveyance roller 59a is disposed to overlap the first belt roller 58a when viewed from the Y direction. The second conveyance roller 59b is disposed to be overlapped with the second belt roller 58b when viewed from the Y direction.
The conveyance rollers 59a and 59b serve as vertical alignment rollers. The conveyance rollers 59a and 59b rotate in a clockwise direction in
The conveyance rollers 59a and 59b convey the sheet S in the +X direction by rotating in a counterclockwise direction in
The discharge unit 23 includes the sheet discharging port 23a and a movable tray 23b. The sheet discharging port 23a is formed in the +X direction of the process tray 51. The movable tray 23b is disposed on the lower side in the vertical direction of the outside of the sheet discharging port 23a. The sheet S discharged from the sheet discharging port 23a is placed on the upper surface of the movable tray 23b. The movable tray 23b is movable in the upward and downward direction according to the amount of placed sheets S.
As illustrated in
The CPU 96 serves as the post-processing control unit 25 by performing the program stored in the memory 97 and the auxiliary memory device 98. The post-processing control unit 25 controls the operations of the units of the sheet processing device 3.
The auxiliary memory device 98 includes a storage device such as a magnetic hard disk device or a semiconductor memory device. The auxiliary memory device 98 stores information.
The communication unit 29 is configured to include a communication interface to be connected to an external device. The communication unit 29 communicates with an external device through the communication interface.
A first sensor 71 and a second sensor 72 will be described.
As illustrated in
The first sensor 71 outputs a first signal corresponding to a first distance D1 from the first sensor 71 to the object which is disposed at a first position P1 of a sheet placement region 51a of the upper surface of the process tray 51. The first sensor 71 is disposed on the upper side in the vertical direction of the first position P1 with respect to the upper surface of the process tray 51.
The sheet placement region 51a is a region where the sheet S to be stapled is always placed on the upper surface of the process tray 51. Various sizes of the sheets S are placed on the upper surface of the process tray 51. In the sheet placement region 51a, the sheet S to be stapled is always placed regardless of the size of the sheet S. In other words, the sheet S is placed always in the sheet placement region 51a even if the smallest size of the sheet S is supplied in the X direction and the Y direction.
The first position P1 is a position in the +X direction of the stapler 55, and near the stapler 55. A height H1 is a height from the upper surface of the process tray 51 to the first sensor 71. The first distance D1 is matched with the height H1 when the object is not disposed at the first position P1. The first signal is an electrical signal.
The second sensor 72 outputs the second signal corresponding to a second distance D2 from the second sensor 72 to the object which is disposed at a second position P2 of the sheet placement region 51a of the upper surface of the process tray 51. The second sensor 72 is disposed on the upper side in the vertical direction of the second position P2 with respect to the upper surface of the process tray 51.
The second position P2 is a position in the +X direction of the first position P1, and near the sheet discharging port 23a. A height H2 is a height from the upper surface of the process tray 51 to the second sensor 72. The second distance D2 is matched with the height H2 when the object is not disposed at the second position P2. The second signal is an electrical signal.
The first sensor 71 and the second sensor 72 are disposed to almost the same height from the upper surface of the process tray 51. In other words, the height H1 and the height H2 are almost the same.
The first sensor 71 is coupled to the stapler 55 through a first coupling member 75. As illustrated in
The second sensor 72 is configured by a plurality of second distribution sensors 72a, 72b, 72c, and 72d. The plurality of second distribution sensors 72a, 72b, 72c, and 72d are disposed at the second position P2 in the X direction. The plurality of second distribution sensors 72a, 72b, 72c, and 72d are disposed in correspondence with a plurality of staple positions SPa, SPb, SPc, and SPd in the Y direction. In other words, the second A distribution sensor 72a is disposed at A position SPa in the Y direction. The second B distribution sensor 72b is disposed at B position SPb in the Y direction. The second C distribution sensor 72c is disposed at C position SPc in the Y direction. The second D distribution sensor 72d is disposed at D position SPd in the Y direction.
The first sensor 71 outputs the first signal corresponding to the first distance D1 to the object which is disposed at the first position P1. The object disposed at the first position P1 is the plurality of the sheets S. The first distance D1 is a distance from the first sensor 71 to the sheet S of the uppermost layer among the plurality of the sheets S. The first sensor 71 outputs the first signal corresponding to the first distance D1 to the image forming control unit 16.
The second sensor 72 outputs the second signal corresponding to the second distance D2 to the object which is disposed at the second position P2. The object disposed at the second position P2 is the plurality of the sheets S. The second distance D2 is a distance from the second sensor 72 to the sheet S of the uppermost layer among the plurality of the sheets S. The second sensor 72 outputs the second signal corresponding to the second distance D2 to the image forming control unit 16.
The image forming control unit 16 controls the stapling using the first signal and the second signal. The image forming control unit 16 calculates the first distance D1 from the first signal, calculates the second distance D2 from the second signal, and compares the first distance D1 and the second distance D2. As described above, the first sensor 71 and the second sensor 72 are disposed at the same height from the upper surface of the process tray 51. At the first position P1 and the second position P2, the thickness in the Z direction of the plurality of the sheets S is equal. Therefore, the first distance D1 and the second distance D2 are equal if the sheet S is disposed in the process tray 51. The image forming control unit 16 determines that the sheet S is disposed in the process tray 51 if the first distance D1 and the second distance D2 are equal. Specifically, the image forming control unit 16 determines that the sheet S is disposed in the process tray 51 if the difference between the first distance D1 and the second distance D2 is less than a predetermined value. At this time, the image forming control unit 16 performs the stapling. Specifically, the image forming control unit 16 outputs an execution signal of the stapling to the stapler 55. With this configuration, the stapling is performed on the sheet S.
The first sensor 71 outputs the first signal corresponding to the first distance D1 to the object which is disposed at the first position P1. The object disposed at the first position P1 is the tip end of the foreign matter F. The first distance D1 is a distance from the first sensor 71 to the tip end of the foreign matter F. The first sensor 71 outputs the first signal corresponding to the first distance D1 to the image forming control unit 16.
The second sensor 72 outputs the second signal corresponding to the second distance D2 to the object which is disposed at the second position P2. The object disposed at the second position P2 is the root portion of the foreign matter F. The second distance D2 is a distance from the second sensor 72 to the root portion of the foreign matter F. The second sensor 72 outputs the second signal corresponding to the second distance D2 to the image forming control unit 16.
The image forming control unit 16 controls the stapling using the first signal and the second signal. The image forming control unit 16 compares the first distance D1 calculated from the first signal and the second distance D2 calculated from the second signal. The first distance D1 is greater than the second distance D2 if the foreign matter F is disposed in the process tray 51. The image forming control unit 16 determines that the foreign matter F is disposed in the process tray 51 if the first distance D1 and the second distance D2 are different. Specifically, the image forming control unit 16 determines that the foreign matter F is disposed in the process tray 51 if the difference between the first distance D1 and the second distance D2 is equal to or more than a predetermined value. At this time, the image forming control unit 16 stops the stapling. Specifically, the image forming control unit 16 outputs a stop signal of the stapling to the stapler 55. With this configuration, the stapling to the foreign matter F is avoided.
Further, the foreign matter F may be permeated in a state where the tip end of the foreign matter F floats in the Z direction from the upper surface of the process tray 51. In this case, the first distance D1 and the second distance D2 may be equal. However, the stapler 55 is disposed near the upper surface of the process tray 51 in the Z direction. Therefore, even when the stapling is performed, the stapling is not performed on the permeated foreign matter F. With this configuration, the stapling to the foreign matter F is avoided.
The control method of the sheet processing device will be described in detail.
The image forming control unit 16 receives the first signal and the second signal immediately before the stapling. The image forming control unit 16 detects the first distance D1 from the received first signal (ACT 11, first detection step). The image forming control unit 16 detects the second distance D2 from the received second signal (ACT 11, second detection step). The image forming control unit 16 compares the first distance D1 calculated from the first signal and the second distance D2 calculated from the second signal. The image forming control unit 16 determines whether the first distance D1 and the second distance D2 are different (ACT 12). If the determination of ACT 12 is “No”, the first distance D1 and the second distance D2 are equal. In this case, the image forming control unit 16 determines that the sheet S is disposed in the process tray 51. The image forming control unit 16 performs the stapling (ACT 22, stapling control step).
As described above, the image forming control unit 16 performs the determination of ACT 12 immediately before the stapling. If the foreign matter F is permeated to the process tray 51, the foreign matter F is disposed on the sheet S, or the sheet S is disposed on the foreign matter F. In either case, the first distance D1 is greater than the second distance D2. Then, if the determination of ACT 12 is “Yes”, the image forming control unit 16 determines that the foreign matter F is disposed in the process tray 51. The image forming control unit 16 stops the stapling (ACT 14, stapling control step). With this configuration, the stapling to the foreign matter F is avoided. In addition, the image forming control unit 16 stops the operation of the image forming device 2. With this configuration, it is suppressed that the sheet is jammed due to the permeation of the foreign matter F.
The image forming control unit 16 displays information on the control panel 11 (see
The image forming control unit 16 displays information 83 which is used to restart the normal operation (stapling). For example, “Do you want to restart the job?” is displayed as information 83 which is used to restart. The image forming control unit 16 receives a user's instruction related to the restarting of the normal operation. For example, the image forming control unit 16 displays a button 84 of “YES” and a button 85 of “NO” following to information 83 which is used to restart. The display unit 11d includes the touch panel. When the user presses the button 84 of “YES”, a user's instruction to restart the normal operation is input. When the user presses the button 85 of “NO”, a user's instruction to stop the normal operation is input. The user's instruction is transmitted to the image forming control unit 16.
The image forming control unit 16 restarts the stapling when the restart instruction of the stapling is received after the stapling is stopped using the first signal and the second signal. The image forming control unit 16 determines whether the restart instruction of the stapling is received (ACT 18). If the stop instruction of the stapling is received, the determination of ACT 18 is “No”. In this case, the image forming control unit 16 ends without restarting the stapling. If the restart instruction of the stapling is received, the determination of ACT 18 is “Yes”, and the procedure proceeds to ACT 20.
The image forming control unit 16 restarts the stapling using the first signal and the second signal after the restart instruction of the stapling is received. The image forming control unit 16 receives the first signal and the second signal. The image forming control unit 16 detects the first distance D1 from the received first signal (ACT 19, first detection step). The image forming control unit 16 detects the second distance D2 from the received second signal (ACT 19, second detection step). The image forming control unit 16 compares the first distance D1 calculated from the first signal and the second distance D2 calculated from the second signal. The image forming control unit 16 determines whether the first distance D1 and the second distance D2 are equal (ACT 20). If the determination of ACT 20 is “No”, the image forming control unit 16 determines that the foreign matter F is disposed in the process tray 51. In other words, the image forming control unit 16 determines that the foreign matter F is not taken off from the process tray 51. In this case, the image forming control unit 16 repeatedly performs the following information displaying (ACT 16) to the control panel 11.
As described above, if the foreign matter F is permeated to the process tray 51, the foreign matter F is disposed on the sheet S, or the sheet S is disposed on the foreign matter F. When the foreign matter F is taken off from the process tray 51, only the sheet S is left in the upper surface of the process tray 51. At this time, the first distance D1 and the second distance D2 are equal. Then, if the determination of ACT 20 is “Yes”, the image forming control unit 16 determines that the foreign matter F is taken off from the process tray 51. The image forming control unit 16 restarts the stapling (ACT 22, stapling control step). With this configuration, the stapling is performed on the sheet S.
The image forming control unit 16 starts the operation of the image forming device 2 using the first signal and the second signal. The image forming control unit 16 performs the determination of ACT 20 using the first signal and the second signal, and restarts the stapling. Therefore, the image forming control unit 16 restarts the operation of the stopped image forming device 2. The image forming control unit 16 may use the first signal and the second signal not only when the operation of the image forming device 2 restarts but also when the operation of the image forming device 2 is started.
Therefore, the process of the control method of the sheet processing device ends.
As described above, the image forming system 1 of the embodiment includes the image forming device 2, the stapler 55, the process tray 51, the first sensor 71, the second sensor 72, and the image forming control unit 16. The image forming device 2 forms an image on the sheet S. The stapler 55 performs the stapling on the sheet S. The process tray 51 places the sheet S to be stapled on the upper surface. The first sensor 71 is disposed on the upper side of the process tray 51. The first sensor 71 outputs the first signal corresponding to the first distance D1 to the object disposed at the first position P1 of the sheet placement region 51a of the upper surface of the process tray 51 or the first thickness of the object which is disposed at the first position P1. The second sensor 72 is disposed on the upper side of the process tray 51. The second sensor 72 outputs the second signal corresponding to the second distance D2 to the object disposed at the second position P2 on the downstream side in the sheet discharge direction from the first position P1 of the sheet placement region 51a of the upper surface of the process tray 51 or the second thickness of the object which is disposed at the second position P2. The image forming control unit 16 is provided in the image forming device 2. The image forming control unit 16 controls the stapling using the first signal and the second signal.
Using the first signal and the second signal, a case where the sheet S is disposed in the process tray 51 and a case where the foreign matter F is disposed in the process tray 51 are distinguished. The image forming control unit 16 performs the stapling if the sheet S is disposed in the process tray 51. The image forming control unit 16 stops the stapling if the foreign matter F is disposed in the process tray 51. With this configuration, the stapling for the foreign matter F is suppressed.
The first sensor 71 is disposed on the upper side in the vertical direction of the first position P1 with respect to the upper surface of the process tray 51. The second sensor 72 is disposed on the upper side in the vertical direction of the second position P2 with respect to the upper surface of the process tray 51. The first sensor 71 and the second sensor 72 are disposed at the same height from the upper surface of the process tray.
The image forming control unit 16 stops the stapling if the first signal and the second signal are different. The first sensor 71 outputs the first signal corresponding to the first distance D1. The second sensor 72 outputs the second signal corresponding to the second distance D2. The image forming control unit 16 stops stapling if the first distance D1 indicated by the first signal and the second distance D2 indicated by the second signal are different.
With this configuration, if the sheet S is disposed in the process tray 51, the first signal (the first distance D1) and the second signal (the second distance D2) are equal. If the foreign matter F is disposed in the process tray 51, the first signal (the first distance D1) and the second signal (the second distance D2) are different. Therefore, the sheet S and the foreign matter F are easily discriminated, and the stapling for the foreign matter F is suppressed.
The first sensor 71 is formed to be movable in the Y direction intersecting the X direction together with the stapler 55. The second sensor 72 includes the plurality of second distribution sensors 72a, 72b, 72c, and 72d which are arranged along the Y direction intersecting the X direction.
The stapler 55 staples at the plurality of predetermined staple positions SP in the Y direction. According to the above configuration, the first sensor 71 and the second sensor 72 are disposed at the staple position SP where the stapler 55 staples. Therefore, the sheet S and the foreign matter F are discriminated at the staple position SP where the stapler 55 staples.
Since the first sensor 71 is formed to be movable together with the stapler 55, the plurality of first sensors 71 are not needed to be disposed. Since the first sensor 71 is disposed near the stapler 55, the first sensor 71 is easily formed to be movable together with the stapler 55. On the other hand, the second sensor 72 is disposed to be separated from the stapler 55. Since the second sensor 72 includes the plurality of second distribution sensors 72a, 72b, 72c, and 72d, there is no need to form the second sensor 72 to be movable together with the stapler 55.
The image forming control unit 16 controls the stapling using the first signal and the second signal immediately before the stapling.
With this configuration, an unnecessary stopping of the stapling is suppressed.
After the stapling is stopped using the first signal and the second signal, the image forming control unit 16 restarts the stapling after the restart instruction of the stapling is received.
The image forming control unit 16 stops the stapling when the foreign matter F is detected using the first signal and the second signal. The restarting of the stapling is instructed after the foreign matter F is taken off. The stapling for the foreign matter F is suppressed by restarting the stapling after the restart instruction is received.
The image forming control unit 16 restarts the stapling using the first signal and the second signal after the restart instruction of the stapling is received.
There is a possibility to instruct the restarting of the stapling before the foreign matter F is taken off. The image forming control unit 16 restarts the stapling if the foreign matter F is not detected using the first signal and the second signal. With this configuration, the stapling for the foreign matter F is suppressed.
The sheet processing device 3 of the embodiment includes the stapler 55, the process tray 51, the first sensor 71, and the second sensor 72. The stapler 55 performs the stapling on the sheet S. The process tray 51 places the sheet S to be stapled on the upper surface. The first sensor 71 is disposed on the upper side of the process tray 51. The first sensor 71 outputs the first signal corresponding to the first distance D1 to the object disposed at the first position P1 of the sheet placement region 51a of the upper surface of the process tray 51 or the first thickness of the object which is disposed at the first position P1. The second sensor 72 is disposed on the upper side of the process tray 51. The second sensor 72 outputs the second signal corresponding to the second distance D2 to the object disposed at the second position P2 on the downstream side in the sheet discharge direction from the first position P1 of the sheet placement region 51a of the upper surface of the process tray 51 or the second thickness of the object which is disposed at the second position P2. The sheet processing device 3 transmits the first signal and the second signal to the image forming device 2. The sheet processing device 3 operates on the basis of the content of the signal received from the image forming device 2.
With this configuration, the stapling for the foreign matter F is suppressed.
A control method of the sheet processing device of the embodiment includes the first detection step, the second detection step, and the stapling control step. In the first detection step, the first distance D1 or the first thickness are detected. The first distance D1 is a distance to the object which is disposed at the first position P1 of the sheet placement region 51a of the upper surface of the process tray 51. The first thickness is the thickness of the object which is disposed at the first position P1. The process tray 51 places the sheet S to be stapled. In the second detection step, the second distance D2 or the second thickness is detected. The second distance D2 is a distance to the object which is disposed at the second position P2 of the sheet placement region 51a of the upper surface of the process tray 51. The second thickness is the thickness of the object which is disposed at the second position P2. The second position P2 is a position on the downstream side in the sheet discharge direction from the first position P1. In the stapling control step, the stapling is controlled on the basis of the results of the first detection step and the second detection step.
With this configuration, the stapling for the foreign matter F is suppressed.
A sheet processing device of a first modification of the embodiment will be described.
The second sensor 72 is coupled to the first sensor 71 through a second coupling member 76. As described above, the first sensor 71 is coupled to the stapler 55 through the first coupling member 75. With this configuration, the second sensor 72 is formed to be movable in the Y direction together with the first sensor 71 and the stapler 55. The first sensor 71 and the second sensor 72 are movable to A position SPa, B position SPb, C position SPc, and D position SPd along the Y direction.
In this way, the second sensor 72 is formed to be movable in the Y direction intersecting the X direction together with the stapler 55. With this configuration, the plurality of second distribution sensors are not necessarily disposed.
Therefore, the cost of the sheet processing device 103 is reduced.
A sheet processing device of a second modification of the embodiment will be described.
The first sensor 71 is configured by the plurality of first distribution sensors 71a, 71b, 71c, and 71d. The plurality of first distribution sensors 71a, 71b, 71c, and 71d are disposed at the first position P1 in the X direction. The plurality of first distribution sensors 71a, 71b, 71c, and 71d are disposed in correspondence with the plurality of staple positions SPa, SPb, SPc, and SPd in the Y direction. In other words, the first A distribution sensor 71a is disposed at A position SPa in the Y direction. The first B distribution sensor 71b is disposed at B position SPb in the Y direction. The first C distribution sensor 71c is disposed at C position SPc in the Y direction. The first D distribution sensor 71d is disposed at D position SPd in the Y direction.
In this way, the first sensor 71 includes the plurality of first distribution sensors 71a, 71b, 71c, and 71d which are disposed along the Y direction intersecting the X direction. With this configuration, the first sensor 71 does not move in the Y direction, so that interference between the first sensor 71 and the components of the sheet processing device 3 is avoided.
In the above-described embodiment, the first sensor 71 and the second sensor 72 are disposed at the same height from the upper surface of the process tray 51. With this regard, the first sensor 71 and the second sensor 72 may be disposed at different heights from the upper surface of the process tray 51. At this time, the image forming control unit 16 compares the first distance D1 and the second distance D2 in consideration of the difference in height between the first sensor 71 and the second sensor 72.
In the above-described embodiment, the first sensor 71 is disposed on the upper side in the vertical direction of the first position P1 with respect to the upper surface of the process tray. In other words, a straight line connecting the first sensor 71 and the first position P1 is disposed to be perpendicular to the upper surface of the process tray. With this regard, the straight line connecting the first sensor 71 and the first position P1 may be disposed to be inclined to the upper surface of the process tray. At this time, the image forming control unit 16 compares the first distance D1 and the second distance D2 in consideration with an inclined angle and an inclined direction of the straight line connecting the first sensor 71 and the first position P1.
The configuration of the second sensor 72 is also similar.
In the above-described embodiment, the image forming control unit 16 compares the first distance D1 calculated from the first signal and the second distance D2 calculated from the second signal to control the stapling. With this regard, the image forming control unit 16 may compare another value calculated from the first signal and another value calculated from the second signal. In addition, the image forming control unit 16 may compare the first signal itself and the second signal itself.
In the above-described embodiment, the first sensor 71 and the second sensor 72 output the first signal and the second signal to the image forming control unit 16. With this regard, the first sensor 71 and the second sensor 72 may output the first signal and the second signal to the post-processing control unit 25. In this case, the post-processing control unit 25 transmits the first signal and the second signal to the image forming control unit 16. In addition, the post-processing control unit 25 may control the stapling by itself using the first signal and the second signal.
In the above-described embodiment, the image forming control unit 16 controls the stapling. With this regard, the image forming control unit 16 may control the stapling through the post-processing control unit 25.
In the above-described embodiment, the plurality of second distribution sensors 72a, 72b, 72c, and 72d are disposed in correspondence with the plurality of staple positions SPa, SPb, SPc, and SPd. At this time, the distance to the object existing at one staple position SP is detected by one second sensor 72. With this regard, the distance to the object existing at the plurality of staple positions SP may be detected by one second sensor 72.
According to at least one of the embodiments described above, the first sensor 71, the second sensor 72, and the image forming control unit 16 are provided. The first sensor 71 outputs the first signal corresponding to the first distance D1 to the object which is disposed at the first position P1 of the sheet placement region 51a of the upper surface of the process tray 51. The second sensor 72 outputs the second signal corresponding to the second distance D2 to the object which is disposed at the second position P2 on the downstream side in the sheet discharge direction from the first position P1 of the sheet placement region 51a of the upper surface of the process tray 51. The image forming control unit 16 controls the stapling using the first signal and the second signal. With this configuration, it is possible to suppress the stapling for the foreign matter F.
While certain embodiments have been described these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms: furthermore various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and there equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the invention.
This application is a Continuation of U.S. application Ser. No. 16/283,957, filed on Feb. 25, 2019, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | 16283957 | Feb 2019 | US |
Child | 17191753 | US |