1. Field of the Invention
The present invention relates to a sheet stacking mechanism for successively stacking sheets being carried in from a carry-in opening on the upper surface of a sheet placing table, a sheet folding device, a sheet post-processing apparatus and an image forming apparatus provided with the sheet stacking mechanism.
2. Description of the Related Art
Some of image forming apparatuses include post-processing apparatuses such as a sheet middle-folding device as disclosed in Japanese Unexamined Patent Publication No. 2002-167120. A sheet stacking mechanism is provided in this sheet middle-folding device. However, since this sheet stacking mechanism has a mere construction of providing a pair of carry-in rollers at a carry-in opening for sheets, there is a likelihood that, upon receiving a sheet fed from the sheet post-processing apparatus, the trailing end of this sheet comes into contact with the leading end of a succeeding sheet, thereby causing a jam.
As means for solving such a problem, a processing tray includes a sheet stocking portion having a paddle for pressing a sheet in a guiding path for guiding the sheet, and a succeeding sheet is further stocked with the trailing end of the previously stocked sheet pressed by the paddle, for example, in Japanese Unexamined Patent Publication No. 2001-171889 although this technology is not applied to a sheet middle-folding device as described above. Accordingly, an occurrence of a jam caused by the collision of sheets can be prevented and even folded sheets can be stocked without causing any jam. This publication discloses that a high-speed processing can be carried out since the above makes it unnecessary to stop the conveyance of sheets during the application of stapling as a post-processing to a stack of sheets.
Further, Japanese Patent Publication No. 3423462 discloses the arrangement of a paddle for pressing an upstream end of a stapled stack of sheets with respect to a sheet discharging direction in a discharge tray.
However, even with the technologies disclosed in the latter two publications, if a sheet is stacked in an unstable state such as a curled state upon being stored, it is difficult to solve problems such as the switch of sheets (disorder in numbering) caused by a succeeding sheet having slipped in a clearance between the curled sheet and the sheet right below it or a tray and an occurrence of a jam caused by the collision of sheets. There have been also problems such as a loud hitting sound (noise) of the paddle when the stacked sheets are moved toward one end by the paddle in order to prevent the above switch of sheets.
In view of the above problems residing in the prior art, an object of the present invention is to prevent a disorder in the numbering of stacked sheets and to securely prevent an occurrence of a conveyance jam by a sheet collision.
The present invention is directed to a sheet stacking mechanism, comprising a sheet placing table having one end of the upper surface thereof arranged at the side of a carry-in opening for sheets and having sheets carried in from the carry-in opening successively stacked on the upper surface thereof; a receiving member disposed movably along the upper surface of the sheet placing table within a specified range including a first position located at the other end of the sheet placing table and distanced from the carry-in opening at least by the length of the sheet on the sheet placing table and adapted to receive the leading end of the sheet on the sheet placing table; and an operation control unit for performing a control of moving the receiving member to the first position and a control of moving the receiving member to a second position where the trailing end of the sheet slips under the carry-in opening.
According to the present invention, the receiving member for receiving the leading end of the sheet on the sheet placing table is disposed movably along the upper surface of the sheet placing table within the specified range including the first position located at the other end of the sheet placing table and distanced from the carry-in opening at least by the length of the sheet on the sheet placing table, and the operation control unit causes the receiving member to move to the second position where the trailing end of the sheet received by the receiving member slips under the carry-in opening. Thus, even if the sheets are stacked in an unstable state such as in a curled state, the leading end of a succeeding sheet carried onto the sheet placing table from the carry-in opening can be located on the sheet already stacked on the sheet placing table. Therefore, there is no problem such as the switch of sheets (disorder in numbering) caused by a succeeding sheet having slipped in a clearance between the sheets or the sheet and the sheet placing table, for example, due to a curled state of the sheet and an occurrence of a jam caused by the collision of sheets.
Further, since no paddle is used to prevent the switch of the sheets, there is no problem of loud hitting sounds (noise) of the paddle. As a result, it is possible to prevent a disorder in the numbering of stacked sheets without creating any noise and to securely prevent an occurrence of a conveyance jam by a collision.
Hereinafter, a sheet stacking mechanism, a sheet folding device, a sheet post-processing apparatus and an image forming apparatus according to one embodiment of the present invention are described with reference to the accompanying drawings.
The sheet conveyance paths R include an entrance conveyance path R1 extending leftward from a sheet receiving opening 13 of the post-processing apparatus 10 to a substantially transverse middle position of the post-processing apparatus 10; an auxiliary-tray conveyance path R2 branched off from the downstream end of the entrance conveyance path R1 and extending toward an auxiliary tray 15, a staple-unit conveyance path R3 branched off from the downstream end of the entrance conveyance path R1 and extending toward a post-processing space V1 of a staple unit 20, a main-tray conveyance path R4 extending toward a main tray 14 from the upper end of the post-processing space V1, a staple-tray conveyance path R5 branched off from the downstream end of the staple-unit conveyance path R3 and extending leftward toward a staple tray 30; a detour-tray conveyance path R6 branched off from the downstream end of the staple-unit conveyance path R3 and extending rightward; and a middle-folding-unit conveyance path R7 extending toward a middle-folding unit 17 through the detour tray 40. It should be noted that an end-binding stapler 38 for binding an end of a sheet stack P1 formed on the staple tray 30 is disposed at a position below the staple tray 30.
A switching guide 18 for switching a conveyance end of the sheet P between the auxiliary-tray conveyance path R2 and the staple-unit conveyance path R3 is disposed at the downstream end of the entrance conveyance path R1. If no binding is applied to the sheet P, the sheet P is discharged onto the auxiliary tray 15 via the auxiliary-tray conveyance path R2 with the switching guide 18 set in a specified posture. On the other hand, if binding is applied to the sheet P, the sheet P is fed to the staple unit 20 via the staple-unit conveyance path R3 by changing the posture of the switching guide 18. When a specified number of sheets P are stored in the post-processing space V1 to form a sheet stack P1, end binding is applied to this sheet stack P1 by the end-binding stapler 38. The stack of sheets P1 after the end binding is discharged onto the main tray 14 via the main-tray conveyance path R4.
The middle-folding-unit conveyance path R7 extends downward from a substantially vertical middle position of the detour tray 40. The sheet P to be folded in the middle is introduced into the middle-folding unit 17 via the middle-folding-unit conveyance path R7 after passing above the detour tray 40. A bottom part of such a middle-folding-unit conveyance path R7 is bent obliquely downward to the left toward the middle-folding unit 17 at the bottom end of the staple unit 20.
The sheet placing table 170 is inclined downward toward the leading end with respect to a carry-in opening 170a for sheets P, and is at an angle of inclination of about 30° with respect to a horizontal plane so that a sheet P carried in by carry-in rollers 170b provided at the carry-in opening 170a smoothly slides along the outer surface of the sheet placing table 170. A pair of carry-in rollers 170b and a guide 170c are disposed at a position of the carry-in opening 170a as shown in
A sheet stacking mechanism according to one embodiment of the present invention is constructed by a front-aligning cursor 1701 for receiving the leading end of the sheet P carried onto the sheet placing table 170 and front-aligning-cursor moving means 1702 for moving the front-aligning cursor 1701 along the sheet placing table 170. The middle-folding unit 17 further includes upper width-aligning cursors 1703a and lower width-aligning cursors 1703b arranged at the opposite widthwise sides at upstream and downstream sides of the sheet placing table 170 with respect to a sheet conveying direction for aligning a sheet stack P2 comprised of a plurality of sheets P carried onto the sheet placing table 170 in width direction and correcting an oblique conveyance, and width-aligning cursor moving means 1704 for independently reciprocating both upper and lower width-aligning cursors 1703a, 1703b so that these cursors 1703a, 1703b are symmetrical on the sheet placing table 170 with respect to width direction. After being moved by the front-aligning-cursor moving means 1702 such that the sheet stack P2 comprised of a plurality of sheets P comes to such a position as to enable the middle binding by the middle-binding stapler 171 with the sheet stack P2 aligned with respect to width direction and its oblique conveyance corrected by the width-aligning cursor moving means 1704, the front-aligning cursor 1701 is moved such that the sheet stack P2 bound in the middle comes to such a position as to be folded in the middle by the pair of folding rollers 172 and the folding blade 173. It should be noted that a blade HP sensor S2 for detecting a home position (HP) of the folding blade 173 is arranged at a specified position of the folding blade 173 driven by a motor M1. This blade HP sensor S2 is turned on when the folding blade 173 comes to its home position.
The sheet placing table 170 also includes a back-aligning cursor 1705 for aligning the back end of the sheet stack P2 on the sheet placing table 170, and back-aligning-cursor moving means 1706 for moving the back-aligning cursor 1705 along the sheet placing table 170. An upper width-alignment HP sensor S4, a lower width-alignment HP sensor S5, a front-alignment HP sensor S6 and a back-alignment HP sensor S7 for detecting the respective home positions (HPs) of the upper width-aligning cursors 1703a, the lower width-aligning cursors 1703b, the front-aligning cursor 1701 and the front-aligning cursor 1705 are arranged at specified positions of the sheet placing table 170 (see
A drive pulley 1702a to be driven by a motor M4 is arranged at the upper end of a downstream side of this sheet placing table 170, a driven pulley 1702b driven to rotate by the drive pulley 1702a is arranged at the bottom end of this downstream side, and an endless belt 1702c is so mounted between these pulleys 1702a, 1702b as to extend in the sheet conveying direction at the widthwise center of this downstream side. The front-aligning cursor 1701 having a Γ-shaped cross section is integrally formed at a specified position of the upper surface of the endless belt 1702c, and is moved along the sheet placing table 170 by a turning movement of the endless belt 1702c. The aforementioned front-aligning-cursor moving means 1702 is constructed by the motor M4, the pulleys 1702a, 1702b, the endless belt 1702c and a front-alignment instructing section 815 (see
Further, a drive pulley 1706a to be driven by a motor M5 is arranged at the bottom end of an upstream side of this sheet placing table 170, a driven pulley 1706b driven to rotate by the drive pulley 1706a is arranged at the upper end of this upstream side, and an endless belt 1706c is so mounted between these pulleys 1706a, 1706b as to extend in the sheet conveying direction at the widthwise center of this upstream side. The back-aligning cursor 1705 having a transversely inverted Γ-shaped cross section is integrally formed at a specified position of the upper surface of the endless belt 1706c, and is moved along the sheet placing table 170 by a turning movement of the endless belt 1706c. The aforementioned back-aligning-cursor moving means 1706 is constructed by the motor M5, the pulleys 1706a, 1706b, the endless belt 1706c and a back-alignment instructing section 816 (see
The upper width-aligning cursors 1703a include guiding plates having a Γ-shaped cross section and a transversely inverted Γ-shaped cross section when viewed from front and standing at the opposite widthwise sides of the endless belt 1706c. By cutting and bending parts of ceiling plates at the upper ends of these guiding plates, a sheet carried in from the carry-in rollers 170b can easily enter a space between the upper width-aligning cursors 1703a. The upper width-aligning cursors 1703a further include a pair of left and right racks (not shown) fixed to the guiding plates and supported movably along the width direction of the sheet placing table 170, pinions (not shown) in mesh with these racks, and a motor M2 for driving these pinions.
The lower width-aligning cursors 1703b include guiding plates having a Γ-shaped cross section and a transversely inverted Γ-shaped cross section when viewed from front and standing at the opposite widthwise sides of the endless belt 1702c. Unlike the upper width-aligning cursors 1703a, these guiding surfaces are entirely straight. The lower width-aligning cursors 1703b include a pair of left and right racks (not shown) fixed to the guiding plates and supported movably along the width direction of the sheet placing table 170, pinions (not shown) in mesh with these racks, and a motor M3 for driving these pinions.
The aforementioned width-aligning-cursor moving means 1704 is constructed by these motors M2, M3, racks and pinions and an upper and lower width-alignment instructing section 814 (see
The middle-binding stapler 171 is for applying so-called middle binding by driving staples at once to a middle part of the width-aligned sheet stack P2 of a specified number of sheets P with respect of the sheet conveying direction by means of a pair of left and right staplers 1711, 1712. Each of the staplers 1711, 1712 is provided at its lower part with a folding portion for enabling the staple driven from the front side and pierced through the sheet stack P2 to be easily folded back at the underside of the sheet stack P2.
The pair of folding rollers 172 are comprised of two folding rollers 1721, 1722 that are driven by an unillustrated motor while being synchronized with each other. One folding roller 1722 is elastically biased in a direction toward the other folding roller 1721 by an unillustrated spring so that the two rollers 1721, 1722 are pressed in contact at a nip with a specified force.
The folding blade 173 is constructed to press the middle part of the sheet stack P2 bound in the middle by the middle-biding stapler 171 toward a nip between the pair of folding rollers 172 by driving the motor M1. Accordingly, the sheet stack P2 folded in the middle by having the middle part thereof pressed by the folding blade 173 is pushed into a carry-out conveyance path R8 by the pair of folding rollers 172, and is discharged toward a middle-folded stack tray 176 via a discharge opening 175a comprised of the carry-out roller 174 and a pressing member 175. It should be noted that a discharge sensor S3 for detecting the sheet stack P2 discharged from the sheet placing table 170 is arranged in the vicinity of the carry-out opening 175a. This discharge sensor S3 is turned on upon detecting the sheet stack P2 discharged from the sheet placing table 170.
A control unit 80 including a microcomputer is provided for controlling the middle-folding process of the middle-folding unit 17.
A sheet-receipt judging section 811, a sheet-discharge judging section 811a, a stapler-operation instructing section 812, a folding-blade-operation instructing section 813, the upper and lower width-alignment instructing section 814, the front-alignment instructing section 815, the back-alignment instructing section 816 and a sheet-end judging section 817 are built in the CPU 81 by the reading of the program. A counter 84 for counting the number of sheets P discharged to the conveyance path R7 during one job is disposed outside the CPU 81.
The sheet-receipt judging section 811 is for outputting specified signals to the stapler-operation instructing section 812, the folding-blade-operation instructing section 813, the upper and lower width-alignment instructing section 814, the front-alignment instructing section 815, and the back-alignment instructing section 816 every time a sheet P passes the sheet carry-in opening 170a. To this end, the sheet-receipt judging section 811 receives a detection signal (ON, OFF) for the sheet P from the carry-in sensor S1, judges a timing at which the sheet P is carried to the sheet placing table 170 via the carry-in rollers 170b by adding a period required for the conveyance of the sheet P to the carry-in rollers 170b to a timing represented by the received signal, and outputs signals representing the judged timing to the stapler-operation instructing section 812, the folding-blade-operation instructing section 813, the upper and lower width-alignment instructing section 814, the front-alignment instructing section 815, and the back-alignment instructing section 816.
The sheet-discharge judging section 811a is for outputting specified signals to the stapler-operation instructing section 812, the folding-blade-operation instructing section 813, the upper and lower width-alignment instructing section 814, the front-alignment instructing section 815, and the back-alignment instructing section 816 every time a sheet P passes the sheet discharge opening 175a. To this end, the sheet-discharge judging section 811a receives a detection signal (ON) for the sheet P from the discharge sensor S3, judges a timing at which the sheet P is discharged to the middle-folded stack tray 176 via the carry-out roller 174 by adding a period required for the conveyance of the sheet P to the carry-out roller 174 to a timing represented by the received signal, and outputs signals representing the judged timing to the stapler-operation instructing section 812, the folding-blade-operation instructing section 813, the upper and lower width-alignment instructing section 814, the front-alignment instructing section 815, and the back-alignment instructing section 816.
The stapler-operation instructing section 812 is for outputting a control signal to the middle-binding stapler 171 to apply the middle-binding operation the sheets after receiving the signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a. The signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a is outputted to the stapler-operation instructing section 812, which in turn outputs the control signal to the middle-binding stapler 171 to cause this stapler 171 to apply the middle-binding operation to the sheets.
The folding-blade-operation instructing section 813 is for outputting a control signal to the folding-blade motor M1 to move the folding blade 173 in a specified direction after receiving the signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a. The signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a is outputted to the folding-blade-operation instructing section 813, which in turn outputs the control signal to the folding-blade motor M1 to move the folding blade 173 in the specified direction.
The upper and lower width-alignment instructing section 814 is for outputting a control signal to the upper width-alignment motor M2 and the lower width-alignment motor M3 to move the upper and lower width-aligning cursors 1703a, 1703b in specified directions after receiving the signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a. The signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a is outputted to the upper and lower width-alignment instructing section 814, which in turn outputs the control signal to the upper width-alignment motor M2 and the lower width-alignment motor M3 to move the upper and lower width-aligning cursors 1703a, 1703b in the specified directions.
The front-alignment instructing section 815 is for outputting a control signal to the front-alignment motor M4 to move the front-aligning cursor 1701 in a specified direction after receiving the signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a. The signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a is outputted to the front-alignment instructing section 815, which in turn outputs the control signal to the front-alignment motor M4 to move the front-aligning cursor 1701 in the specified direction.
By this front-alignment instructing section 815, there is realized an operation control unit for: (1) receiving the leading end of the sheet P carried in from the carry-in opening 170a by the front-aligning cursor 1701 moved to a first position within a specified range, and (2) moving the front-aligning cursor 1701 until the trailing end of the received sheet P slips under the guide 170c for the pair of carry-in rollers 170b constructing the carry-in opening 170a to move the trailing end of this sheet P away from the leading end of the a sheet P carried in next.
The back-alignment instructing section 816 is for outputting a control signal to the back-alignment motor M5 to move the back-aligning cursor 1705 in a specified direction after receiving the signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a. The signal based on the judgment result of the sheet-receipt judging section 811 or the sheet-discharge judging section 811a is outputted to the back-alignment instructing section 816, which in turn outputs the control signal to the back-alignment motor M5 to move the back-aligning cursor 1705 in the specified direction.
The counter 84 is configured to count the number of sheets P every time the sheet-receipt judging section 811 judges the receipt of a sheet P and to input the number of sheets discharged from the image forming apparatus 19 to the sheet post-processing apparatus 10 to the CPU 81.
The sheet-end judging section 817 judges whether or not the number of sheets counted by the counter 84 coincides with sheet number information from the image forming apparatus 19, and outputs signals based on the judgment result to the stapler-operation instructing section 812, the folding-blade-operation instructing section 813, the upper and lower width-alignment instructing section 814, the front-alignment instructing section 815, and the back-alignment instructing section 816 when the counted number of sheets coincides with the sheet number information. The stapler-operation instructing section 812, the folding-blade-operation instructing section 813, the upper and lower width-alignment instructing section 814, the front-alignment instructing section 815, and the back-alignment instructing section 816 having received these signals output signals to the middle-binding stapler 171, the folding-blade motor M1, the upper width-alignment motor M2, the lower width-alignment motor M3, the front-aligning cursor 1701, and the back-aligning cursor 1705 to cause them to stop operating. In this way, the respective operations of the middle-binding stapler 171, the folding-blade motor M1, the upper width-alignment motor M2, the lower width-alignment motor M3, the front-aligning cursor 1701, and the back-aligning cursor 1705 are stopped.
Next, the middle-folding operation by the middle-folding unit 17 of the sheet post-processing apparatus 10 is described.
In
Subsequently, the sheet-receipt judging section 811 judges whether or not the carry-in sensor S1 has been turned on and this routine waits on standby until the carry-in sensor S1 is judged to have been turned on (Step S2). Upon the lapse of a specified period after the sheet-receipt judging section 811 judges that the carry-in sensor S1 has been turned on, the front-alignment motor M4 is rotated clockwise (CW) by 133 steps by an instruction from the front-alignment instructing operation 815 (Step ST3). Then, the front-aligning cursor 1701 moves downward by 26.6 mm from the home position on the sheet placing table 170 (i.e. the front-aligning cursor 1701 is moved to the first position).
Further, immediately after the sheet-receipt judging section 811 judges that the carry-in sensor S1 has been turned on, the upper width-alignment motor M2 is stopped after being rotated counterclockwise (CCW) by 100 pulses and the lower width-alignment motor M3 is stopped after being rotated counterclockwise by 100 pulses by an instruction from the upper and lower width-alignment instructing section 814. Then, the upper and lower width-aligning cursors 1703a, 1703b are each moved toward the opposite widthwise ends by 10 mm on the sheet placing table 170. At this time, the back-aligning cursor 1705 is still kept at its home position so as not to hinder the conveyance of the sheet P, and the sheet P is carried onto the sheet placing table 170 by the carry-in rollers 170b and slides down on the upper surface of the sheet placing table 170 by the action of gravity.
Upon the lapse of 250 msec. after this width alignment (the sheet P is still sliding down by the action of gravity), the upper width-alignment motor M2 is stopped after being rotated clockwise by 70 pulses by an instruction from the upper and lower width-alignment instructing section 814 (Step ST4). Then, the upper width-aligning cursors 1703a are each moved toward the widthwise center by 7 mm at both sides. At this time, the leading end of the sheet substantially has the width thereof aligned by the upper width-aligning cursors 1703a and has its oblique conveyance corrected.
Subsequently, the sheet-receipt judging section 811 judges whether or not the carry-in sensor S1 has been turned off and this routine waits on standby until the carry-in sensor S1 is judged to have been turned off (Step ST5).
Upon the lapse of 155 msec. after the sheet-receipt judging section 811 judges that the carry-in sensor S1 has been turned off (when one sheet P is completely carried onto the sheet placing table 170: see
After this front alignment, the upper width-alignment motor M2 is stopped after being rotated clockwise by 30 pulses and the lower width-alignment motor M3 is stopped after being rotated clockwise by 100 pulses by an instruction from the upper and lower wais 814 (Step ST6). Then, the upper width-aligning cursors 1703a are each moved toward the widthwise center by 3 mm at both sides and the lower width-aligning cursors 1703b are each moved toward the widthwise center by 10 mm at both sides. At this time, the sheet P is precisely aligned with respect to width direction by both upper and lower width-aligning cursors 1703a and 1703b and has its oblique conveyance corrected.
Subsequently, the sheet-end judging section 817 judges whether or not the alignment (width alignment and oblique conveyance correction) of the last sheet of a set has been completed (Step ST7). Here, if the sheet-end judging section 817 judges that the alignment of the last sheet has not been completed, this routine returns to Step ST2 to repeat Steps ST2 to ST6.
Specifically, the sheet-receipt judging section 811 judges whether or not the carry-in sensor S1 has been turned on and this routine waits on standby until the carry-in sensor S1 is judged to have been turned on (Step ST2). Upon the lapse of a specified period after the sheet-receipt judging section 811 judges that the carry-in sensor S1 has been turned on, the front-alignment motor M4 is stopped after being rotated clockwise (CW) by 133 steps by an instruction form the front-alignment instructing section 815 (Step ST3). Then, the front-aligning cursor 1701 is moved downward by 26.6 mm on the sheet placing table 170 (see
Further, immediately after the sheet-receipt judging section 811 judges that the carry-in sensor S1 has been turned on, the upper width-alignment motor M2 is stopped after being rotated counterclockwise (CCW) by 100 pulses and the lower width-alignment motor M3 is stopped after being rotated counterclockwise by 100 pulses by an instruction from the upper and lower width-alignment instructing section 814. Then, both upper and lower width-aligning cursors 1703a, 1703b are each moved toward the widthwise ends by 10 mm on the sheet placing table 170. At this time, the back-aligning cursor 1705 is still kept at its home position so as not to hinder the conveyance of the sheet P, and the sheet P is carried onto the sheet placing table 170 by the carry-in rollers 170b and slides down on the upper surface of the sheet placing table 170 by the action of gravity.
Upon the lapse of 250 msec. after this width alignment (the sheet P is still sliding down by the action of gravity), the upper width-alignment motor M2 is stopped after being rotated clockwise by 70 pulses by an instruction from the upper and lower width-alignment instructing section 814 (Step ST4). Then, the upper width-aligning cursors 1703a are each moved toward the widthwise center by 7 mm at both sides. At this time, the leading end of the sheet substantially has the width thereof aligned by the upper width-aligning cursors 1703a and has its oblique conveyance corrected.
Subsequently, the sheet-receipt judging section 811 judges whether or not the carry-in sensor S1 has been turned off and this routine waits on standby until the carry-in sensor S1 is judged to have been turned off (Step ST5).
Upon the lapse of 155 msec. after the sheet-receipt judging section 811 judges that the carry-in sensor S1 has been turned off (when the two sheets P are completely carried onto the sheet placing table 170: see
When the sheet-end judging section 817 judges that the alignment of the last sheet of the set has been completed (YES in Step ST7), next Step ST8 follows. Here, the upper and lower width-alignment motors M2, M3 are respectively stopped after being rotated counterclockwise by 20 pulses by an instruction from the upper and lower width-alignment instructing section 814 (Step ST8). Then, the upper and lower width-aligning cursors 1703a, 1703b are each moved toward the opposite widthwise ends by 2 mm. Since this makes the sheets between the upper and lower width-aligning cursors 1703a, 1703b movable, the front-alignment motor M4 and back-alignment motor M5 are respectively stopped after being rotated in specified directions by specified numbers of steps by instructions from the front-alignment instructing section 815 and the back-alignment instructing section 816 (Step ST9). In this way, the sheets can be easily located at a specified middle-binding position.
Further, the upper and lower width-alignment motors M2, M3 are respectively stopped after being rotated clockwise by 20 pulses by an instruction from the upper and lower width-alignment instructing section 814 (Step ST10). Then, the upper and lower width-aligning cursors 1703a, 1703b are each moved toward the widthwise center by 2 mm to fix the sheets. A specified middle-binding processing is applied by the middle-binding stapler 171 by an instruction from the stapler-operation instructing section 812 (Step ST11).
Subsequently, in
Subsequently, the upper and lower width-alignment motors M2, M3 are respectively stopped after being rotated clockwise by 20 pulses by an instruction from the upper and lower width-alignment instructing section 814 (Step ST14). Then, the upper and lower width-aligning cursors 1703a, 1703b are each moved toward the widthwise center by 2 mm at both sides. In this way, the sheet stack P2 is aligned with respect to width direction and has its oblique conveyance corrected.
Further, the upper and lower width-alignment motors M2, M3 are each stopped after being rotated counterclockwise by 20 pulses by an instruction from the upper and lower width-alignment instructing section 814 (Step ST15). Then, the upper and lower width-aligning cursors 1703a, 1703b are moved toward the opposite widthwise sides by 2 mm, thereby making the sheet stack P2 movable and enabling the middle folding process.
Subsequently, the folding-blade motor M1 is turned on by an instruction from the folding-blade operation instructing section 813 (Step ST16). Then, the folding blade 173 pushes the middle part of the sheet stack P2 toward the nip of the pair of folding rollers 172, wherefore the sheet stack P2 sandwiched between the folding rollers 172 is folded in two. The sheet stack P2 is discharged through between the folding rollers 172, whereas the folding blade 173 is returned to its initial position and the folding-blade motor M1 is stopped when the folding-blade HP sensor S2 is turned off.
Subsequently, the sheet-discharge judging section 811a judges whether or not the discharge sensor S3 has been turned on and this routine waits on standby until the discharge sensor S3 is judged to have been turned on (Step ST17). Upon the lapse of 1.8 sec. after the sheet-discharge judging section 811a judges that the discharge sensor S3 has been turned on, the upper and lower width-alignment motors M2, M3 are respectively rotated counterclockwise by an instruction from the upper and lower width-alignment instructing section 814 and stopped when the upper and lower width-alignment HP sensors S4, S5 are respectively turned on. Further, the front-alignment motor M4 is rotated counterclockwise by an instruction from the front-alignment instructing section 815 and stopped when the front-alignment HP sensor S6 is turned on. Furthermore, the back-alignment motor M5 is rotated counterclockwise by an instruction from the back-alignment instructing section 816 and stopped when the back-alignment HP sensor S7 is turned on (Step ST18).
In this way, the upper and lower width-alignment motors M2, M3, the front-alignment motor M4 and the back-alignment motor M5 are all brought to standby states and a job is ended (Step ST19).
As described in detail above, the middle-folding unit of the sheet post-processing apparatus 10 according to one embodiment of the present invention is provided with the front-aligning cursor 1701 disposed movably along the upper surface of the sheet placing table 170 within the specified range including the first position set at a position displaced from the carry-in opening 170a toward the other end of the sheet placing table 170 at least by the length of the sheet P, and the control unit 80, wherein the front-alignment instructing section 815 causes the front-aligning cursor 1701 to move to the first position and to receive the leading end of the sheet P carried in from the carry-in opening 170a, and causes the front-aligning cursor 1701 to move until the trailing end of the received sheet P slips under the carry-in opening 170a, bringing the trailing end of the sheet P away from the leading end of a sheet carried in next. Thus, even if the sheet P is stacked in an unstable state such as in a curled state, there is no problem such as the switch of sheets (disorder in numbering) caused by a succeeding sheet having slipped in a clearance between the sheets or the sheet and the sheet placing table 170, for example, due to a curled state of the sheet and an occurrence of a jam caused by the collision of sheets. Further, since no paddle is used to prevent the switch of the sheets P, there is no problem of loud hitting sounds (noise) of the paddle. As a result, it is possible to prevent a disorder in the numbering of stacked sheets without creating any noise and to securely prevent an occurrence of a conveyance jam by a collision.
Although the middle-binding stapler 171 is incorporated into the middle-folding unit 17 in the foregoing embodiment, it is not always necessary to incorporate this middle-binding stapler into the middle-folding unit 17. In such a case, the middle-binding stapler 171 may be incorporated, for example, into the staple tray 30 upstream of the sheet post-processing apparatus 10.
Although the sheet stacking mechanism of the middle-folding unit 17 built in the sheet post-processing apparatus 10 connected with the image forming apparatus 19 is described in the foregoing embodiment, the sheet stacking mechanism according to the embodiment of the present invention is similarly applicable to sheet stacking mechanisms provided in other apparatuses.
In short, the present invention is directed to a sheet stacking mechanism comprising a sheet placing table having one end of the upper surface thereof arranged at the side of a carry-in opening for sheets and having sheets carried in from the carry-in opening successively stacked on the upper surface thereof; a receiving member disposed movably along the upper surface of the sheet placing table within a specified range including a first position located at the other end of the sheet placing table and distanced from the carry-in opening at least by the length of the sheet on the sheet placing table and adapted to receive the leading end of the sheet on the sheet placing table; and an operation control unit for performing a control of moving the receiving member to the first position and a control of moving the receiving member to a second position where the trailing end of the sheet slips under the carry-in opening.
In the present invention, the operation control unit causes the receiving member to move from the second position to the first position upon the lapse of a predetermined period after the leading end of a succeeding sheet is carried onto the sheet placing table from the carry-in opening.
In the present invention, a carry-in sensor for detecting the sheet being carried onto the sheet placing table is disposed in the vicinity of the carry-in opening, and the operation control unit causes the receiving member to move to the first position upon the lapse of a predetermined period after the sheet is detected by the carry-in sensor while causing the receiving member to move to the second position after the sheet is no longer detected by the carry-in sensor.
In the present invention, the operation control unit causes the receiving member to move to the first position upon the lapse of a predetermined period after the leading end of the sheet is carried onto the sheet placing table from the carry-in opening while causing the receiving member to move to the second position after the trailing end of the sheet is carried onto the sheet placing table.
In the present invention, a pair of carry-in rollers disposed at the carry-in opening for carrying sheets onto the sheet placing table and a guide for guiding sheets to the pair of carry-in rollers are further provided, and the one end of the sheet placing table is extended to a position below the guide so that the trailing end of the sheet having slipped under the carry-in opening is/are placed thereon.
According to these inventions, the receiving member for receiving the leading end of the sheet on the sheet placing table is disposed movably along the upper surface of the sheet placing table within the specified range including the first position located at the other end of the sheet placing table and distanced from the carry-in opening at least by the length of the sheet on the sheet placing table, and the operation control unit causes the receiving member to move to the second position where the trailing end of the sheet received by the receiving member slips under the carry-in opening. Thus, even if the sheets are stacked in an unstable state such as in a curled state, the leading end of a succeeding sheet carried onto the sheet placing table from the carry-in opening can be located on the sheets already stacked on the sheet placing table. Therefore, there is no problem such as the switch of sheets (disorder in numbering) caused by a succeeding sheet having slipped in a clearance between the sheets or the sheet and the sheet placing table, for example, due to a curled state of the sheet and an occurrence of a jam caused by the collision of sheets.
Further, since no paddle is used to prevent the switch of the sheets, there is no problem of loud hitting sounds (noise) of the paddle. As a result, it is possible to prevent a disorder in the numbering of stacked sheets without creating any noise and to securely prevent an occurrence of a conveyance jam by a collision.
In the present invention, the sheet placing table has such an inclination that the one end thereof is located higher than the other end thereof.
With this arrangement, the sheets can be more smoothly carried onto the sheet placing table.
The present invention is also directed to a sheet folding device comprising the sheet stacking mechanism according to the present invention and a middle-folding device for applying a middle-binding process and a middle-folding process to a sheet stack comprised of a plurality of sheets stacked on the sheet placing table at a position near a middle part of the sheet placing table with respect to a sheet conveying direction.
With such a sheet folding device, there is no problem such as the switch of sheets (disorder in numbering) caused by a succeeding sheet having slipped in a clearance between the sheets or the sheet and the sheet placing table, for example, due to a curled state of the sheet and an occurrence of a jam caused by the collision of sheets. Therefore, the middle-binding and middle-folding processes can be satisfactorily performed.
The present invention is further directed to a sheet post-processing apparatus comprising the sheet folding device according to the present invention in an apparatus main body connected with an image forming apparatus, wherein sheets having images formed thereon in the image forming apparatus are carried onto the sheet placing table.
The present invention is furthermore directed to an image forming apparatus comprising any one of the sheet stacking mechanism, the sheet folding device and the sheet post-processing apparatus according to the present invention.
This application is based on patent application No. 2005-345706 filed on Nov. 30, 2005 in Japan, the contents of which are hereby incorporated by references.
As this invention may be embodied in several forms without departing from the spirit of essential characteristics thereof, the present embodiment is therefore illustrative and not restrictive, since the scope of the invention is defined by the appended claims rather than by the description preceding them, and all changes that fall within metes and bounds of the claims, or equivalence of such metes and bounds are therefore intended to embraced by the claims.
Number | Date | Country | Kind |
---|---|---|---|
2005-345706 | Nov 2005 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6022011 | Hirose | Feb 2000 | A |
6209864 | Taniguchi et al. | Apr 2001 | B1 |
6779790 | Kitahara | Aug 2004 | B2 |
7052005 | Yamakawa et al. | May 2006 | B2 |
20030227121 | Yamakawa et al. | Dec 2003 | A1 |
Number | Date | Country |
---|---|---|
3423462 | Sep 1996 | JP |
201-171889 | Jun 2001 | JP |
2001-348153 | Dec 2001 | JP |
2002-167120 | Jun 2002 | JP |
2004-284762 | Oct 2004 | JP |
2005-82306 | Mar 2005 | JP |
2005-96913 | Apr 2005 | JP |
Number | Date | Country | |
---|---|---|---|
20070120308 A1 | May 2007 | US |