This patent application is based on and claims priority pursuant to 35 U.S.C. ยง 119 to Japanese Patent Applications No. 2018-050397, filed on Mar. 19, 2018, and No. 2019-010038, filed on Jan. 24, 2019 in the Japanese Patent Office, the entire disclosure of which is hereby incorporated by reference herein.
This disclosure relates to a sheet processing apparatus and an image forming system incorporating the sheet processing apparatus.
The image forming system is known that includes an image forming apparatus to form an image on a sheet and a sheet processing apparatus including a skew correction member to correct a sheet skew by contacting the sheet sent from the image forming apparatus and performing predetermined processing on the skew-corrected sheet.
This specification describes an improved sheet processing apparatus that includes an entry portion, a sheet conveyance path extending from the entry portion, a skew correction roller pair that contacts a leading edge of a sheet conveyed in a predetermined direction from the entry portion to correct skew of the sheet, and a receiving path. The skew correction roller pair conveys the skew-corrected sheet in a direction opposite the predetermined direction. The receiving path branches from the sheet conveyance path from the entry portion to the skew correction roller pair to receive the sheet conveyed in the direction opposite the predetermined direction.
This specification further describes an improved image forming system that includes an image forming apparatus to form an image on a sheet, a sheet processing apparatus disposed in an internal ejection section of the image forming apparatus that ejects the sheet on which an image is formed in a space formed inside the image forming apparatus, and circuitry. The sheet processing apparatus includes an entry portion coupled to the image forming apparatus, a skew correction roller pair that contacts a leading edge of a sheet conveyed in a predetermined direction from the entry portion to correct skew of the sheet and conveys the skew-corrected sheet in a direction opposite the predetermined direction, a receiving path branched from a sheet conveyance path from the entry portion to the skew correction roller pair to receive the sheet conveyed in the direction opposite the predetermined direction, and a plurality of conveyance rollers to convey the sheet. After a leading edge of the sheet leaving an end portion in the image forming apparatus contacts the skew correction roller pair, the circuitry controls the plurality of conveyance rollers to convey a whole of the sheet in the sheet processing apparatus and controls the skew correction roller pair to convey the sheet in the direction opposite the predetermined direction to the receiving path.
This specification still further describes an improved image forming system that includes an image forming apparatus to form an image on a sheet and a sheet processing apparatus to overlay a following sheet sent from the image forming apparatus and leaving an end portion of the following sheet in the image forming apparatus on a preceding sheet and, subsequently, perform a predetermined process on the sheets.
The aforementioned and other aspects, features, and advantages of the present disclosure would be better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
The accompanying drawings are intended to depict embodiments of the present disclosure and should not be interpreted to limit the scope thereof. The accompanying drawings are not to be considered as drawn to scale unless explicitly noted.
In describing embodiments illustrated in the drawings, specific terminology is employed for the sake of clarity. However, the disclosure of this specification is not intended to be limited to the specific terminology so selected and it is to be understood that each specific element includes all technical equivalents that have a similar function, operate in a similar manner, and achieve a similar result.
Although the embodiments are described with technical limitations with reference to the attached drawings, such description is not intended to limit the scope of the disclosure and all of the components or elements described in the embodiments of this disclosure are not necessarily indispensable.
Referring now to the drawings, embodiments of the present disclosure are described below. In the drawings illustrating the following embodiments, the same reference numbers are allocated to elements having the same function or shape and redundant descriptions thereof are omitted below.
The image forming apparatus 3 forms an image on a sheet based on image data that is input to the image forming apparatus 3 or obtained by scanning. The image forming apparatus 3 may be, for instance, a copier, a printer, a facsimile machine, or a multifunction peripheral having at least two of these functions. The image forming apparatus 3 may use any known image forming method, such as electrophotography or droplet discharge. The image forming apparatus 3 in the present embodiment is a copier using the electrophotography.
Examples of the post-processing apparatus 2 include a punch apparatus that punches a hole in the sheet, a sheet binding apparatus in which a stapler or the like binds sheets and make a sheet bundle, and a sorter that sorts and ejects a sheet on which an image formed into each of a plurality of ejection trays.
The image forming unit 110 includes photoconductor drums 200Y, 200C, 200M, and 200K for respective colors of the image forming stations 111Y, 111C, 111M, and 111K. Chargers 80Y, 80C, 80M, and 80K, developing devices 70Y, 70C, 70M, and 70K, cleaning units 40Y, 40C, 40M, and 40K, and electric charge removing units are disposed along the outer peripheries of the photoconductor drums 200Y, 200C, 200M, and 200K, respectively. The image forming apparatus main body 101 also includes an intermediate transfer belt 112 onto which the images formed on the photoconductor drums 200Y, 200C, 200M, and 200K are transferred by primary transfer rollers 74Y, 74C, 74M, and 74K and the optical writing device 180 to write respective color images on the photoconductor drums 200Y, 200C, 200M, and 200K.
The optical writing device 180 is disposed below the image forming stations 111Y, 111C, 111M and 111K, and the intermediate transfer belt 112 is disposed above the image forming stations 111Y, 111C, 111M and 111K. Toner storage containers 116Y, 116C, 116M, and 116K containing toner for replenishing to the developing devices 70Y, 70C, 70M, and 70K are disposed above the image forming unit 110 in an exchangeable manner.
As illustrated in
Meanwhile, an image forming process performed by a tandem color image forming apparatus using an indirect transfer method is known and is not directly related to the present disclosure; accordingly, a detailed description thereof is omitted herein.
The feeder 120 includes a sheet feed tray 121, a pick-up roller 122, and a feeding conveyance roller 123 and feeds the sheet P picked up from the sheet feed tray 121 upward along the feed conveyance path 130.
An image is transferred to the fed sheet P in the secondary transfer section 140, and the sheet P is fed into the fixing device 150. The fixing device 150 includes a fixing roller 150a and a pressure roller 150b, and heat and pressure are applied in a process in which the sheet P passes through the nip between the fixing roller 150a and the pressure roller 150b, and the toner is fixed on the sheet P.
Downstream from the fixing device 150, the ejection conveyance path 160 and the duplex copy conveyance path 170 are disposed, both of which are branched in two directions by a bifurcating claw 161 that selects whether the sheet P is conveyed to a conveyance path to the folding apparatus 1 or the duplex copy conveyance path 170.
Bifurcating conveyance rollers 162 are disposed immediately upstream of the bifurcating claw 161 in a sheet conveyance direction to apply a conveyance force to the sheet.
The folding apparatus 1 is disposed in an internal ejection section in the image forming apparatus main body 101, folds the image formed sheet P conveyed from the image forming apparatus main body 101, and ejects the sheet P to the post-processing apparatus 2.
The image scanner 500 is a known apparatus that scans a document placed on an exposure glass 501 with light to read an image on the document. The configuration and function of the image scanner 500 are known and are not directly related to the present disclosure; accordingly, a detailed description thereof is omitted herein.
In the image forming apparatus main body 101 configured as described above, image data to use image writing is generated based on original document data read by the image scanner 500 or print data sent from an outer personal computer (PC). Based on the data, the optical writing device 180 optically writes an electrostatic latent image on each of the photoconductor drums 200Y, 200C, 200M, and 200K. Respective color images formed in the image forming stations 111Y, 111C, 111M, and 111K are successively transferred onto the intermediate transfer belt 112, and a color image on which four color images are superimposed is formed on the intermediate transfer belt 112.
On the other hand, the sheet P is fed from the sheet feed tray 121 in accordance with the image formation. The sheet P is temporarily stopped at a position of a registration roller right in front of the secondary transfer section 140, is fed in synchronization with a leading edge of an image on the intermediate transfer belt 112, is secondarily transferred by the secondary transfer section 140, and is fed into the fixing device 150.
The sheet P on which the image is fixed by the fixing device 150 is conveyed, by the switching operation of the bifurcating claw 161, to the ejection conveyance path 160 after single-sided printing and completion of duplex printing. Or the sheet P is conveyed to the duplex copy conveyance path 170 after single-sided printing of the duplex printing.
The sheet P conveyed to the duplex copy conveyance path 170 is inverted, conveyed to the secondary transfer section 140 again, and, after an image is formed on the other surface of the sheet P, returned to the ejection conveyance path 160.
The sheet P conveyed to the ejection conveyance path 160 is conveyed to the folding apparatus 1, folded by the folding apparatus 1, or ejected to the post-processing apparatus 2 without folding processing. A controller 40 controls the operation of the above-described parts and the operation of parts described later.
An entry roller pair 10 is disposed on the right side of the folding apparatus 1 in
In addition, a skew correction roller pair 11 serving as a first conveyer is disposed downstream from the entry roller pair 10 on the through-conveyance path W1. The skew correction roller pair 11 includes a skew correction pressing roller 11a that is a rotating member and a skew correction driving roller 11b that is an opposing member. A driving force of a skew motor 11M that is a driving source rotatable in reverse drives and rotates the skew correction driving roller 11b.
In addition, there is a first folding roller 12, a first forward and reverse rotation roller 13 disposed in contact with the first folding roller 12, and a pressing roller 14 disposed in contact with the first forward and reverse rotation roller 13 on an exit side, which is the left side in
Additionally, in the present embodiment, a second folding roller 15 is disposed in contact with the first forward and reverse rotation roller 13 on an exit side of the bifurcation conveyance path W2. On the bifurcation conveyance path W2, the second forward and reverse rotation roller pair 16 is disposed opposite the second folding roller 15 with respect to the nip between the first folding roller 12 and the first forward and reverse rotation roller 13 to which the sheet p enters from the through-conveyance path W1. The second forward and reverse rotation roller pair 16 includes a second forward and reverse pressing roller 16a that is a rotating member and a second forward and reverse driving roller 16b that is an opposing member. A driving force of a second motor 16M that is a driving source rotatable in reverse drives and rotates the second forward and reverse driving roller 16b.
A driving force of a first motor 13M can drive and rotate the first forward and reverse rotation roller 13 so that the first forward and reverse rotation roller 13 can rotate forward and reverse. All of the first folding roller 12, the pressing roller 14 and the second folding roller 15 which are disposed in contact with the first forward and reverse rotation roller 13 are driven rollers that are driven to rotate by the first forward and reverse rotation roller 613.
The driving force of the second motor 16M that is rotatable in reverse can drive and rotate the second forward and reverse rotation driving roller 16b that configures the second forward and reverse rotation roller pair 16. The second forward and reverse pressing roller 16a of the second forward and reverse rotation roller pair 16 is a driven roller that is driven to rotate by the second forward and reverse driving roller 16b.
Additionally, in the present embodiment, a switchback conveyance roller pair 17 is disposed on the switchback conveyance path W3. The switchback conveyance roller pair 17 includes a switchback conveyance pressing roller 17a that is a rotating member and a switchback conveyance driving roller 17b that is an opposing member. A driving force of a switchback motor 17M that is a driving source drives and rotates the switchback conveyance forward and reverse driving roller 17b.
In addition, a film 18 is disposed at a fork between the switchback conveyance path W3 and the through-conveyance path W1. The leading end of the film 18 is set on the side of the through-conveyance path W1 as illustrated in
The pressure springs 10s, 11s, 12s, 14s, 15s, 16s and 17s serving as the pressure members press roller shafts of all driven rollers 10a, 11a, 12, 14, 15, 16a, and 17b to form nips between the driven rollers 10a, 11a, 12, 14, 15, 16a, and 17b and the respective opposing rollers.
In the present embodiment, an entry sensor 24 as a sheet end detector to detect the end of the sheet P is disposed on the upstream side of the entry roller pair 10 in the sheet conveyance direction, which is the entrance side of the through-conveyance path W1. The entry sensor 24 outputs to a controller a detection signal indicating that the leading edge and trailing edge of the sheet P conveyed from the image forming apparatus 3 reaches the detection area of the entry sensor 24. As the entry sensor 24, a known sensor can be used.
A skew sensor 21 as a sheet end detector to detect the end of the sheet P is disposed on the upstream side of the skew correction roller pair 11 in the sheet conveyance direction, which is near the center of the through-conveyance path W1. The skew sensor 21 outputs to a controller a leading-edge detection signal indicating that the leading edge of the sheet P conveyed from the image forming apparatus 3 reaches the detection area of the skew sensor 21. As the skew sensor 21, a known sensor can be used.
In the present embodiment, a sheet detector 22 functioning as a sheet leading edge detector to detect the leading edge of the sheet P is disposed on the downstream side of the second conveyer configured by the first forward and reverse rotation roller 13 and the pressing roller 14 in the sheet conveyance direction, which is the exit side of the through-conveyance path W1. The sheet detector 22 outputs to the controller a leading-edge detection signal indicating that the leading edge of the sheet P conveyed from the through-conveyance path W1 reaches the detection area of the sheet detector 22. Similar to the above-described skew sensor 21, as the sheet detector 22, a known sensor can be used.
In the present embodiment, a sheet detector 26 to detect the leading edge of the sheet P is disposed downstream from the second forward and reverse rotation roller pair 16 in the sheet conveyance direction, which is opposite side of the exit of the bifurcation conveyance path W2. The sheet detector 26 outputs the controller a leading-edge detection signal indicating that the leading edge of the sheet P conveyed from the through-conveyance path W1 to the bifurcation conveyance path W2 reaches the detection area of the sheet detector 26. Similar to the entry sensor 24, the skew sensor 21, and the sheet detector 22 which are described above, a known sensor can be used as the sheet detector 26.
In the present embodiment, a second conveyance unit is configured by the first forward and reverse rotation roller 13 and the pressing roller 14, and a folded portion forming unit is configured by the first folding roller 12 and the first forward and reverse rotation roller 13. Additionally, in the present embodiment, the folded portion forming unit is configured by the first forward and reverse rotation roller 13 and the second folding roller 15.
As the second conveyance unit, an adhesion roller or an attraction belt may be adopted instead of the above-described roller pair. In the present embodiment, the second conveyance unit including the first forward and reverse rotation roller 13 and the folded portion forming unit including the first forward and reverse rotation roller 13 and the second folding roller 15 has the common roller. However, the second conveyance unit and the folded portion forming unit are not limited by the above-described configuration and may be an independent structure configured by different rollers.
In the present embodiment, the switchback conveyance path W3 is connected to the bifurcation conveyance path W2. This can reduce a size of the folding apparatus 1 because it is possible to double the conveyance path of the sheet entering the second forward and reverse rotation roller pair 16 on the bifurcation conveyance path W2 and a part of the switchback conveyance path W3.
Next, a flow and operation of the folding processing for forming the folded portion on the sheet P by the folding apparatus 1 is described.
The folding apparatus 1 of the present embodiment can form two outer folded portions for the sheet P to perform Z-folding processing that folds the sheet P like a letter Z as illustrated in
Firstly, the skew sensor 21 detects the leading edge of the sheet P delivered from the ejection roller in the image forming apparatus 3 to the entry roller pair 10 and given a conveyance force by the entry roller pair 10 to be conveyed in a predetermined direction, which is called a regular conveyance. The controller receives the leading-edge detection signal output from the skew sensor 21 and controls the skew motor 11M to start rotations of the skew correction roller pair 11 as illustrated in
The leading edge of the sheet P conveyed on the through-conveyance path W1 enters the nip between the first forward and reverse rotation roller 13 and the pressing roller 14. After the leading edge of the sheet P passes through the nip, the sheet detector 22 detects the leading edge of the sheet P. The controller 40 receives the leading-edge detection signal from the sheet detector 22 which has detected the leading edge of the sheet P and performs the following control. That is, the controller 40 controls the first motor 13M to stop the rotation of the first forward and reverse rotation roller 13 when leading edge of the sheet P protrudes by a predetermined protrusion amount from the nip between the first forward and reverse rotation roller 13 and the pressing roller 14 as illustrated in
The protrusion amount is set depending on the length of the sheet P in the sheet conveyance direction and the content of the folding processing, such as the manner of folding. The controller can obtain the protrusion amount of the leading edge of the sheet P from, for example, a rotation amount of the pressing roller 14 from when the controller receives the leading-edge detection signal output from the sheet detector 22.
After the sheet P protrude by the predetermined protrusion amount, the controller controls the first motor 13M to start a reverse rotation of the first forward and reverse rotation roller 13 which returns the sheet P to the entrance side of the through-conveyance path W1 and the skew motor 11M to start the rotation of the skew correction roller pair 11. As illustrated in
The first folded portion of the sheet P enters a nip of the second forward and reverse rotation roller pair 16 and is detected by the sheet detector 26 after the first folded portion passes through the nip. The controller 40 receives the leading-edge detection signal from the sheet detector 26 which has detected the leading edge of the sheet P and performs the following control. That is, the controller 40 controls the first motor 13M to stop the rotation of the first forward and reverse rotation roller 13 when the first folded portion of the sheet P protrudes by a predetermined protrusion amount from a position of the nip between the second forward and reverse rotation roller pair 16 as illustrated in
After the sheet P protrudes by the predetermined protrusion amount, the controller 40 controls the second motor 16M to start a reverse rotation of the second forward and reverse rotation roller pair 16 which conveys the sheet P to the exit side of the bifurcation conveyance path W2, the first motor 13M to start the reverse rotation of the first forward and reverse rotation roller 13 again, and the skew motor 11M to start the rotation of the skew correction roller pair 11 again. As illustrated in
As illustrated in
Although both the inner three-fold processing and the outer three-fold processing are similar to the above-described Z-folding processing, the protrusion amounts are different. Therefore, the timing of starting the reverse rotation of the first forward and reverse rotation roller 13 and the second forward and reverse rotation roller pair 16 is different between the Z-folding processing, the inner three-fold processing, and the outer three-fold processing.
Next, the sheet overlay process is described. In the present embodiment, the folding apparatus 1 can overlay a plurality of sheets and folds the overlaid plurality of sheets.
As illustrated in
In the present embodiment, as illustrated in
The skew sensor 21 detects the leading edge of the sheet (Yes in step S2 of
Specifically, when the skew sensor 21 detects the leading edge of the sheet, the controller starts time measurement and rotates the skew correction roller pair 11 in the predetermined direction at a predetermined time. The predetermined time is the time from when the skew sensor 21 detects the leading edge of the sheet to when the leading edge of the sheet contacts the skew correction roller pair, and the sheet P bends a predetermined amount to complete the skew correction.
Next, as illustrated in
Next, the skew motor 11M, the first motor 13M, and the switchback motor 17M rotates in reverse to convey the sheet in the reverse direction, that is, convey the sheet in the opposite direction to the predetermined direction, which is called reverse conveyance, in step S6 of
When the sheet P is conveyed in the reverse direction, that is, the opposite direction to the predetermined direction, the film 18 guides the trailing edge of the sheet in the regular direction, that is, the predetermined direction to convey the sheet to the switchback conveyance path W3 as illustrated in
Next, the switchback motor 17M rotates forward by a predetermined conveyance amount, and the leading edge of the sheet P contacts the skew correction roller pair to perform the skew correction.
Next, as illustrated in
In the present embodiment, as described above, since the sheet conveyance length L1 from the entry portion H to the skew correction roller pair 11 is shorter than the length of the sheet in the sheet conveyance direction, as illustrated in
As described above, after the skew correction of the following sheet P2 by the skew correction roller pair 11 and the overlay process that overlays the following sheet P2 on the preceding sheet P1, the skew correction roller pair 11 conveys the overlaid following sheet P2 and the preceding sheet P1 in step S11 of
On the other hand, when a number of overlaid sheets is less than the number of sheets set by the user (No in step S12), the steps after step S5 are executed again.
In the present embodiment, as illustrated in
In the present embodiment, the folding apparatus 1 includes the switchback conveyance path W3 to receive the preceding sheet P1 conveyed in the reverse direction. Therefore, the preceding sheet P1 conveyed in the reverse direction does not enter the image forming apparatus 3 though the sheet conveyance length L1 from the entry portion H to the nip between the skew correction roller pair 11 is smaller than the length of the sheet in the sheet conveyance direction.
In the present embodiment, the leading edge of the preceding sheet in the regular direction, that is, the predetermined direction is positioned before the skew correction roller pair 11 in switchback conveying, that is, conveying the sheet in the reverse direction. This provides certain advantages compared to a technique in which the preceding skew-corrected sheet by the skew correction roller pair 11 is conveyed in the regular direction, that is, the predetermined direction and looped one round, and the leading edge of the preceding sheet in the regular direction is positioned before the skew correction roller pair 11. When the preceding sheet is looped one round and returned before the skew correction roller pair 11, a large curvature of a loop formed by the preceding sheet prevents satisfactory conveyance, so it is necessary to reduce the curvature of the loop. As a result, the conveying path length of one round of the loop is somewhat longer than the length of the sheet in the conveyance direction. As a result, in the above-described technology, after the trailing edge of the sheet has passed through the skew correction roller pair 11, the preceding sheet is conveyed to some extent, and the leading edge of the preceding sheet is positioned before the skew correction roller pair 11.
When the sheet is sandwiched by the skew correction roller pair 11, the skew correction can be kept, but, after the trailing edge of the sheet passes through the skew correction roller pair 11, other conveyance roller pairs may affect and increase the skew of the sheet. As described above, since the technology in which the sheet is looped one round and returned to the skew correction roller pair conveys the sheet to some extent after the sheet passes through the skew correction roller pair, the amount of the skew may increase while the sheet is conveyed to some extent.
The preceding sheet is bent and contacts the skew correction roller pair 11 to correct the skew, but too much bending amount of the sheet for the skew correction may cause the preceding sheet to block the conveyance path and obstruct conveyance of the following sheet, which results in conveyance failure. Therefore, the bending amount of the sheet cannot be increased, and the amount of skew that can be corrected is limited. Therefore, the technology in which the sheet is looped one round and returned to the skew correction roller pair may increase the amount of skew, does not perfectly correct the skew, and may leave the skew.
In the present embodiment, since switchback conveying returns the preceding sheet before the skew correction roller pair 11, the preceding sheet returns before the skew correction roller immediately after the leading edge of the preceding sheet in the regular conveyance passes through the skew correction roller pair 11. Since the preceding sheet is hardly conveyed after passing through the skew correction roller pair 11, and stopped the conveyance, the preceding sheet does not greatly skew. Therefore, skew correction after the preceding sheet returns before the skew correction roller pair 11 can correct the skew enough and satisfactorily overlay the following sheet on the preceding sheet.
Preferably, the timing of stopping the sheet when the switchback conveying returns the preceding sheet before the skew correction roller pair 11 is immediately after the leading edge of the preceding sheet in the regular conveyance that is the conveyance in the predetermined direction passes through the skew correction roller pair 11, and the reverse conveyance that is conveyance in the opposite direction to the predetermined direction preferably stops before the distance from the skew correction roller pair 11 to the leading edge of the preceding sheet in the regular direction becomes at least 5 mm.
When a plurality of sheets is overlaid and folded, the positions of the folded portions may be different for each sheet. To align the positions of the folded portions, the preceding sheet may be stopped in the switchback conveying when the leading edge of the preceding sheet in the regular direction, that is, the predetermined direction is sandwiched by the skew correction roller pair 11, which forms a predetermined gap in the sheet conveyance direction between the preceding sheet and the following sheet overlaid the preceding sheet. Since the preceding sheet is stopped in the switchback conveying when the leading edge of the preceding sheet in the regular direction, that is, the predetermined direction is sandwiched by the skew correction roller pair 11 and does not separate from the skew correction roller pair 11, the skew of the preceding sheet does not occur in this switchback conveying. This can improve the productivity and shorten time for control in the overlay process compared to the over lay process in which the preceding sheet is conveyed to form the predetermined gap between the preceding sheet and the following sheet overlaid the preceding sheet after the preceding sheet contacts the skew correction roller pair to correct the skew and the leading edge of the preceding sheet is sandwiched.
First Variation
Next, a description is given of a folding apparatus 1 according to variations.
As illustrated in
On the other hand, when the folding processing is performed, the stopper 28 is positioned on the through-conveyance path W1 and moved to a position corresponding to a type of the folding processing in a direction of an arrow D in the
As illustrated in
In the configuration of the above embodiment, after the first forward and reverse rotation roller 13 rotates forward and conveys the sheet by a predetermined amount, the first forward and reverse rotation roller 13 stops conveyance of the sheet and rotates in reverse to bend the sheet, and the bend of the sheet enters the nip between the first folding roller 12 and the first forward and reverse rotation roller 13. However, in the first variation, the first forward and reverse rotation roller 13 does not need to rotate forward and convey the sheet, and it is enough for the first forward and reverse rotation roller 13 to rotate in reverse at a predetermined timing. Since the first forward and reverse rotation roller 13 does not need to stop the conveyance of the sheet to switch from forward rotation drive to reverse rotation drive, the first variation can shorten the folding processing time and improve the productivity.
Second Variation
The folding apparatus of the second variation includes a second stopper 29 instead of the second forward and reverse rotation roller pair 16 of the folding apparatus of the first variation to further improve the productivity. Unlike the stopper 28 described above, the second stopper 29 cannot retract from the conveyance path and can move only in the sheet conveyance direction. When the folding processing is performed, the second stopper 29 is moved in the sheet conveyance direction to position the second stopper 29 at the position corresponding to the type of the folding processing.
As illustrated in
The first folded portion of the sheet P passes through the nip between the first folding roller 12 and the first forward and reverse rotation roller 13, enters the bifurcation conveyance path W2, is conveyed to the second stopper 29 on the bifurcation conveyance path W2, and, as illustrated in
In the present embodiment, after the second forward and reverse rotation roller pair 16 rotates forward and conveys the sheet by a predetermined amount, the second forward and reverse rotation roller pair 16 stops conveyance of the sheet and rotates in reverse to bend the sheet, and the bend of the sheet enters the nip between the second folding roller 15 and the first forward and reverse rotation roller 13. However, the second variation that includes the stopper instead of the second forward and reverse rotation roller pair 16 can bend the sheet and lead the bend of the sheet to enter the nip between the second folding roller 15 and the first forward and reverse rotation roller 13 without stopping the conveyance of the sheet. This shortens the folding processing time and improves productivity.
Third Variation
The folding apparatus according to the third variation illustrated in
As illustrated in
Next, as illustrated in
As illustrated in
As illustrated in
Subsequently, the second folded portion is formed by two types of folding processing, that is, folding processing illustrated in
In the folding processing illustrated in
The folding processing illustrated in
Since the folding apparatus 1 according to the third variation does not include the skew correction roller pair, the number of parts can be reduced, and the cost of the folding apparatus and the size of the folding apparatus can be reduced.
Fourth Variation
As illustrated in
In the fourth variation, the leading edge of the sheet contacts the nip between the first forward and reverse rotation roller 13 and the pressing roller 14 to correct the skew. Subsequently, the sheet is bent between the stopper 28 and the nip between the first forward and reverse rotation roller 13 and the pressing roller 14, and this bent portion of the sheet that becomes the folded back portion enters the nip between the first forward and reverse rotation roller 13 and the first folding roller 12 to form the first folded portion.
The sheet that passes through the nip between the first forward and reverse rotation roller 13 and the first folding roller 12 is conveyed to the left side in
Numerous additional modifications and variations are possible in light of the above teachings. It is therefore to be understood that, within the scope of the above teachings, the present disclosure may be practiced otherwise than as specifically described herein. With some embodiments having thus been described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the scope of the present disclosure and appended claims, and all such modifications are intended to be included within the scope of the present disclosure and appended claims.
Each of the functions of the described embodiments may be implemented by one or more processing circuits or circuitry. Processing circuitry includes a programmed processor, as a processor includes circuitry. A processing circuit also includes devices such as an application specific integrated circuit (ASIC), digital signal processor (DSP), field programmable gate array (FPGA), and conventional circuit components arranged to perform the recited functions.
Number | Date | Country | Kind |
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2018-050397 | Mar 2018 | JP | national |
2019-010038 | Jan 2019 | JP | national |