1. Field of the Invention
The present invention relates to a sheet processing apparatus including an aligning member that aligns sheets on a tray.
2. Description of the Related Art
A sheet processing apparatus is used, for example, by being coupled to an image forming apparatus. The image forming apparatus forms an image on sheets. The sheet processing apparatus is configured to, after receiving the sheets in a process tray as a stack tray, collate the sheets into a bundle form, and perform a stitching operation for such bundle of the sheets by a staple mechanism as processing means. In the event of performing the stitching operation, the sheet processing apparatus conveys the sheets onto the process tray by conveyance rollers as a sheet conveyance unit that conveys the sheets thereonto, and aligns the sheets by hitting the sheets against sheet edge regulating means by using a return roller as an aligning roller. After that, the sheet processing apparatus performs the stitching operation by the staple mechanism. Here, in the vicinity of the sheet edge regulating means, the return roller is arranged so as to be movable up and down by switching means. The return roller is lowered to a contact portion thereof that abuts on the sheets, the sheets are conveyed toward the sheet edge regulating means by the aligning roller, and leading edges of the sheets are hit against the sheet edge regulating means. In such a way, an operation of aligning the sheets is surely performed (refer to Japanese Patent Application Laid-Open No. 2006-82153 and Japanese Patent Application Laid-Open No. H05-169396).
However, in the event of allowing the aligning roller to perform such aligning operation for the trailing edges of the sheets as described above, in some case, the aligning operation for the sheets is not smoothly performed depending on a type of the sheets for use such as recording mediums. For example, in the case where the type of the sheets for use is thick paper (with a basis weight of 105 g/m2 or more), stiffness of the sheets becomes strong. Accordingly, there is a fear that the leading edges of the sheets may collide with a return guide member, and the sheets may not be nipped between the aligning roller and the process tray, causing a conveyance failure. In the case where the type of the sheets for use is coat paper onto which a coating material such as a resin is applied, the sheets become prone to stick on one another by the coating material. Accordingly, there is a fear that conveyance performance for the sheets may become poor, and the alignment of the sheets may turn to a disorder state.
In this connection, it is an object of the present invention to provide a sheet processing apparatus capable of, with a simple configuration, nicely performing the aligning operation for the sheets conveyed onto the process tray.
Further, in order to achieve the above-mentioned object, according to the present invention, a sheet processing apparatus includes: a process tray onto which a sheet is stacked; an aligning member that conveys the sheet toward a sheet edge regulating member arranged on an upstream end portion of the process tray in a contact state in which the aligning member is in contact with the sheet, the sheet edge regulating member regulating the leading edge of the sheet; and a switching member that switches a state of the aligning member between the contact state where, at a contact position in which the aligning member comes into contact with the sheet conveyed onto the process tray, the aligning member is in contact with the sheet, and a non-contact state where the aligning member is spaced apart from the process tray, wherein the switching member maintains the aligning member in the non-contact state until the sheet reaches the contact position on the process tray, and switches the aligning member from the non-contact state to the contact state after the sheet conveyed onto the process tray reaches the contact position.
In order to achieve the above-mentioned object, according to the present invention, a sheet processing apparatus includes: a process tray onto which a sheet is stacked; an aligning member that conveys the sheet toward a sheet edge regulating member arranged on an upstream end portion of the process tray in a contact state in which the aligning member is in contact with the sheet, the sheet edge regulating member regulating the leading edge of the sheet; and a switching member that switches a state of the aligning member between the contact state where, at a contact position in which the aligning member comes into contact with the sheet conveyed onto the process tray, the aligning member is in contact with the sheet, and a non-contact state where the aligning member is spaced apart from the process tray, wherein, while the sheet on the process tray is being conveyed toward the sheet edge regulating member by the aligning member, the switching member switches the aligning member from the contact state to the non-contact state, and further switches the aligning member from the non-contact state to the contact state.
Further, a sheet processing apparatus includes: a process tray onto which a sheet is stacked; an aligning member that conveys the sheet toward a sheet edge regulating member arranged on an upstream end portion of the process tray in a contact state in which the aligning member is in contact with the sheet, the sheet edge regulating member regulating the leading edge of the sheet; a switching member that switches a state of the aligning member between the contact state where, at a contact position in which the aligning member comes into contact with the sheet conveyed onto the process tray, the aligning member is in contact with the sheet, and a non-contact state where the aligning member is spaced apart from the process tray, the switching member operating in two modes including: a first mode of switching the aligning member from the non-contact state to the contact state before the sheet reaches the contact position on the process tray; and a second mode of maintaining the aligning member in the non-contact state until the sheet reaches the contact position on the process tray, and switching the aligning member from the non-contact state to the contact state after the sheet conveyed onto the process tray reaches the contact position; and a selection member that selects one of the first mode and the second mode so as to cause the switching member to operate.
Still further, a sheet processing apparatus includes: a process tray onto which a sheet is stacked; an aligning member that conveys the sheet toward a sheet edge regulating member arranged on an upstream end portion of the process tray in a contact state in which the aligning member is in contact with the sheet, the sheet edge regulating member regulating the leading edge of the sheet; a switching member that switches a state of the aligning member between a contact state where, at the contact position in which the aligning member comes into contact with the sheet conveyed onto the process tray, the aligning member is in contact with the sheet, and a non-contact state where the aligning member is spaced apart from the process tray, the switching member operating in two modes including: a first mode of switching the aligning member from the non-contact state to the contact state before the sheet reaches the contact position on the process tray; and a second mode of, while the sheet on the process tray is being conveyed toward the sheet edge regulating member by the aligning member, switching the aligning member from the contact state to the non-contact state, and further, switching the aligning member from the non-contact state to the contact state; and a selection member that selects one of the first mode and the second mode so as to cause the switching member to operate.
The switching member switches the aligning member from the non-contact state to the contact state before the sheet reaches the contact position on the process tray. In such a way, the stick of the coat sheet is prevented, and it is possible to convey the thick sheet without causing the leading edge of the thick sheet to collide with the aligning member.
Further, while the sheet on the process tray is being conveyed toward the sheet edge regulating member by the aligning member, the switching member switches the aligning member from the contact state to the non-contact state, and further switches the aligning member from the non-contact state to the contact state. In such a way, the stick of the coat sheet is prevented, and even if the leading edge of the thick sheet collides with the aligning member, the sheet can be nipped between the aligning member and the process tray by switching the state of the aligning member, whereby it is possible to reduce the conveyance failure.
For example, in the case where the type of the sheets for use is the thick paper thicker than the plain paper, the switching member is configured to switch the aligning member from the non-contact state to the contact state before each of the sheets reaches the contact position on the process tray.
According to the present invention having the configuration as described above, when the thick sheet having strong stiffness approaches a return roller as an aligning roller, the return roller is maintained in a raised state. Accordingly, the collision of the leading edge of the thick sheet with the aligning member is avoided, and the apprehension of the damage caused thereon is reduced.
For example, in the case where the type of the sheets for use is the coat paper coated with a coating material such as a resin, while each of the sheets on the process tray is being conveyed toward the sheet edge regulating member by the aligning member, the switching member switches the aligning member from the contact state to the non-contact state, and further switches the aligning member from the non-contact state to the contact state.
According to the present invention having the configuration as described above, the stick of the sheets is prevented, and good conveyance performance is maintained.
By using the present invention as described above, the aligning operation for the sheets conveyed onto the process tray can be nicely performed irrespective of the type of the sheets, and reliability of the sheet processing apparatus can be enhanced.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Referring to the drawings, an embodiment is described below in detail, in which the present invention is applied to an image forming system including a sheet processing apparatus B and a copier A as an image forming apparatus.
[Configuration of the Image Forming System]
The image forming system illustrated in
[Configuration of the Image Forming Apparatus]
As illustrated in
Further, an image reading apparatus 11 of
The image forming apparatus A with the above-mentioned configuration is provided with an image forming apparatus control portion (controller) 150 as illustrated in
A post-processing condition is also input and designated from the control panel 18, concurrently with the image formation conditions such as one-side/two-side printing and enlargement/reduction printing. Selected as the post-processing condition in this case is, for example, a “print-out mode”, “stitching finish mode”, or “brochure finish mode”.
[Configuration of the Sheet Processing Apparatus]
The sheet processing apparatus B is configured as described below to receive a sheet-shaped recording medium with the image formed thereon from the sheet discharge outlet 3 of the image forming apparatus A, and to (i) store the sheet-shaped recording medium in the stack tray 21 without post-processing (print-out mode), (ii) collate sheet-shaped recording mediums from the sheet discharge outlet 3 in a bundle form to be stapled, and store the stapled sheet-shaped recording mediums on the stack tray (a first stack tray) 21 (stitching finish mode), or (iii) collate sheet-shaped recording media from the sheet discharge outlet 3 in a bundle form, staple its center of the sheet-shaped recording mediums, fold the stapled sheet-shaped recording mediums in a book form to be stored in the saddle tray (a second stack tray) 22 (brochure finish mode).
Specifically, as illustrated in
The first conveyance path P1 includes a “buffer path P3” between a punch unit 60 and a process tray 29. When the post-processing such as the staple stitching is performed for a bundle of the stacked sheet-shaped recording mediums (hereinafter, referred to as a sheet bundle) stacked and collated for each set on the process tray 29, the buffer path P3 temporarily stays therein a subsequent sheet-shaped recording medium delivered to the sheet carry-in entrance 23a during such operation of the post-processing. Therefore, as illustrated in
The first conveyance path P1 is arranged in a substantially horizontal direction in an upper portion of an apparatus housing configured with the casing 20. The first processing section BX1 is arranged downstream of the first conveyance path P1, and the stack tray 21 is arranged downstream of the first processing section BX1. In the first conveyance path P1, the punch unit 60 to be described later is arranged between the carry-in entrance 23a and the first processing section BX1. In the first conveyance path P1, sheet discharge rollers 25 and a sheet discharge outlet 25x are provided at an outlet end of the first conveyance path P1. A sheet discharge sensor S2 is arranged on the sheet discharge outlet 25x. The sheet discharge sensor S2 is configured to detect the sheet-shaped recording mediums passing through the first conveyance path P1, and to detect a jam and count the number of sheets passing therethrough. A difference in level is formed downstream of the sheet discharge outlet 25x, and the process tray 29 to be described below is arranged there.
The second conveyance path P2 is arranged in a substantially vertical direction in a lower portion of the casing 20. The second processing section BX2 is arranged downstream of the second conveyance path P2, and the saddle tray 22 is arranged downstream of the second processing section BX2. Further, in the second conveyance path P2, a trimmer unit (a cutting unit) 90 to be described later is arranged close to the saddle tray 22. Still further, in the second conveyance path P2, conveyance rollers 27 are provided. A difference in level is formed downstream of the conveyance rollers 27, and a stacking guide 45 to be described later is arranged there.
[Configuration of the First Processing Section]
Here, the first processing section BX1 which is the above-mentioned processing means is formed of the process tray 29 disposed in the first conveyance path P1, a side stitching unit 31 disposed in the process tray 29, and aligning means 51.
[Configuration of the Process Tray]
As illustrated in
Sheet edge regulating means (a sheet edge regulating member) 32 regulates a leading edge of a sheet. The sheet edge regulating means 32 is provided downstream of the process tray 29 in a conveyance direction. The sheets discharged from the sheet discharge outlet 25x are switched back, and leading edges of the sheets are aligned by being hit against the sheet edge regulating means 32. Above the process tray 29, there are arranged switchback rollers (first friction rotating members; the same applies below) 26 (a movable roller 26a, a fixed roller 26b) which convey, to the sheet edge regulating means 32, the sheet-shaped recording mediums carried onto the process tray 29, aligning means 51, and side aligning means 34.
Each structure is described below.
[Configuration of the Sheet Edge Regulating Means]
In the process tray 29, the sheet edge regulating means 32 is disposed for positioning one edge of the leading edge and trailing edge of the fed sheet. The sheet edge regulating means 32 illustrated in
The sheet edge face regulating surface 32a and the sheet upper face regulating surface 32b illustrated in
Thus, the first and second movable stopper members 32B and 32C positioned in the sheet right and left edge portions move to positions in accordance with the sheet size. Therefore, with the bottom wall of the process tray 29, there are fitted and supported a right slide member 38a and a left slide member 38b to be movable in the sheet width direction. Then, the first movable stopper member 32B and the second movable stopper member 32C are fixed to the right and left slide members 38a and 38b. The right and left slide members 38a and 38b are coupled to alignment plates 34R and 34L for aligning the sheet side to move in association with the movement of the alignment plates 34R and 34L as described later.
In the sheet edge regulating means 32 configured as described above, at least the sheet upper face regulating surface 32b is configured to be able to move up and down in the sheet stacking direction. This is because sheet-bundle carry-out means 100 as described later sometimes raises a bundle of sheets on the process tray 29 upward in carrying out the bundle of sheets on the process tray 29, and the sheet upper face regulating surface 32b should be moved upward according to upward movements of the bundle of sheets.
Therefore, as illustrated in
[Configuration of the Sheet Conveying Means]
In the process tray 29, the sheet conveying means (a switchback roller) 26 is disposed for guiding a sheet discharged from the sheet discharge outlet 25x to the sheet edge regulating means 32 by performing switchback after temporarily stopping the sheet. The sheet conveying means 26 is formed of a friction rotating member such as a roller, belt, or the like for conveying a sheet fed to the process tray 29 from the sheet discharge outlet 25x to the sheet edge regulating means 32. The following description is given according to the switchback roller mechanism as illustrated in
As illustrated in
The movable-side switchback roller 26a pivotally supported by the raising and lowering support arm 28 is coupled to a forward and reverse motor (not shown) via transmission means (coupling), and rotates forward and reverse in the discharge direction of the sheet conveyed onto the process tray 29 and the opposite direction thereto. Therefore, a roller rotary shaft 26z of the switchback roller 26a is pivotally supported by a long groove 28u formed in the raising and lowering support arm 28 as illustrated in
[Paper Surface Contact Sensor]
The raising and lowering support arm 28 is provided with the paper surface contact sensor Ss for detecting a position of the roller rotary shaft 26z moving up and down along the long groove 28u. The paper surface contact sensor Ss is configured to detect a position of the roller rotary shaft 26z traveling (moving upward) in the long groove 28u by the contact pressure caused by the switchback roller 26a coming into contact with the uppermost sheet on the process tray. Therefore, the raising and lowering arm 28 is provided with a sensor lever 30 having a rotation center o1 in a position different from the swinging rotary shaft 28a, and the roller rotary shaft 26z is pivotally coupled to the forward end portion of the sensor lever 30. Then, the paper surface contact sensor Ss is formed of a photosensor for detecting a sensor flag 30f formed in the rear end portion of the sensor lever 30.
The thus configured switchback roller 26a moves up and down between the standby position (
[Configuration of Control Means]
Raising and lowering control means 165 (switching means) for controlling the raising and lowering motor MY is configured as described below. The raising and lowering control means 165 is formed of a control CPU 160 as described later, and controls the raising and lowering support arm 28 to be raised and lowered between the contact position and the non-contact position. First, the raising and lowering control means 165 controls the raising and lowering support arm 28 to rest in the standby position using the position sensor S3 disposed in the vicinity of the raising and lowering support arm 28. Then, an initial operation for determining a height position of the switchback roller 26a at the present moment is first executed.
Specifically, as illustrated in
In the event of conveying the next first sheet, the leading edge of the sheet carried out from the above-mentioned sheet discharge outlet 25x is detected by the sheet sensor S2. After the leading edge of the sheet passes immediately under the switchback roller 26a, the raising and lowering motor MY is rotated counterclockwise. Then, the raising and lowering support arm 28 rotates counterclockwise about the swinging rotary shaft 28a thereof. In such a way, because the roller rotary shaft 26z of the switchback roller 26a is supported by the long groove 28u, the switchback roller 26a is lowered from the non-contact position (
Subsequently, the switchback roller 26a is started to be raised, and a distance (height) H1 to which the switchback roller 26a reaches a certain height position where the paper surface contact sensor Ss for detecting the position of the roller rotary shaft 26z is turned off is measured. Such measurement is repeatedly performed multiple times (for example, three times), an average value of multiple measurement values thus obtained is calculated, and the average value is determined and stored as the measured height H1 from the uppermost surface of the stacked sheets. The measured height H1 is defined as a lowering amount for the next second sheet. After that, the switchback roller 26a is raised to the home position (height: 22 mm) together with the raising and lowering support arm 28, and is turned to the standby state, and such sheet conveyance operation by the switchback roller 26a is similarly performed for the second sheet and after.
As described above, in this embodiment, in the case of conveying an N-th sheet, the leading edge of the sheet carried out from the above-mentioned sheet discharge outlet 25x is detected by the sheet sensor S2. Then, after the leading edge of the sheet passes immediately under the switchback roller 26a, the switchback roller 26a is lowered from the non-contact position (
Subsequently, the switchback roller 26a is started to be raised, and a distance (height) HN to which the switchback roller 26a reaches a certain height position where the paper surface contact sensor Ss for detecting the position of the roller rotary shaft 26z is turned off is measured. Such measurement is repeatedly performed multiple times (for example, three times), an average value of multiple measurement values thus obtained is calculated, and the average value is determined and stored as the measured height HN from the uppermost surface of the stacked sheets. The measured height HN is defined as a lowering amount for the N+1th sheet. After that, the switchback roller 26a is raised to the home position in the non-contact state together with the raising and lowering support arm 28, and such sheet conveyance operation by the switchback roller 26a is similarly performed for the N+1th sheet onwards.
At this time, the raising and lowering control unit 165 sets the lowering speed (rotation speed of the raising and lowering motor MY) Va of the raising and lowering support arm 28 to be equal to or slower than the speed (free fall speed) Vr at which the movable switchback roller 26a falls inside of the long groove 28u with the aid of the gravitational force of the switchback roller 26a (Va≦Vr). That is because, when the lowering speed Va of the raising and lowering support arm 28 is set to be faster than the falling speed of the switchback roller 26a freely falling inside of the long groove 28u, the roller becomes unstable to cause malfunctioning of the paper surface contact sensor Ss through rebounding of the roller. In other words, the speed Vr at which the switchback roller 26a falls is limited through the speed of the raising and lowering support arm 28, and the switchback roller 26a is thereby lowered gently, whereby the paper surface contact sensor Ss is prevented from erroneous detection due to chattering and the like.
Next, when a peripheral surface of the switchback roller 26a comes into contact with the uppermost sheet on the process tray 29, the switchback roller 26a is rested on the uppermost sheet, and the raising and lowering support arm 28 rotates and falls in the same direction as that of the switchback roller 26a. At this time, the paper surface contact sensor Ss rotates counterclockwise about the swinging rotary shaft 28a of the raising and lowering support arm 28. Then, the paper surface contact sensor Ss detects the sensor flag 30f of the sensor lever 30, and turns “ON”. The raising and lowering motor MY is stopped based on a detection signal of the paper surface contact sensor Ss. By being controlled as described above, the switchback roller 26a always comes into contact with the uppermost sheet with constant pressure-contact force (for example, the weight of the switchback roller 26a) regardless of whether the stacking amount of the sheets stacked on the process tray 29 is large or small (refer to
Substantially simultaneously with the falling of the switchback roller 26a to the contact position, the raising and lowering control unit 165 drives the forward and reverse rotation motor (not shown) to rotate the switchback roller 26a forward and reverse. Then, the sheet carried onto the uppermost sheet on the process tray 29 from the sheet discharge outlet 25x receives constant transport force, and is conveyed in the sheet discharge direction and the direction opposite to the sheet discharge direction. Note that, in the illustrated apparatus, when the sheet from the sheet discharge outlet 25x is conveyed from the sheet discharge outlet in the sheet discharge direction, the switchback roller 26a is rotated clockwise as illustrated in
With such configuration, for example, even if the sheets are fed at a high speed, and the curled portions occur in the sheets, the sheet conveying means 26a is caused to once abut against the uppermost surface of the stacked sheets on the process tray 29, and thereby, in a state in which the sheets have an original stacking height due to the abutting action of the sheet conveying means 26a, the detection value of the height of the stacked sheets can be accurately obtained as a reference position for measuring the height.
Here, in this embodiment, the following configuration is adopted. Multiple conveyance modes are set, in which timing when a return roller 51b as an aligning member in the present invention moves between a conveying position of conveying the sheets and a non-contact position spaced apart from the conveying position is mutually differentiated, and further, any of multiple conveyance modes is selected, and the sheets are aligned based on the selected mode. In other words, with regard to the sheets discharged onto the process tray 29 as mentioned above, a configuration is adopted, in which the sheets on the process tray 29 are conveyed and aligned based on a predetermined conveyance mode of appropriately vertically moving and rotationally driving the switchback roller 26a and the return roller 51b as an aligning roller in the present invention. In this case, the above-mentioned raising and lowering control unit 165 is configured so as to switch the conveyance modes depending on types of the sheets (recording mediums) for use. A “plain paper mode”, a “thick paper mode” and a “coat paper mode” are set as the conveyance modes.
The plain paper mode is a conveyance mode for sheets as plain paper having a basis weight of 64 g/m2 or more and less than 105 g/m2. The thick paper mode is a conveyance mode for sheets as thick paper having a basis weight of 105 g/m2 or more. The coat paper mode is a conveyance mode for sheets as coat paper having surfaces coated with a coating material such as a resin.
First, in the “plain paper mode” in the case where the type of the sheets (recording mediums) for use is the plain paper, as illustrated in
Subsequently, the switchback roller 26a is reversed, and the sheet is conveyed on the process tray 29 toward the sheet edge regulating means 32 (refer to Step ST114 of
Further, in the “thick paper mode” (
At this time, as illustrated in
Subsequently, the switchback roller 26a is reversed, and the sheet is conveyed on the process tray 29 toward the sheet edge regulating means 32 (refer to Step ST132 of
Further, in the “coat paper mode” (
Subsequently, the switchback roller 26a is reversed, and the sheet is conveyed on the process tray 29 toward the sheet edge regulating means 32 (refer to Step ST114 of
In addition, in this mode, as illustrated in
Further, as the peeling operation for each of the sheets, in a state where the leading edge of the sheet is located between the contact position and the sheet edge regulating means, the return roller 51b is switched from the contact state to the non-contact state, and is further switched from the non-contact state to the contact state. Also in such a way, the same effect can be obtained.
As described above, this embodiment is configured so as to change the conveyance mode upon stacking the sheets on the process tray 29 to any of the “plain paper mode”, the “thick paper mode”, and the “coat paper mode” based on the type of the sheets for use. In the case where the type of the sheets is changed while the sheets are being stacked, the conveyance mode is changed in response to the change of the type of the sheets. However, for the first sheet immediately after the mode is changed, the previous mode (old mode) is implemented. For example, in the case where the conveyance mode is changed from the coat paper mode to the plain paper mode while the sheets are being stacked, the first sheet of the plain paper is conveyed in the coat paper mode, and the second sheet of the plain paper and subsequent sheets are conveyed in the plain paper mode. However, in the case where the conveyance mode is changed from the coat paper mode to the thick paper mode, a first half of the first sheet of the thick paper is conveyed on the thick paper mode in a state where the return roller is raised, and a second half thereof is conveyed on the coat paper mode without raising the swing roller.
Further, even in the case of using the thick paper mode for the coat paper (coat sheets), the stick of the coat sheets is prevented, and it is possible to reduce the apprehension that the leading edge of each of the coat sheets may collide with the aligning member and be damaged. Reasons for this are as follows. Specifically, the above-mentioned switching means switches the aligning member from the non-contact state to the contact state until the sheet reaches the contact position on the stack tray, whereby it is possible to peel the stuck coat sheet with an impact generated when the aligning member comes into contact in the contact position.
Further, even in the case of using the coat paper mode for the thick paper (thick sheets), it is possible to convey each of the thick sheets even if the leading edge thereof collides with the aligning member. Reasons for this are as follows. Specifically, while each of the thick sheets on the stack tray is being conveyed toward the sheet edge regulating means by the aligning member, the switching member switches the aligning member from the contact state to the non-contact state, and further, switches the aligning member from the non-contact state to the contact state, whereby, even if the leading edge of the thick sheet collides with the aligning member, it is possible to nip the sheet between the aligning member and the stack tray, and to reduce the conveyance failure.
[Description of the Control Configuration]
A control configuration of the image forming system as described above is described below with reference to a block diagram of
Concurrently therewith, the post-processing mode is set by input from the control panel 118. For example, the “print-out mode”, “staple stitching finish mode”, “sheet-bundle folding finish mode”, or the like is set. At this time, when the type of the sheets is special paper (thick paper, coat paper), the type of the sheets is input, and the conveyance mode is set to any one of the “plain paper mode”, the “thick paper mode”, and the “coat paper mode”. Accordingly, the main body control portion 150 transfers, to the post-processing control portion 160, information on the finish mode, the number of sheets, and the number of sets in the post-processing, and information on a stitching mode (one-portion stitching, two-portion stitching, or multiple-portion stitching). Simultaneously therewith, the main body control portion 150 transfers a job finish signal to the post-processing control portion 160 as selection means whenever the image formation is completed.
The post-processing control portion 160 includes the control CPU 161 for operating the post-processing apparatus B corresponding to the designated finish mode, a ROM 162 for storing an operation program, and a RAM 163 for storing control data. Then, the control CPU 161 includes a sheet conveyance control portion 164a for executing conveyance of a sheet sent to the carry-in entrance 23a, a sheet stacking operation control portion 164b for executing the operation of stacking sheets, a stitching operation control portion 164c for executing sheet stitching processing, and a sheet bundle folding operation control portion 164d for executing the operation of folding a bundle of sheets.
The sheet conveyance control portion 164a is coupled to a control circuit of drive motors (not shown) of the carry-in roller 23 and the sheet discharge roller 25 of the first conveyance path P1, and is configured to receive a detection signal from the sheet sensor S1 disposed in this conveyance path. Further, the sheet stacking operation control portion 164b is connected to the forward and reverse rotation motor of the switchback roller 26a and a driving circuit of a shift motor of the sheet edge regulation member to gather sheets on the process tray 29. Further, the stitching operation control portion 164c is connected to a driving circuit of drive motors MD incorporated into the side stitching unit 31 of the process tray 29 and into the saddle stitching staple unit 40 of the stacking guide 45.
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 Applications No. 2009-096537, filed Apr. 10, 2009, and No. 2010-087605, filed on Apr. 6, 2010 which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | Kind |
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2009-096537 | Apr 2009 | JP | national |
2010-087605 | Apr 2010 | JP | national |
This application is a divisional of U.S. patent application Ser. No. 12/757,102, filed Apr. 9, 2010, and allowed on Nov. 23, 2012.
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Japanese Office Action issued in Counterpart Application No. 2010-087605, mailed Aug. 27, 2013. |
Number | Date | Country | |
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20130187324 A1 | Jul 2013 | US |
Number | Date | Country | |
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Parent | 12757102 | Apr 2010 | US |
Child | 13772567 | US |