1. Field of the Invention
The present invention relates to a sheet processing apparatus that is detachably equipped on the main body of an image forming apparatus such as a copying machine or a printer, and to an image forming apparatus equipped with such a sheet processing apparatus. Particularly, the present invention relates to a sheet processing apparatus that can discharge sheets reliably and an image forming apparatus equipped with such a sheet processing apparatus.
2. Related Background Art
Recently, sheet processing apparatuses such as sorters for sorting sheets, on which images have been formed, have been developed as optional apparatuses for image forming apparatuses such as electrophotographic copying machines or laser printers. Such kinds of sheet processing apparatus is designed to perform at least one processing such as sorting, stapling or jogging etc. on sheets.
A sheet processing apparatus having a stapler for stapling sheets is designed in such a way that the stapling operation is performed after the sheets conveyed into the body of the sheet processing apparatus have been made to pass through a conveying path provided in the interior of the body and then stacked on a post-processing tray.
The sheet processing apparatus for stapling a stack of sheets is adapted to place sheets in a stack on the post-processing tray and moving a stapler serving as stapling means to perform stapling at one position or multiple positions (typically, at two positions). During the stapling operation, it is not possible to place the sheets for the next job on the post-processing tray. Consequently, it is necessary to set intervals between sets of sheets on a job by job basis for stapling operations.
However, the intervals set between sheets invites a decrease in productivity. In other words the number of sheets processed per unit time is decreased. A sheet processing apparatus as shown in
The conventional sheet processing apparatus 10 shown in
With the above-described structure, in the conventional sheet processing apparatus 10, sheets conveyed from a sheet discharge roller pair 17 provided in the main body 16 of an image forming apparatus 15 are stored in the buffer roller path 14, so that a set of sheets stored on the buffer roller 13 are conveyed to the post-processing tray 11 after the processing, such as stapling for example, of the preceding set of sheets on the post-processing tray 11 has been completed and the preceding set of sheets has been discharged from the post-processing tray 11 by a rotating upper roller 18a of an oscillation roller pair 18 that holds the sheets in cooperation with a lower roller 18b. Thus, the intervals between sheets are not extended during the stapling operation, and a decrease in productivity can be avoided.
However, with the provision of the buffer roller path 14, this conventional sheet processing apparatus 10 suffers from the problem that it is necessary to arrange an installation space for the buffer roller 13 and the buffer roller path 14 for suspending the conveyance of the succeeding sheets to the post-processing tray 11 so as to keep them in a waiting state during the stapling operation, and so the size and the cost of the sheet processing apparatus are increased.
In addition, in the prior art sheet processing apparatus 10, since sheets are discharged by means of the oscillation roller pair 18, the sheet conveyance rate can vary due to a variation in the friction between the upper roller 18a and the lower roller 18b or a variation in the rotation speed of them, so that a displacement between the upper portion of the sheets and the lower portion of the sheets can occur. Therefore, sheet discharge operation is not stable and there is a variation in the time required for discharging sheets.
Furthermore, even the conventional sheet processing apparatus 10 that is adapted to place the sheet stored in the buffer roller path onto the post-processing tray 11 after the sheets on the post-processing tray 11 have been discharged cannot meet recent requirements for an increase in the processing speed, and an apparatus with a reduced processing time has been demanded.
An object of the present invention is to provide a sheet processing apparatus that can discharge sheets reliably.
Another object of the present invention is to provide an image forming apparatus having an improved productivity with equipment of a sheet processing apparatus that can discharge sheets stable.
According to the present invention that is intended to attain the aforementioned object, there is provided a sheet processing apparatus comprising sheet holding means for holding a plurality of supplied sheets in a stack, first sheet stacking means on which sheets that have been held by the sheet holding means or have passed through the sheet holding means without being held are stacked and subjected to a processing, second sheet stacking means, provided downstream of the first sheet stacking means with respect to a sheet conveying direction, on which sheets are to be stacked, first sheet conveying means for conveying the sheets stacked on the first sheet stacking means to discharge the sheets to the second sheet stacking means, and second sheet conveying means for conveying the sheets stacked on the first sheet stacking means toward the second sheet stacking means, wherein after the sheets stacked on the first sheet stacking means are conveyed by the second sheet conveying means toward the second sheet stacking means by a predetermined amount, the first sheet conveying means conveys the sheets held by the sheet holding means and the sheets stacked on the first sheet stacking means simultaneously under a state in which a downstream edge of the sheet stacked on the first sheet stacking means protrudes in a downstream side beyond a downstream edge of the sheets held by the sheet holding means by a predetermined amount to thereby discharge the sheets stacked on the first sheet stacking means to the second sheet stacking means and to stack the sheets held by the sheet holding means onto the first sheet stacking means.
In the sheet processing apparatus according to the present invention that is intended to attain the aforementioned object, the second sheet conveying means may be adapted to push a trailing edge, with respect to the sheet conveying direction, of the sheets stacked on the first sheet stacking means to thereby convey those sheets.
The sheet processing apparatus according to the present invention that is intended to attain the aforementioned object may further comprise control means for controlling the second sheet conveying means in such a way that the second sheet conveying means conveys the sheets stacked on the first sheet stacking means until the downstream edge of those sheets protrude in the downstream side beyond the downstream edge of the sheets held by the sheet holding means by a predetermined amount.
According to the present invention that is intended to attain the aforementioned object, there is also provided an image forming apparatus comprising image forming means for forming an image on a sheet and a sheet processing apparatus for performing a processing on a sheet on which an image has been formed by the image forming means, wherein the sheet processing apparatus comprises any one of the aforementioned sheet processing apparatus.
The sheet processing apparatus according to the present invention is constructed in such a way that after the sheets stacked on the first sheet stacking means are conveyed by the second sheet conveying means toward the second sheet stacking means by a predetermined amount, the sheets held by the sheet holding means and the sheets stacked on the processing the first sheet stacking means are conveyed simultaneously by the first sheet conveying means so as to be discharged to the second sheet stacking means. Consequently, the overlapping area of the sheet stack and the buffer sheets is reduced by an amount corresponding to the predetermined conveyance amount of the sheet stack, and therefore the sheet stack can be detached from the buffer sheets reliably and discharged to be stacked onto the second sheet stacking means reliably. In addition, since sheets are conveyed by the first sheet conveying means and the second sheet conveying means, the sheets can be discharged quickly without variations in sheet discharge time. Therefore, it is possible to provide an apparatus with reduced processing time.
In the following, a sheet processing apparatus according to an embodiment of the present invention and a copying machine as an example of an image forming apparatus equipped with the sheet processing apparatus will be described with reference to the accompanying drawings. In connection with this, it should be understood that the image forming apparatus includes a copying machine, a facsimile machine, a printer or a multi function machine having combined functions of those machines, and therefore the image forming apparatus to which the sheet processing apparatus according to the present invention is to be equipped is not limited to a copying machine.
In addition, dimensions, numerical values, materials, shapes and relative positions that will be described in connection with the constituent parts of the embodiment will not be intended to limit the scope of the present invention unless otherwise specified.
The following description of the embodiment will be made with reference to a case in which the sheet processing apparatus is an optional apparatus that is adapted to be detachably attached to the main body of an image forming apparatus, as an individual apparatus. However, it is apparent that the sheet processing apparatus according to the present invention may be applied to the case in which the apparatus is integrally provided in an image forming apparatus. Even in that case, the functions of the apparatus are not different from those of the sheet processing apparatus that will be described in the following, and therefore the description of such an apparatus will be omitted.
(Image Forming Apparatus)
The copying machine 100 is composed of a main body of the apparatus 101 and a sheet processing apparatus 119. On the top of the main body 101, there is provided an original feeding apparatus 102. Sheets D are set by a user on an original placement portion 103 and fed to a registration roller pair 105 separately one by one by means of a feeding portion 104. The original D is then stopped temporarily by the registration roller pair 105 and caused to form a loop so that skewed feeding is corrected. After that, the original D is made to pass through a reading position 108 via an introducing path 106, so that the image formed on the surface of the original D is read. Having passed through the reading position 108, the original D is made to pass through a discharge path 107 so as to be discharged onto a discharge tray 109.
In the case that both the front and back sides of the original are to be read, one of the side of the original D is read first when the original passes through the reading position 108 in the above-described manner. After that, the original is made to pass the discharge path 107 and switched back by a reversing roller pair 110 so as to be conveyed to the registration roller pair 105 again under the state in which the sides of the original have been reversed.
Thus, skewed feeding of the original D is corrected by the registration roller pair in the same manner as in the case that the image on one of the sides was read, and then the original is made to pass through the introducing path 106 and the reading position 108, at which the image on the other side of the original D is read. After that, the original D is made to pass through the discharge path 107 so as to be discharged onto the discharge tray 109.
The image on the original D that passes through the reading position 108 is irradiated with light emitted from an illumination system 111. The light reflected from the original is directed by a mirror 112 to an optical element 113 (composed of a CCD or other element), at which image data is generated. A laser beam based on this image data is irradiated onto image forming means in the form of, for example, a photosensitive drum 114, so that a latent image is formed thereon. Alternatively, the apparatus may be constructed in such a way that the reflected light is guided onto the photosensitive drum 114 directly by the mirror 112 to form a latent image, although such a structure is not shown in the drawings.
Toner supplied from a toner supplying apparatus (not shown) is applied to the latent image formed on the photosensitive drum 114, so that a toner image is formed. A cassette 115 stores recording mediums in the form of paper sheets or plastic films etc. A sheet is sent out from the cassette 115 in response to a recording signal and entered into between the photosensitive drum 114 and a transferring device 116 by a registration roller pair 150 at appropriate timing. The toner image on the photosensitive drum 114 is transferred by the transferring device 116 onto the sheet. As the sheet on which the toner image has been transferred passes through a fixing apparatus 117, the toner image is fixed by heat and pressure applied by the fixing apparatus 117.
In the case that images are to be formed on both sides of the recording medium, the sheet on one side of which the image has been fixed by the fixing apparatus 117 is made to pass through a double-side path 118 provided in the downstream of the fixing apparatus 117 and delivered into between the photosensitive drum 114 and the transferring device 116. Thus, an toner image is transferred also on the back side of the sheet. The toner image is fixed in the fixing apparatus 117, and the sheet is discharged to the exterior (i.e. to the finisher 119).
An operation portion 210 is adapted in such a way that sheet size information and information on which processing (for example, stapling) is to be performed on sheets can be entered when a user uses the copying machine. In addition, the operation portion 210 is adapted to display information on the operating state or other information on the main body 101 of the copying machine or the finisher 119 as a sheet post-processing apparatus. A finisher control portion 211 is adapted to control the internal operation of the finisher 119 as a sheet post-processing apparatus. A fax control portion 212 is adapted to control the copying machine to enable the copying machine to function as a facsimile machine so that it can transmit/receive a signal to/from another facsimile machine.
(Sheet Processing Apparatus)
The sheet processing apparatus 119 has a function of binding a sheet stack. The sheet processing unit 119 is provided with stapler units 132 for stapling a sheet stack at positions near the edge of the sheet stack, a stapler 138 for stapling the sheet stack at a central position and a folding unit 139 for folding the sheet stack stapled by the stapler 138 at the stapled position to make the sheet stack into a book-like form.
The sheet processing apparatus 119 according to the embodiment is provided with a buffer unit 140 for storing (i.e. buffering) a plurality of sheets stacked in a straight (or flat) state during the operation of the stapler units 132.
Since the buffer unit 140 is adapted to store a plurality of sheets stacked in a straight state, the buffer unit 140 can be formed in a flat shape unlike conventional structures such as the structure including the buffer roller 13 shown in
The sheet processing apparatus 119 is controlled by a finisher control portion 211 shown in
Incidentally, the CPU control circuit portion 200 and the finisher control portion 211 shown in
Since the lower roller 127b and the return roller 130 are rotated commonly by the stock delivery motor M3, when a sheet or a stack of sheets are conveyed by the lower roller 127b and the return roller 130, the sheet or the stack of sheets can be wrinkled or broken if slippage occurs or a difference in the sheet conveying speed is generated between both the rollers. The under-stack clutch CL shown in
(Description of Sheet Stack Stapling and Discharging Operation)
When a sheet stapling operation is selected by a user through the display on the operation portion 210 (shown in
The description of the operation with reference to
The finisher control portion 211 activates the inlet conveyance motor M2 and the stack delivery motor M3 based on the sheet stapling operation signal. The finisher control portion 211 also activates a buffer roller separating plunger SL1 (shown in
The first sheet delivered from the discharge roller pair 120 of the main body 101 of the copying machine 100 (shown in
As shown in
The sheet P1 is conveyed further with the rotation of the first sheet discharge roller pair 126 as shown in
At that time, the upper roller 127a and the lower roller 127b have already been rotated in the respective direction indicated by arrows by the stack delivery motor M3 (shown in
As shown in
Subsequently, the succeeding sheets are placed on the processing tray 129 in the same manner. As shown in
In the following, an operation of the sheet processing apparatus is described with reference to the flow chart of
As shown in
As shown in
In the above-described operation, if as shown in
However, in some cases as shown in
With the difference ΔT in the activation time, the oscillation roller pair 127 and the trailing edge assist 134 can discharge the sheet stack without applying a tensile or compressive force to the sheet stack even if there is a difference in the initial speed between the oscillation roller pair 127 and the trailing edge assist 134. In addition, deterioration in quality of the sheet stack or in quality of images on the sheets in the stack due to a roller trace of the oscillation roller pair 127 can be avoided.
The sheet discharge of the sheet stack toward the stack tray 128 is started by the oscillation roller pair 127, the trailing edge assist 134 and the return roller 130 (S108). When the trailing edge assist has been moved about 15 mm (S109), it is returned back to its original position (or the home position) (S110, which operation corresponds to HP delivery control shown in
Referring to
In the sheet processing apparatus 119 according to this embodiment, since the trailing edge assist 134 is adapted to push the trailing edge of the sheet stack to convey it, the sheet stack can be conveyed reliably without the surface of the sheet stack being damaged unlike the case in which the sheet stack is discharge by a rotating roller that is pressed against the surface of the sheet stack.
(Description of Buffer Operation)
The above description has been directed to the case in which for example the conveyance interval between sheets is so large that the stapling operation can be performed on a sheet stack while the next sheet is delivered. On the other hand, the following description will be directed to a buffer operation in which the conveyance interval between sheets is small and when the succeeding sheets are delivered while the stapling operation is performed on a sheet stack, the succeeding sheets are stored (i.e. buffered) during that stapling operation.
The sheet processing apparatus 119 performs the buffer operation based on a buffer operation command by the finisher control portion 211 when it is determined by the CPU circuit portion 200 that an interval between sheets delivered from the main body 101 of the copying machine 100 is shorter than the time required for the sheet stapling operation. In that case, the buffer roller 124 is lowered by the plunger SL1 (shown in
In
As shown in
When the trailing edge of the sheet P1 reaches the switchback point SP as shown in
After the downstream edge of the sheet P1 is detected, the upstream edge portion of the sheet P1 is received by the trailing edge receiving portion 136 as shown in
After that, the second sheet P2 is delivered as shown in
At that time, the first sheet P1 is being pressed against the lower conveyance guide plate 123b together with the second sheet P2 by means of the buffer roller 124. Consequently, the first sheet P1 is disposed to follow the second sheet P2 under conveyance to move toward the downstream. However, the first sheet P1 is not actually moved, since it is pressed against the lower conveyance guide plate 123b by the friction member 141 provided on the trailing edge retention 135.
The second sheet P2 is also returned toward the upstream when the trailing edge of the second sheet P2 reaches the switchback point SP as shown in
After that, when the third sheet P3 is delivered and the trailing edge of the third sheet P3 passes through the inlet roller pair 121 as shown in
As shown in
After that, the three sheets P1, P2 and P3 and the sheet stack P are conveyed while held between the oscillation roller pair 127. When the sheet stack P is discharge onto the stack tray 128 as shown in
Under the state shown in
The three sheets are conveyed by the oscillation roller pair 127 and the return roller 130 to slide down on the processing tray 129 as shown in
Although the above description has been made with reference to the case in which three sheets are stored on the lower conveyance guide plate 123b, the number of the stored sheets (i.e. buffer sheets) is not limited to three, but it may be varied depending on the length of the sheets, the time required for the stapling operation, the sheet conveying speed or other factors.
As described in the foregoing, the sheet processing apparatus 119 according to this embodiment is designed in such a way that under the state shown in
If it is assumed that the protruding length of the downstream edge of the sheet stack P is L1 that is shorter than L, the protruding length of the upstream edge of the third sheet P3 is also L1. Therefore, the length of the portion at which the three buffer sheets are held by the oscillation roller pair 127 after the sheet stack P is discharged onto the stack tray 128 becomes short and the oscillation roller pair 127 might fail to hold the three buffer sheets. Thus, the three buffer sheets cannot be delivered to the processing tray 129 reliably. In view of this, the apparatus is constructed in such a way that the sheet stack P protrudes beyond the downstream edge P3a of the sheet P3 by length L so that the buffer sheets are held reliably by the oscillation roller pair 127 so as to be delivered to the processing tray 129.
In addition, if the aforementioned protruding length is short, the contact area of the buffer sheets and the sheet stack becomes large and the sheet stack is in close contact with the buffer sheets, so that falling of the sheet stack onto the stack tray 128 might be delayed. In that case, when the rotation of the oscillation roller pair 127 is reversed to convey the buffer sheets to the processing tray 129, the sheet stack might enter the oscillation roller pair 127 while closely attached to the buffer sheets, whereby the sheet stack might be damaged or jam might occur. In view of this, the apparatus is constructed in such a way that the sheet stack P protrudes beyond the downstream edge P3a of the sheet P3 by length L so that detachability of the sheet stack and the buffer sheets can be improved.
As per the above, the apparatus is constructed in such a way that after the sheet stack P stacked on the first sheet stacking means in the form of, for example, the processing tray 128 is conveyed by the second sheet conveying means in the form of, for example, the trailing edge assist 134 toward the second sheet stacking means in the form of, for example, the stack tray 128 by a predetermined amount, the buffer sheets P1, P2 and P3 held by the sheet holding means in the form of, for example, the buffer unit 140 and the sheets stacked on the processing tray 129 are conveyed simultaneously by the first sheet conveying means in the form of, for example, the oscillation roller pair 127 so as to be discharged onto the stack tray 128. Consequently, the overlapping area of the sheet stack and the buffer sheets is reduced by an amount corresponding to the predetermined conveyance amount (e.g. length L) of the sheet stack, and therefore the sheet stack can be detached from the buffer sheets reliably and discharged to be stacked onto the stack tray reliably.
Furthermore, the sheet processing apparatus is constructed in such a way that the trailing edge of the sheet stack is pushed by the trailing edge assist 134. In the case that the trailing edge of the sheet stack is pushed by the trailing edge assist 134 so as to be conveyed as above, the sheet can be conveyed reliably without the surface of the sheet being damaged, unlike the case in which the sheet is conveyed to be discharged by a rotating roller that is brought into pressure contact with the surface of the sheet stack.
Specifically, in the case that the sheet stack is discharged only by the oscillation roller 127 as shown in
The aforementioned events are liable to occur when the sheet stack holding pressure of the oscillation roller pair 127 is increased with a view to reliably discharge the sheet stack. In contrast, when the holding pressure is decreased, it is not possible to convey the sheet stack reliably. Therefore, it is difficult to set the holding pressure of the oscillation roller pair 127 appropriately.
In view of the above, the sheet processing apparatus is constructed in such a way that the sheet stack is discharged not only by the oscillation roller pair 127 but also the trailing edge assist 134. Thus, the aforementioned slippage of the rotating roller against the sheet or the twisting of the sheet stack can be avoided, so that the sheet stack can be discharged smoothly and quickly without the sheets or sheet stack being damaged. In addition the sheet stack can be discharged without need for strict control of the holding pressure of the oscillation roller pair 127.
Although the above description of the sheet processing apparatus has been made with reference to the case in which the buffer unit 140 for storing (or buffering) a plurality of sheets in a straight state during the operation of the stapler 132 is provided, the present invention can be applied to the apparatus provided with a buffer roller unit having a buffer roller 13 and a buffer roller path as shown in
Although in the above description has been made with reference to the case in which the sheet position is detected by a sensor, the sheet position may be determined based on a sheet storage information (memory information) controlled in the CPU 221.
In addition, although the above sheet processing apparatus 129 is adapted to staple the sheet stack after trailing edge alignment and width alignment for aligning the sheet stack from both sides have been performed, the sheet stack may be discharged onto the stack tray 128 directly after the width alignment and the trailing edge alignment without being stapled.
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Number | Date | Country | |
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20080143034 A1 | Jun 2008 | US |
Number | Date | Country | |
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Parent | 11555705 | Nov 2006 | US |
Child | 12034114 | US | |
Parent | 10790001 | Mar 2004 | US |
Child | 11555705 | US |