The present application claims priority to and incorporates by reference the entire contents of Japanese priority document, 2006-241695 filed in Japan on Sep. 6, 2006.
1. Field of the Invention
The present invention relates to a sheet aligning device, a sheet processing device, and an image forming apparatus.
2. Description of the Related Art
For center stapling, sheet finishers align sheets in a stapling unit and position them at the same place to staple the sheets, and convey the center-stapled sheets to a folding unit downstream. Although the maximum stapling capacity of approximately 50 sheets has been sufficient, there has been a recent demand for a stapling capacity of 100 sheets. When the stapling capacity is increased to meet the demand, staplers are also increased in size, which makes a layout of a center stapler and a center-folding mechanism difficult.
More specifically, in a conventional sheet finisher with a stapling capacity of 50 sheets, as described above, the center stapler is positioned in the stapling unit, and stapling can be performed on sheets by aligning the sheets with a jogger fence, which is commonly used for both edge stapling and center stapling. The shared use of the jogger fence is allowed thanks to a conveyance capacity of 50 sheets, corresponding the maximum stapling capacity, through between a clincher and a driver (distance set for the clearance between the clincher and the driver is 15 millimeters) of the center stapler.
Such a sheet finisher is described in, for example, Japanese Patent Application Laid-open Nos. H10-181987, 2000-118850, and 2003-073022.
When the center stapler is positioned in a stapling unit having a stapling capacity of 100 sheets as in the case of a stapling unit having a stapling capacity of 50 sheets, it is physically impossible to convey 100 sheets, corresponding to the maximum stapling capacity, through clearance space between the clincher and the driver of the center stapler. Thus, the sheets cause jam by blocking the clearance space. Meanwhile, when a stack of sheets is aligned in the stapling unit as performed in the conventional device, because the width of a jogger fence of the conventional stapling unit is set for the maximum stapling capacity, i.e., 50 sheets, a large space allowance is produced. The large space allowance sometimes causes the sheets to flutter, and stapling positions to vary. In other words, due to the large space allowance, control against curling or bending of the sheets sometimes fails, which also causes stapling at an intended position to fail.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an aspect of the present invention, a sheet aligning device includes a transport path that transports sheets; a first aligning unit that aligns the sheets in a first direction in which the sheets are transported on the transport path; a second aligning unit that aligns the sheets in a second direction perpendicular to the first direction on the transport path; and a mode control unit that switches aligning modes in which the first aligning unit and the second aligning unit align the sheets.
According to another aspect of the present invention, a sheet processing device includes a sheet aligning device including a transport path that transports sheets; a first aligning unit that aligns the sheets in a first direction in which the sheets are transported on the transport path; a second aligning unit that aligns the sheets in a second direction perpendicular to the first direction on the transport path; and a mode control unit that switches aligning modes in which the first aligning unit and the second aligning unit align the sheets. The sheet processing device further includes a stapling unit that is located on the transport path for stapling the sheets.
According to still another aspect of the present invention, an image forming apparatus includes a sheet aligning device including a transport path that transports sheets; a first aligning unit that aligns the sheets in a first direction in which the sheets are transported on the transport path; a second aligning unit that aligns the sheets in a second direction perpendicular to the first direction on the transport path; and a mode control unit that switches aligning modes in which the first aligning unit and the second aligning unit align the sheets.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
Exemplary embodiments of the present invention are explained in detail below referring to the accompanying drawings.
As shown in
The sheet is conveyed via the transport paths A and D to the stapling tray F, in which the sheet is aligned and stapled, and then steered by the switching guide 54 and the movable guide 55 to either the transport paths C that guides the sheet to the shift tray 202 or the processing tray G (hereinafter, also “stapling/folding tray”), in which the sheet is subjected to folding, or the like. The sheet folded in the stapling/folding tray G is guided to the lower tray 203 via a transport path H. The transport path D includes a path-switching flap 17 that is retained in a state shown in
The transport path A, which is upstream of and common to the transport paths B, C and D, includes, in addition to a sheet entry sensor 301, an inlet roller pair 1, the punching unit 100, a punching-waste hopper 101, a transport roller pair 2, and the path-switching flaps 15 and 16 arranged in this order downstream of the sheet entry sensor 301. The sheet entry sensor 301 detects receipt of a sheet from the image forming apparatus PR. The path-switching flaps 15 and 16 are retained in the positions shown in
To guide a sheet to the transport path B, the solenoid for the path-switching flap 15 is turned off to hold the path-switching flap 15 at the position shown in
The paper finishing device is capable of performing punching (using the punch unit 100), aligning and edge stapling (using jogger fences 53 and the edge stapler S1), a combination of aligning and center stapling (using the jogger fence 53 and a center stapler S2), sorting (using the shift tray 202), and a combination of aligning, center stapling, and center folding (using an upper jogger fence 250a and a lower jogger fence 250b, the center stapler unit, the folding plate 74, and the folding roller pair 81), and the like.
In
As specifically shown in
In the embodiment, upon being shielded by the sector shielding portion 30b, each of the sheet level sensor (for sheets to be stapled) 330a and the sheet level sensor (for sheets not to be stapled) 330b is turned on. Thus, when the shift tray 202 ascends to rotate the contacting portion 30a of the sheet-level detecting lever 30 upward, the sheet level sensor (for sheets to be stapled) 330a is turned off. When the shift tray 202 further rotates the contacting portion 30a, the sheet level sensor (for sheets not to be stapled) 330b is turned on. When the sheet level sensor (for sheets to be stapled) 330a and the sheet level sensor (for sheets not to be stapled) 330b detect that a sheet stack height has reached a predetermined value, the tray elevating motor 168 is driven to lower the shift tray 202 by a predetermined distance. Thus, the shift tray 202 is maintained at an essentially constant stack height.
The elevating mechanism of the shift tray 202 is described in detail below. As shown in
The drive unit L includes the tray elevating motor 168 serving as a drive source that can run reversely, and a worm gear 25. Torque generated by the tray elevating motor 168 is transmitted to the last gear of a gear train fixed to the drive shaft via the worm gear 25 to move the shift tray 202 upward or downward. Because the power is transmitted through the worm gear 25, the shift tray 202 can be maintained at a fixed position. Thus, the gear structure prevents unintentional dropping of the shift tray 202, and the like.
A shield plate 24a is formed integrally with the side plate 24 of the shift tray 202. A full-stack sensor 334 that detects a fully-stacked state of the shift tray 202 and a lower limit sensor 335 that detects a lower limit level of the shift tray 202 are positioned below the shield tray 24. The shield plate 24a turns on and off the full-stack sensor 334 and the lower limit sensor 335. Each of the full-stack sensor 334 and the lower limit sensor 335 is embodied by a photosensor, and turned off upon being shielded by the shield plate 24a. Meanwhile, the discharge roller pair 6 is not shown in
As shown in
Guiding channels 32c, through which the shift tray 202 is guided, are provided on the front surface of the end fence 32. Rear end portions of the shift tray 202 are vertically movably received in the guiding channels 32c. Thus, the shift tray 202 is supported by the end fence 32 to be movable vertically, as well as back and forth in the direction perpendicular to the sheet conveying direction. The end fence 32 guides trailing edges of sheets stacked on the shift tray 202 to align the sheets at their trailing edges.
As shown in
As shown in
As shown in
The jogger fences 53 (53a and 53a′, see
As shown in
The sheet stack stapled at its center in the stapling tray F is folded at a center portion. The sheet stack is folded at its center in the stapling/folding tray G. Thus, to be folded at its center, the sheet stack must be conveyed to the stapling/folding tray G. In the embodiment, a sheet-stack steering unit that transports the sheet stack to the stapling/folding tray G is provided at a most downstream portion of the stapling tray F in the sheet conveying direction.
As shown in
The movable guide 55 is pivotably supported on the rotary shaft of the output rollers 56. A link arm 60 is rotatably coupled to one end (opposite end from the switching guide 54) of the movable guide 55 via a joint 60a. A pin fixed to the front side plate 64a shown in
An HP sensor 315 detects a shielding portion 61c of the cam 61, thereby detection a home position of the cam 61. Driving pulses of the path-switching drive motor 161 are counted using the thus-detected home position as its reference so that a position at which the cam 61 is to be stopped is controlled based on the pulse count.
In the embodiment, both the switching guide 54 and the movable guide 55 are driven by a drive motor. As an alternative configuration, each of the switching guide 54 and the movable guide 55 can include a drive motor so that stop positions and timings, at which the guides are to be moved, can be controlled according to a sheet size and the number of sheets to be stapled.
As shown in
Each of the upper transport-roller pair 71 and the lower transport-roller pair 72 is formed with a drive roller and a driven roller. The upper transport-roller pair 71 includes a distance sensor that measures a distance between nip portions of the roller pair. Accordingly, when a sheet stack is nipped by the upper transport-roller pair 71, the distance between the nip portions can be detected using the distance sensor and transmitted to a central processing unit (CPU) 360. Thus, a controller 350 can acquire thickness data about the sheet stack, and the CPU 360 can perform mode selection, described later, based on the thickness data.
The movable fence 73 is positioned across the lower guide plate 91. A transfer mechanism including a timing belt and its drive allows the movable fence 73 to move in the sheet conveying direction (vertical direction in the drawings). Although not shown, the drive includes a drive pulley, a driven pulley, around which the timing belt is wound, and a stepping motor that drives the drive pulley. Similarly, the tapping tab 251 and its drive are positioned on an upper end of the upper guide plate 92. A timing belt 252 and a drive (not shown) move the tapping tab 251 back and force, i.e., in a direction separating from the sheet stack steering mechanism and a direction pressing the trailing edge of a sheet stack (corresponding to a tail end of the sheet in an orientation taken at entry to the finisher). An HP sensor 326 detects a home position of the tapping tab 251.
A center-folding mechanism is provided at or near the center of the stapling/folding tray G, and includes the folding plate 74, the folding roller pair 81, and a transport path H on which a folded sheet stack is conveyed.
Two pins 64c are positioned upright on the front and rear side plates 64a and 64b, and elongated holes 74a are defined in the folding plate 74. The elongated holes 74 movably receive a corresponding one of the two pins 64c, thereby supporting the folding plate 74. A pin 74b is positioned upright on the folding plate 74, and an elongated hole 76b is defined in the link arm 76. The elongated hole 76b movably receives the pin 74b, and the link arm 76 pivots about a fulcrum 76a, thereby allowing the folding plate 74 to move rightward and leftward in
A pin 75b on a folding-plate cam 75 is movably received in an elongate hole 76c defined in the link arm 76. Thus, rotating motion of the folding-plate drive cam 75 causes the link arm 76 to pivot, and, in response thereto, the folding plate 74 is reciprocally moved in a direction perpendicular to the lower and upper guide plates 91 and 92 in
The folding-plate drive cam 75 is rotated by a folding-plate drive motor 166 in a direction indicated by arrow in
While, in the embodiment, a center fold is assumed to be given to a sheet stack, the invention can be also applied to a fold of a single sheet. When a single sheet is to be folded, the center stapling is skipped. Accordingly, at an instant of being delivered, the sheet is conveyed to the stapling/folding tray G, in which the sheet is subjected to folding performed by the folding plate 74 and the folding roller pair 81, and then output to the lower tray 203. A folded-portion-passage sensor 323 detects a center-folded sheet. A sheet-stack sensor 321 detects arrival of a sheet stack at the center-fold position. A movable HP sensor 322 that detects a home position of the movable fence 73. In the embodiment, a detecting lever 501 for use in detection of a stack height of center-folded sheet stacks in the lower tray 203 is positioned to be pivotable about a fulcrum 501a. A sheet level sensor 505 detects an angle of the detecting lever 501, thereby detecting ascending and descending, and overflow pertaining to the lower tray 203.
The CPU 360 controls, based on the thus-supplied signals, a tray elevating motor 168 that lifts and lowers the shift tray 202; the guide-plate opening/closing motor 167 that opens and closes the reclosable guide plate; the shift tray motor 169 that moves the shift tray 202; a tapping roller motor (not shown) that drives the tapping roller 12; various solenoids such as the tapping SOL 170; transport motors that drives the various transport rollers; sheet-output motors that drive the various output rollers; the delivery motor 157 that drives the delivery belt 52; the stapler-moving motor 159 that moves the edge stapler S1; the stapler-tilting motor 160 that rotates the edge stapler S1 to tilt; the jogger motor 158 that moves the jogger fences 53; the path-switching drive motor 161 that rotates the switching guide 54 and the movable guide 55; a transport motor (not shown) for driving the transport rollers that convey the sheet stack; a trailing-edge fence moving motor (not shown) that moves the movable fence 73; the folding-plate drive motor 166 that moves the folding plate 74; and a folding-roller drive motor that drives the folding roller pair 81. Pulses of a transport-to-stapler motor (not shown) that drives the discharge roller pair 11 are entered to the CPU 360. The CPU 360 counts the pulses and controls the tapping SOL 170 and the jogger motor 158 in accordance with the number of pulses.
The folding-plate drive motor 166, embodied using a stepping motor, is controlled by the CPU 360 either directly via a motor driver or indirectly via the I/O interface 370 and the motor driver. Because the CPU 360 controls a clutch and a motor of the punching unit 100 as well, perforation is performed in response to a command supplied from the CPU 360.
The CPU 360 controls the sheet finisher PD by executing programs stored in a read only memory (ROM, not shown) using a random access memory (RAM, not shown) as a working area.
Operations of the sheet finisher performed under control of the CPU 360 is described below. According to the embodiment, a sheet is output in the following finishing modes:
Non-stapling mode “a” in which a sheet stack is conveyed to the upper tray 201B via the transport paths A and B
Non-stapling mode “b” in which a sheet stack is conveyed to the shift tray 202 via the transport paths A and C
Sorting-and-stacking mode in which a sheet stack is conveyed to the shift tray 202 via the transport paths A and C, while the shift tray 202 is moved in a direction perpendicular to the sheet output direction alternately back or forth for every set of collated sheets, thereby offsetting each collated sheet set for easy separation;
Stapling mode, in which a sheet stack is conveyed via the transport paths A and D to the edge stapling tray F, in which the sheet stack is aligned and stapled, and thereafter conveyed to the shift tray 202 via the transport path C
Center-stapling-for-booklet-production mode, in which a sheet stack is conveyed via the transport paths A and D to the edge stapling tray F, in which the sheet stack is aligned and stapled, further conveyed to the stapling/folding tray G, in which the sheet stack is folded at its center, and thereafter conveyed to the lower tray 203 via the transport path H. Each mode is described in detail below.
(1) Non-Stapling Mode “a”
A sheet stack is guided by the path-switching flap 15 from the transport path A to the transport path B, and then delivered onto the upper tray 201 by the transport roller pair 3 and a discharge roller pair 4. The discharge sensor 302 positioned near the discharge roller pair 4 detects whether a sheet stack has been output to the upper tray 201.
(2) Non-Stapling Mode “b”
A sheet stack is guided by the path-switching flaps 15 and 16 from the transport path A to the transport path C, and then delivered onto the shift tray 202 by the transport roller pair 5 and the discharge roller pair 6. The discharge sensor 303 provided near the discharge roller pair 6 detects whether a sheet stack has been output.
(3) Sorting-and-Stacking Mode
A sheet stack is conveyed and delivered in the same manner as the non-stapling mode “b.” Simultaneously, the shift tray 202 is moved alternately back or forth in the direction perpendicular to the sheet output direction for every set of collated sheets, thereby offsetting each collated set for easy separation.
(4) Stapling Mode
A sheet stack is guided by the path-switching flaps 15 and 16 from the transport path A to the transport path D, and thereafter delivered onto the edge stapling tray F by the transport roller pairs 7, 9, and 10, and the discharge roller pair 11. The discharge roller pair 11 sequentially delivers sheets into the edge stapling tray F, in which the sheets are aligned. When the number of the thus-stacked sheets reaches a predetermined number, the edge stapler S1 staples the sheet stack. The thus-stapled sheet stack is conveyed downstream by the support lug 52a, and delivered onto the shift tray 202 by the discharge roller pair 6. The discharge sensor 303 provided near the discharge roller pair 6 detects whether a sheet stack has been output.
As shown in
After a lapse of a predetermined period of time since the tapping SOL 170 is turned off, the jogger motor 158 causes each jogger fence 53 to move further inward by 2.6 millimeters, and stop. Thus, widthwise alignment is completed. The jogger fence 53 is thereafter moved outward by 7.6 millimeters to return to the stand-by position, and waits for a subsequent sheet. This operation procedure is repeated up to the last page. Thereafter, each jogger fence 53 is moved inward by 7 millimeters and stopped to restrain the sheet stack at its opposite side ends as a preparation for stapling. Subsequently, after a lapse of predetermined period of time, the edge stapler S1 is driven by a staple motor (not shown) to staple the sheet stack. When stapling at two or more positions is specified, after stapling at a first position is completed, the stapler-moving motor 159 is driven to move the edge stapler S1 along the trailing edge of the sheet to an appropriate position corresponding to a second stapling position, at which the edge stapler S1 staples the sheet stack. This operation procedure is repeated when three or more stapling positions are specified.
After completion of the stapling, the delivery motor 157 is driven to rotate the delivery belt 52. In conjunction therewith, the sheet-output motors are also driven to cause the discharge roller pair 6 to start rotating to receive the stapled sheet stack lifted up by the support lug 52a. In conjunction therewith, the jogger fences 53 are controlled to perform an operation differently depending on a sheet size and the number of sheets to be stapled together. For example, when the number of sheets to be stapled together or the sheet size is smaller than a set value, the support lug 52a conveys the sheet stack, which is being press restrained by the jogger fences 53, by supporting the sheet stack at the trailing edge. When a predetermined number of pulses are detected by the sheet detecting sensor 310 or the HP sensor 311, the jogger fences 53 are retracted by 2 millimeters to release the sheet stack from restraint. The predetermined number of pulses is set to a time duration between a time when the support lug 52a comes into contact with the trailing edge of the sheet stack and a time when the sheet stack advances past the leading edges of the jogger fences 53. On the other hand, when the number of sheets to be stapled together or the sheet size is greater than the set value, the jogger fences 53 are retracted by 2 millimeters in advance, and then the sheet stack is delivered. In any case, at an instant when the stapled sheet stack has advanced past the jogger fences 53, each jogger fence 53 is further moved outward by 5 millimeters to return to the stand-by position to prepare for a subsequent sheet. Alternatively, a restraining force exerted on the sheet stack can be controlled by changing the distance of the jogger fences 53 with respect to a sheet.
(5) Center-Stapling-for-Booklet-Production Mode
With reference to
After being temporarily aligned in the edge stapling tray F, the sheets are lifted up by the support lug 52a as shown in
Thereafter, the support lug 52a conveys the sheets until the trailing edge advances past the output rollers 56. Furthermore, the upper and lower transport-roller pairs 71 and 72 convey the sheets to the position shown in
In the aligning, a stopper (the movable fence 73) and the jogger fences 250 are forcibly pushed by a predetermined distance with respect to paper size (hereinafter, “push distance”). The distance is optimally changed based on size data, sheet-count data, and thickness data. When a stack of sheets is thick, allowance space in the transport paths is reduced, making it difficult to align the sheets in a single aligning. In this case, the aligning is performed repeatedly for an increased number of times, thereby attaining better alignment.
As the number of sheets increases, the longer period of time is required for stacking them sequentially upstream. This lengthens the time until the next stack. Accordingly, even when the aligning is performed more repeatedly, no loss is produced for the system in terms of time, but attains effective and favorable alignment. Thus, as a matter of course, by controlling the number of repetitions to perform the aligning depending on the period of time required by an upstream process, effective alignment can be attained.
Subsequently, the center stapler pairs S2 staple the sheet stack at its center (
The position of the movable fence 73 is determined based on pulses supplied from the movable HP sensor 322, and the position of the tapping tab 251 is determined based on pulses supplied from the HP sensor 326. As shown in
Because the center-folded sheet stack to be subjected to folding is moved upward, the sheet stack can be conveyed without fail only by movement of the movable fence 73. If the sheet stack to be subjected to folding is moved downward, influences imparted by friction and static electricity make it uncertain whether the sheet stack follows the descending movement of the movable fence 73, which deteriorates reliability of conveyance. Accordingly, a method of conveying the sheet stack by descending the movable fence 73 requires another unit, such as another transport roller, which undesirably complicates the structure.
As shown in
According to the mode table shown in
Thus, modes such as the number-of-aligning (
To align a sheet stack in a transport path having a limited space allowance, a stack of sheets which are in close contact with each other is caused to deform in the transport path so that air layers are included between each sheets to facilitate conveyance of the sheets, and eventually to attain alignment. Thus, it is theoretically possible to deform each sheet stack optimally by changing conditions, such as the sheet size, the number of sheets, and thickness of the sheet stack. A key element to attain the optimum deformation is the push distance as defined in the embodiment. When a sheet stack is deformed by a degree greater than that allowed in a limited space of the transport path, the sheet can be scratched, creased, or subjected to other damage. In addition, when a sheet stack is deformed by an excessive degree, the tapping tab 251 (stopper) and the jogger fences 250 (jogger) are overloaded, which can result in breakage of them. On the other hand, deforming a sheet stack by an insufficient degree can result in insufficient alignment of the sheet stack.
When, as in the embodiment, the push distances for the tapping tab 251 (stopper) and the jogger fences 250 (jogger) are set to optimum values in accordance size data, sheet-count data, and thickness data, sheets can be aligned in a vertical transport path.
When a stack of sheets is thick, allowance space in the transport path is reduced, making it difficult to align the sheets in a single aligning. In this case, the aligning is performed repeatedly for an increased number of times, thereby attaining better alignment.
As the number of sheets increases, the longer period of time is required for stacking them sequentially upstream. This lengthens the time until the next stack. Under such a state, even when the aligning is performed more repeatedly, no loss is produced for the system in terms of time, but effective and favorable alignment is attained. Thus, by controlling the number of repetitions to perform the aligning depending on the period of time required by an upstream process, effective alignment can be attained.
According to an embodiment of the invention, an optimum mode can be selected for aligning sheets based on sheet size, the number of sheets, and their thickness. Thus, sheets can be aligned appropriately irrespective of a condition of the sheets.
Although the invention has been described with respect to a specific embodiment for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
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