1. Field of the Invention
The present invention relates to sheet discharge control performed by a sheet conveying apparatus.
2. Description of the Related Art
Post-processing apparatuses are apparatuses for aligning, sorting, and stapling a plurality of sheets output from an image forming apparatus. Japanese Patent Laid-Open No. 2005-206335 discloses an alignment plate that moves in a direction orthogonal to the direction in which sheets are discharged, in order to align a plurality of sheets discharged on a tray. In particular, the alignment plate abuts on a sheet bundle for a longer time than normal when a sheet stacked on the tray is the final sheet, thus improving alignment of the sheet bundle. Japanese Patent Laid-Open No. 2006-206331 proposes an apparatus for improving productivity of post-processing performed on preceding sheets by superimposing several succeeding sheets on the preceding sheets.
Superimposing a plurality of sheets one above another and discharging them together, however, may create a situation in which preceding sheets already stacked on the tray are pushed out by a plurality of succeeding sheets due to the weight of the succeeding sheets. This may result in disturbance of sheet alignment.
The present invention reduces disturbance of sheet alignment that can happen when a sheet bundle of a plurality of succeeding sheets is discharged on preceding sheets.
An embodiment of the present invention provides a sheet conveying apparatus comprising the following elements. A discharge unit is configured to discharge a sheet. A stacking unit is configured to stack a sheet discharged from the discharge unit. A pressure unit is configured to press a preceding sheet stacked on the stacking unit against the stacking unit when a sheet bundle of a plurality of succeeding sheets is discharged on the preceding sheet.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Overall Configuration
Now, a principle part of an image forming system will be described with reference to
Block Diagram of Overall System
As illustrated in
The image reader control unit 921 controls the image reader 20 and transfers an image signal output by the image reader 20 to the image signal control unit 922. The image signal control unit 922 converts an analog image signal received from the image reader 20 into a digital signal, converts this digital signal into a video signal, and outputs the video signal to the printer control unit 931. The image signal control unit 922 also performs various types of processing on a digital image signal that is input from a computer 905 via the external I/F 904, converts this digital image signal into a video signal, and outputs the video signal to the printer control unit 931. These processing activities performed by the image signal control unit 922 are controlled by the CPU circuit unit 900. The printer control unit 931 controls the printer 30 based on an input video signal and forms an image on recording paper. The finisher control unit 951 is mounted on the finisher 50 and exchanges information with the CPU circuit unit 900 to perform overall drive control of the finisher 50. The UI control unit 941 allows information to be exchanged between the UI unit 40 and the CPU circuit unit 900. The term “UI” as used herein is an abbreviation for User Interface. The UI control unit 941 outputs a key signal corresponding to each key operation performed on the UI unit 40 to the CPU circuit unit 900 and displays corresponding information on the UI unit 40, based on a signal from the CPU circuit unit 900.
UI unit
Upon detecting that the finishing key 405 has been operated, the CPU 901 causes the UI control unit 941 to display a setting screen as illustrated in
Finisher
Now, the finisher 50 will be described with reference to
The finisher 50 takes sheets discharged from the image forming apparatus 10 into a conveyance path 520 with a conveying roller pair 511. The sheets taken in by the conveying roller pair 511 are conveyed further downstream by conveying roller pairs 512 and 513. Passage of such sheets is detected by each of conveyance sensors 570, 571, and 572 provided on the conveyance path 520.
The conveying roller pairs 512 are provided in a shift unit 580 together with the conveyance sensor 571. The shift unit 580 is movable along the width of a sheet (sheet width direction) that is orthogonal to the conveying direction by a shift motor M4 illustrated in
A flapper 540 is disposed between the conveying roller pair 513 and a conveying roller pair 514. The flapper 540 guides a sheet that is reversely conveyed by the conveying roller pair 514 to a buffer path 524 that serves as a buffer unit. The buffer path 524 is provided with a conveying roller pair 519 for feeding a sheet, which is held in staying, again to the main conveyance path. The conveying roller pair 514, the flapper 540, and the buffer path 524 are disposed on the conveyance path for conveying sheets and configured to hold at least one sheet in staying and feed that sheet again to the conveyance path, thereby serving as a staying unit that forms a sheet bundle by superimposing a sheet held in staying and a succeeding sheet.
Another flapper 541 is disposed between the conveying roller pair 514 and a conveying roller pair 515. The flapper 541 switches to which path, namely an upper discharge path 522 or a lower discharge path 523, a sheet is conveyed. When the flapper 541 switches to the upper discharge path 522, a sheet is guided to the upper discharge path 522 by the conveying roller pair 514, which is driven by a buffer motor M2 illustrated in
When the flapper 541 switches to the lower discharge path 523, a sheet is guided to the lower discharge path 523 by the conveying roller pair 514. This sheet is then guided to a processing tray 630 by conveying roller pairs 516, 517, and 518, which are driven by the discharge motor M3. The passage of such a sheet is detected by conveyance sensors 575 and 576 provided on the lower discharge path 523.
The sheet guided to the lower discharge path 523 is discharged to a stacking tray 700, either passing through or bypassing the processing tray 630 depending on the mode selected by the operator. When the operator has selected “Stapling,” the sheet is discharged first to the processing tray 630 and then from the processing tray 630 to the stacking tray 700. When “Stapling” is not selected, the sheet is discharged to the stacking tray 700 by a bundle discharge roller pair 680 without being stacked on the processing tray 630, the bundle discharge roller pair 680 being driven by a bundle discharge motor M5 illustrated in
A sheet discharged to the processing tray 630 is drawn back to the opposite side of the sheet discharge direction by a knurling belt 661 and a paddle 660, the knurling belt 661 being driven in synchronization with the conveying roller pair 518, and the paddle 660 being driven by a paddle motor M7 illustrated in
On the stacking tray 700, an alignment plate 710 is disposed to align sheets in the width direction orthogonal to the sheet discharge direction. The alignment plate 710 is constituted by a pair of alignment plates that are movable in the width direction. Note that an alignment plate 711 having a similar configuration is also disposed on the stacking tray 701.
Block Diagram of Finisher
Now, a configuration of the finisher control unit 951 that controls the driving of the finisher 50 will be described with reference to
An inlet motor M1 drives the conveying roller pairs 511, 512, and 513. The buffer motor M2 drives the conveying roller pairs 514 and 519. The discharge motor M3 drives the conveying roller pairs 515, 516, 517, and 518. The shift motor M4 drives the shift unit 580.
The processing tray 630 will now be described. The bundle discharge motor M5 drives the bundle discharge roller pair 680. The bundle pressing motor M6 drives the bundle pressing member 690. The paddle motor M7 drives the paddle 660. The alignment motor M8 drives the alignment members 641. A stapling motor M9 drives the stapler 601 that binds a sheet bundle. A stapler moving motor M10 moves the stapler 601 in the direction orthogonal to the conveying direction along the outer periphery of the processing tray 630. This changes the staple binding position. The CPU 952 receives detection signals from the conveyance sensors 570 to 576 to detect the passage of a sheet.
Tray lifting motors M11 and M12 lift the stacking trays 700 and 701 up and down. Tray alignment motors M13 and M14 move the alignment plates 710 and 711. The CPU 952 is further provided with the sheet-surface detection sensors 720 and 721 to detect whether or not sheets are stacked on the stacking trays 700 and 701. A solenoid SL1 drives the flapper 540, and a solenoid SL2 drives the flapper 541.
Buffering Operation
The term “buffering operation” as used herein refers to processing for causing a sheet discharged from the image forming apparatus 10 to be temporarily held in staying on the conveyance path (buffer path 224), superimposing that sheet on a succeeding sheet, and then conveying these sheets. While post-processing (such as the operation of aligning sheets on a stacking tray) is being performed on a sheet bundle of preceding sheets, succeeding sheets cannot be conveyed to the trays. Even in the case where a sheet is not discharged to the processing tray 630, time is still needed to, for example, move the alignment plate 710 when the alignment position in the width direction is to be changed for alignment of sheets discharged to the stacking tray 700 in the width direction using the alignment plate 710. For these reasons, buffering succeeding sheets is necessary. Also, discharging thin paper having a small basis weight increases the amount of time from when a sheet is discharged from the bundle discharge roller pair 680 to when the sheet falls on the stacking tray 700, as compared with the case of discharging plain paper. Thus, when the alignment plate 710 performs alignment of thin paper with the same timing as the case of plain paper, appropriate alignment may not be performed because the alignment may be performed before the stacking of sheets is completed. Such an increase in the amount of the falling time of sheets can be prevented by superimposing two pieces of thin paper and discharging them together. Thus, buffering is also performed when thin paper is discharged.
Processing for Setting Buffer Mode
Processing for setting the buffer mode of a sheet, performed by the CPU 952 of the finisher 50, will now be described with reference to the flowchart in
In step S601, the CPU 952 substitutes the information included in a sheet transfer start notification regarding a sheet N received from the CPU 901 into the sheet information 750 and stores the sheet information 750 in the RAM 954. The sheet N is a sheet to be processed at that point in time.
In step S602, the CPU 952 references job information in the sheet information 750 to determine whether or not the sheet N is the first sheet in a job. When the sheet N is the first sheet in the job, the procedure proceeds to step S607.
In step S607, the CPU 952 sets the buffer mode of the sheet N to “Pass” and stores information regarding the buffer mode into the sheet information stored in the RAM 954, and then this setting processing ends. The buffer mode of “Pass” means that the sheet N is to be conveyed without being retained on the buffer path 224 or being superimposed on a sheet retained on the buffer path. When the sheet N is not the first sheet in the job, on the other hand, the procedure proceeds to step S603.
In step S603, the CPU 952 references copy set information in the sheet information 750 to determine whether or not the sheet N is the first sheet in a “one copy set” and whether or not the sheet N is the final sheet in the one copy set. When the sheet N is the first sheet in the one copy set and is not the final sheet in the one copy set, the procedure proceeds to step S604. For a one copy set constituted by three sheets, for example, the first sheet is determined as being the first sheet in the one copy set and is not the final sheet in the one copy set.
In step S604, the CPU 952 sets the buffer mode of the sheet N to “Buffer” and stores the sheet information 750 in the RAM 954, and then this setting processing ends. The buffer mode of “Buffer” means that the sheet N is to be retained on the buffer path 224. Specific conveyance processing performed on a sheet having a buffer mode of “Buffer” will be described later. When the sheet N is not the first sheet in the one copy set, the procedure proceeds to step S605. Similarly, when the sheet N is the final sheet in the one copy set, the procedure proceeds to step S605. For a one copy set constituted by a single sheet, for example, the first sheet is the first sheet in the one copy set and is also the final sheet in the one copy set. In this case, the procedure proceeds to step S605. For a one copy set constituted by three sheets, for example, the second sheet is determined as being neither the first sheet in the one copy set nor the final sheet in the one copy set and accordingly the procedure proceeds to step S605. The third sheet in this case is not the first sheet in the one copy set and thus the procedure proceeds to step S605.
In step S605, the CPU 952 determines whether or not the buffer mode of a sheet N-1, which is the sheet previous to the sheet N, is “Buffer”. When the buffer mode of the sheet N-1 is “Buffer”, the procedure proceeds to step S606.
In step S606, the CPU 952 creates sheet information 750 indicating that the buffer mode of the sheet N has been set to “Final Sheet” and stores the sheet information 750 in the RAM 954, and then this setting processing ends. The buffer mode of “Final Sheet” means that the sheet N is to be superimposed on a sheet retained on the buffer path 224.
When the buffer mode of the sheet N-1 is other than “Buffer,” on the other hand, the procedure proceeds to step S607. The buffer mode other than “Buffer” is, for example, “Final Sheet” or “Pass”.
In step S607, the CPU 952 sets the buffer mode of the sheet N to “Pass” and stores the sheet information 750 in the RAM 954, and then this setting processing ends.
Finisher Operation in Each Buffer Mode
The operation of the finisher 50 in each buffer mode will now be described with reference to
Then, as illustrated in
Next, the movement of the finisher 50 when a sheet P2 having a buffer mode of “Final Sheet” is conveyed will be described. The CPU 952 drives the solenoid SL1 to switch the flapper 540 such that the sheet P2 is guided to the discharge path 521. After a predetermined period of time has elapsed since the conveyance sensor 572 has detected the leading edge of the sheet P2 discharged from the image forming apparatus 10, the CPU 952 drives the buffer motor M2 to rotate the conveying roller pairs 514 and 519, thereby starting the conveyance of the sheet P1 that is held in staying on the buffer path 524. The sheet P1 is thus superimposed on the sheet P2 on the conveyance path as illustrated in
This superimposition eliminates the need for the image forming apparatus 10 to delay the conveyance of a succeeding sheet even while post-processing is being performed on a sheet bundle on the processing tray 630. Of course, the image forming apparatus 10 does not need to suspend image forming.
Lastly, the movement of the finisher 50 when a sheet P3 having a buffer mode of “Pass” is conveyed will be described with reference to
Switching Control of Driving of Bundle Pressing Member
Providing a pressure unit is a feature of the present invention. The pressure unit is configured to press preceding sheets stacked on the stacking tray 700 against the stacking tray 700 when a sheet bundle of a plurality of succeeding sheets is discharged on the preceding sheets. The reason why the provision of the pressure unit is advantageous will now be described with reference to
If a sheet bundle of succeeding sheets P2 and P3 is discharged on the preceding sheets P1 as illustrated in
Now, an operation of driving the bundle pressing member 690 to control the switching of whether or not to press sheets on the stacking tray 700 will be described with reference to
In step S1001, the CPU 952 determines whether or not a sheet transfer start notification has been received from the CPU 901 of the circuit unit 900. Upon receipt of a start notification, the procedure proceeds to step S1002.
In step S1002, the CPU 952 sets the buffer mode of a sheet N. This setting processing corresponds to steps S601 to S607 in
In step S1003, the CPU 952 references the sheet information 750 stored in the RAM 954 to specify the buffer mode of the sheet N, and determines whether or not the buffer mode is “Buffer”. When the buffer mode is “Buffer,” the CPU 952 performs control for holding the sheet N in waiting and staying on the buffer path 524 as illustrated in
In step S1004, the CPU 952 waits until the conveyance sensor 575 is turned on. The conveyance sensor 575 is in the ON state while a sheet is passing through the conveyance sensor 575. When the conveyance sensor 575 is turned on, the procedure proceeds to step S1005.
In step S1005, the CPU 952 determines whether or the buffer mode of the sheet N is “Final Sheet”. When the buffer mode is “Final Sheet”, the procedure proceeds to step S1006. At this time, the CPU 952 performs control for superimposing a succeeding sheet on a preceding sheet and conveying them as illustrated in
In step S1006, the CPU 952 drives the bundle pressing motor M6 to move the bundle pressing member 690 to a pressing position because the sheet N is superimposed on a sheet N-1 and discharged together. The movement of the bundle pressing member 690 may be started at such a time that allows the movement of the bundle pressing member 690 to be completed during an interval from when the leading edge of the sheet N (sheet N-1) is detected by the conveyance sensor 575 to when that sheet reaches the bundle discharge roller pair 680. As illustrated in
In step S1007, the CPU 952 determines whether or not the conveyance sensor 575 is turned off (whether or not a sheet has passed through the conveyance sensor 575). When the conveyance sensor 575 is turned off, the procedure proceeds to step S1008.
In step S1008, the CPU 952 determines whether or not a predetermined period of time has elapsed since the conveyance sensor 575 is turned off. As illustrated in
In step S1009, the CPU 952 drives the bundle pressing motor M6 to move the bundle pressing member 690 to a spaced position. As illustrated in
In step S1010, the CPU 952 determines whether or not the sheet N is the final sheet in the job, based on the job information included in the sheet information 750. When the sheet N is the final sheet in the job, the CPU 952 ends the processing shown in this flowchart. When the sheet N is not the final sheet in the job, the procedure returns to step S1001, in which the CPU 952 waits for a sheet transfer start notification for the next sheet.
As described above, by the bundle pressing member 690 pressing already-stacked preceding sheets when a plurality of superimposed succeeding sheets is discharged on the stacking tray 700, it is possible to suppress a phenomenon in which the succeeding sheets push out the already-stacked preceding sheets. This reduces disturbance in the alignment of sheets on the stacking tray 700. Although the present embodiment describes a case in which sheets bypass the processing tray 630, the bundle pressing member 690 may be operated in a similar manner even when sheets pass through the processing tray 630.
The description of the present embodiment is based on the assumption that a single sheet, which is held in staying on the buffer path 524, is superimposed on a succeeding sheet to form a sheet bundle and the sheet bundle of these two sheets is discharged. The number of sheets in a sheet bundle, however, may be two or more. A more generalized technical idea of the above description will be described with reference to
As illustrated in
In step S1202, the CPU 952 counts the number of sheets to be held in staying on the buffer path 524 by referencing the job information, increments the counter value by one, and calculates (counts) the number of sheets that forms a sheet bundle.
In step S1203, the CPU 952 determines whether or not a sheet bundle of at least a predetermined number of succeeding sheets is discharged on preceding sheets stacked on the stacking tray 700. This determination is made by comparing the number of sheets that constitute a sheet bundle with a predetermined number of sheets (threshold value). When a sheet bundle of at least a predetermined number of succeeding sheets is discharged on the preceding sheets stacked on the stacking tray 700, the procedure proceeds to step S1204.
In step S1204, the CPU 952 performs control such that the bundle pressing member 690 presses the preceding sheets. When a sheet bundle of less than the predetermined number of succeeding sheets is discharged, the CPU 952 skips step S1204 and performs control such that the bundle pressing member 690 does not press the preceding sheets.
Note that the CPU 952 may adjust the predetermined number of sheets according to paper type (plain paper, thick paper, or basis weight). This is because the pushing force varies depending on the material, thickness, and basis weight of paper. The relationship between paper type and a predetermined number of sheets may be obtained in advance by experiment or simulation and stored in the ROM 953 in the form of a table. This allows the CPU 952 to determine a predetermined number of sheets from information regarding paper type by simply referencing such a table.
In the present embodiment, at least one sheet is held in staying on the buffer path 524, which is provided on the conveyance path through which sheets are conveyed, and this staying sheet is superimposed on a succeeding sheet and fed again to the conveyance path, thus forming a sheet bundle of the staying sheet and the succeeding sheet. If such a sheet bundle is constituted by a predetermined number of sheets or more, the CPU 952 drives the bundle pressing member 690 such that the bundle pressing member 690 presses preceding sheets against the stacking tray 700. When a succeeding sheet bypasses the buffer path 524, the CPU 952 controls the bundle pressing member 690 such that the bundle pressing member 690 does not press preceding sheets against the stacking tray 700.
According to the present embodiment, the bundle pressing member 690 retracts to a position where it does not press preceding sheets as illustrated in
The bundle pressing member 690 is also disposed below the bundle discharge roller pair 680 in the vertical direction as illustrated in
Although the above description mainly focuses on a case of discharging sheets without passing through the processing tray 630, the present invention is also applicable to a case in which stapling processing is performed on a sheet bundle on the processing tray 630 and the stapled sheet bundle is discharged. Specifically, the alignment of sheets may be disturbed if a stapled sheet bundle is discharged on an unstapled sheet bundle that has already been stacked on the stacking tray 700. The CPU 952, which has detected such a situation, thus may move the bundle pressing member 690 by controlling the bundle pressing motor M6.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2012-104888, filed May 1, 2012 which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2012-104888 | May 2012 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5722650 | Yamamoto et al. | Mar 1998 | A |
5735515 | Hayashi et al. | Apr 1998 | A |
5769406 | Sato | Jun 1998 | A |
5778300 | Murakami et al. | Jul 1998 | A |
6085913 | Aiko et al. | Jul 2000 | A |
6374077 | Hirai et al. | Apr 2002 | B1 |
6412774 | Saito et al. | Jul 2002 | B1 |
6702279 | Adachi et al. | Mar 2004 | B2 |
7021616 | Mizuta et al. | Apr 2006 | B2 |
7413177 | Mori et al. | Aug 2008 | B2 |
7566051 | Kodama et al. | Jul 2009 | B2 |
7568688 | Nomura et al. | Aug 2009 | B2 |
7581725 | Fujita et al. | Sep 2009 | B2 |
7607652 | Kushida | Oct 2009 | B2 |
7766324 | Tamura et al. | Aug 2010 | B2 |
7938388 | Fujii et al. | May 2011 | B2 |
8393372 | Yamauchi et al. | Mar 2013 | B2 |
8413978 | Watanabe et al. | Apr 2013 | B2 |
20080213017 | Morisawa et al. | Sep 2008 | A1 |
20100247203 | Watanabe et al. | Sep 2010 | A1 |
Number | Date | Country |
---|---|---|
2005-206335 | Aug 2005 | JP |
2006-206331 | Aug 2006 | JP |
Number | Date | Country | |
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20130292897 A1 | Nov 2013 | US |