This patent application is based on and claims priority pursuant to 35 U.S.C. § 119 to Japanese Patent Applications No. 2018-050378, filed on Mar. 19, 2018, and No. 2018-202474, filed on Oct. 29, 2018 in the Japanese Patent Office, the entire disclosure of each 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.
Techniques exist for a sheet processing apparatus that includes a pressing member rotatably supported and having a pressing portion to press a folded portion of a sheet in a predetermined range in a rotation direction, and a guide opposite the pressing member.
This specification describes an improved sheet processing apparatus that includes a rotatable pressing member, a guide, and a contact member. The rotatable pressing member includes a pressing portion that is disposed in a predetermined range in a rotation direction of the pressing member to press a folded portion of a sheet. The guide is disposed opposite the pressing member. The contact member contacts the guide and is rotatably disposed at at least one end of the pressing member in an axial direction of the pressing member.
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 codes are allocated to elements (members or components) 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 functions of the foregoing machines. 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.
In an image forming apparatus main body 400, feeding cassettes to store sheets serving as recording media are disposed below an image forming section. After a sheet stored in the feeding cassettes is fed by the feeding roller 414a or 414b, the sheet is conveyed upward along a predetermined conveyance path. Then the sheet reaches a registration roller pair 413.
The image forming section includes a photoconductor drum 401 as an image bearer, a charger 402, an exposure device 410, a developing device 404, a transfer device 405, and a cleaner 406.
The charger 402 uniformly charges a surface of the photoconductor drum 401. The exposure device 410 serving as a latent image forming device forms an electrostatic latent image on the photoconductor drum 401 based on image data read by a scanner 100. The developing device 404 adheres toner to the electrostatic latent image formed on the photoconductor drum 401 to form a visible image as a toner image. The transfer device 405 transfers the toner image from the photoconductor drum 401 onto the sheet. The cleaner 406 removes toner remaining on the photoconductor drum 401 after the transfer.
On the downstream side of the image forming section in the sheet conveyance direction, a fixing device 407 to fix the toner image on the sheet is disposed.
The exposure device 410 includes a laser unit 411 to emit a laser beam based on the image data under a control of a controller and a polygon mirror 412 to scan the laser beam from the laser unit 411 in a rotation axis direction of the photoconductor drum 401 which is called a main scanning direction.
An automatic document feeder (ADF) 500 is mounted on the scanner 100. The automatic document feeder (ADF) 500 includes a platen 501, a separation and feed roller 502, an original conveyor belt 503, and an original ejection tray 504.
When the automatic document feeder (ADF) 500 receives an instruction to start scanning originals placed on the platen 501, the separation and feed roller 502 feeds the originals one by one from the platen 501 to the original conveyor belt 503. The original conveyor belt 503 moves the originals onto a platen glass 309 on which each of the originals temporally stops.
Then, the scanner 100 reads the image data of the original temporarily stopped on the platen glass 309. Thereafter, the original conveyor belt 503 resumes conveyance of the original to eject the original onto the original ejection tray 504.
A more detailed description is now provided of an image reading operation and an image forming operation.
In addition to the platen glass 309, the scanner 100 includes a first carrier 303, a light source 301 and a mirror 302 provided on the first carrier 303, a second carrier 306, mirrors 304 and 305 provided on the second carrier 306, a lens 307, and a charge coupled device (CCD) 308. The light source 301 is lighted when the automatic document feeder (ADF) 500 conveys the original onto the platen glass 309 or when a user places an original on the platen glass 309 and directs the image forming apparatus to start copying via an operation panel. In the meantime, the first carrier 303 and the second carriers 306 move along a guide rail.
The light source 301 emits light to the original positioned on the platen glass 309. Reflected light from the original is guided to the CCD 308 via the mirror 302, the mirrors 304 and 305, and the lens 307. The CCD 308 receives the reflected light and reads the image data of the original. The image data is converted from analog to digital data by an analog-to-digital (A/D) converter. The digital data is sent from a data output unit to the controller in the image forming apparatus main body 400.
On the other hand, the image forming apparatus main body 400 starts to drive the photoconductor drum 401, and after a rotation speed of the photoconductor drum 401 reaches a predetermined speed, the charger 402 uniformly charges the surface of the photoconductor drum 401. The exposure device 410 forms the electrostatic latent image on the charged surface of the photoconductor drum 401 based on the image data read by the scanner 100.
Thereafter, the developing device 404 develops the electrostatic latent image on the surface of the photoconductor drum 401 into a toner image. In the meantime, the feeding roller 414a or 414b feeds the sheet stored in the feeding cassette, and the registration roller pair 413 temporarily stops the sheet.
The registration roller pair 413 feeds the sheet to a transfer portion opposed to the transfer device 405 when a leading edge of the toner image formed on the surface of the photoconductor drum 401 reaches the transfer portion. While the sheet passes through the transfer portion, a transfer electric field transfers the toner image formed on the surface of the photoconductor drum 401 onto the sheet.
The sheet on which the toner image is transferred is conveyed to the fixing device 407, subjected to a fixing process by the fixing device 407, and then discharged to the folding apparatus 1 at the subsequent stage. The cleaner 406 removes residual toner which is not transferred onto the sheet at the transfer portion and remains on the surface of the photoconductor drum 401.
The post-processing apparatus 2 includes an introduction path 201 to receive the sheet from the folding apparatus 1 and three paths diverging from the introduction path 201, that is, a first ejection path 202 to eject the sheet to an upper tray 205, a second ejection path 203 to eject the sheet to a shift tray 206, and a conveyance path 204 to convey the sheet to a sheet binding device 230. On the introduction path 201, a punching device 210 is disposed to puncture a punch hole in the sheet. The punching device 210 punctures the punch hole at a predetermined position in a folded sheet, a folded sheet bundle, and a single sheet that has been conveyed without being folded, which are ejected from the folding apparatus 1.
On the conveyance path 204, an overlay device 220 is disposed. The overlay device 220 includes three conveyance paths 220a, 220b, and 220c. Sorting the sheets to each conveyance path and temporarily waiting on each conveyance path allows up to three sheets to be overlaid and conveyed.
The sheet binding device 230 includes a processing tray 233, a jogger fence 234 to align a plurality of sheets (that is a sheet bundle) in the processing tray 233, a stapler unit 231 to perform binding processing on the sheet bundle in the processing tray 233, and a conveyance belt 232 to convey the sheet bundle subjected to binding processing toward the shift tray 206.
When the predetermined number of sheets which are folded or not folded is conveyed to the processing tray 233, the jogger fence 234 performs the alignment processing on the sheet bundle in the processing tray 233. Then, after the stapler unit 231 performs the binding processing on the sheet bundle in the processing tray 233, the conveyance belt 232 conveys the bound sheet bundle, and the bound sheet bundle is ejected to the shift tray 206.
As illustrated in
The folding processing conveyance path W2 includes an overlay section A to overlap a plurality of sheets, a folding section B to fold one sheet or sheets overlaid in the overlay section A, and an additional folding section C in which the folded sheet is additionally folded.
The overlay section A includes a pair of registration rollers 15, a first conveyance roller pair 117a including a first pressing roller 17a in a folding mechanism 17 described later and a first folding roller 17b, and a conveyance roller pair 12 to convey the sheet toward the pair of registration rollers 15. The overlay section A also includes a switchback conveyance path W3 that branches from the folding processing conveyance path W2 between the conveyance roller pair 12 and the pair of registration rollers 15 and conveys the sheet conveyed in a reverse direction (conveyed in the opposite direction to the predetermined direction) by the pair of registration rollers 15, and a switchback conveying roller pair 13 disposed in the switchback conveyance path W3. The overlay section A also includes a second bifurcating claw 14 disposed at a fork between the switchback conveyance path W3 and the folding processing conveyance path W2 from the conveyance roller pair 12 to the pair of registration rollers 15 to guide the sheet conveyed in the reverse direction (conveyed in the opposite direction to the predetermined direction) toward the switchback conveyance path W3.
The folding section B is disposed downstream of the overlapping section A. The folding section B includes the pair of registration rollers 15, the folding mechanism 17, and a second conveyance roller pair 18. The folding mechanism 17 includes the first folding roller 17b, the first pressing roller 17a which contacts the first folding roller 17b to switch back the sheet, a second folding roller 17c which contacts the first folding roller 17b to form a first folding nip B1, and a second pressing roller 17d which contacts the second folding roller 17c to form a second folding nip B2. The driving force is transmitted to one of the plurality of rollers included in the folding mechanism 17, and the other rollers are driven to rotate.
A third bifurcating claw 16 is disposed downstream of the pair of registration rollers 15 to guide the sheet to the nip between the first folding roller 17b and the first pressing roller 17a or the first folding nip B1.
On the downstream side of the folding section B, the additional folding section C is disposed. The additional folding section C includes an additional folding roller 20. The additional folding roller 20 has a pressing convex portion, and the pressing convex portion presses the folded portion of the sheet, and the folded portion of the sheet is additionally folded.
The controller 40 to control the folding apparatus 1 includes a Central Processing Unit (CPU) 41, a Read Only Memory (ROM) 42, a Random Access Memory (RAM) 43, a sensor controller 44 to control various sensors such as a paper detection sensor disposed in the folding apparatus 1, a first motor controller 45 to control a plurality of conveyance motors which convey the sheet in the folding apparatus 1, a second motor controller 46 to control the additional folding motor 49 drives the additional folding roller 20, and a communication interface 48.
These components are mutually electrically coupled via a bus line 47 such as an address bus or a data bus. The communication interface 48 communicates with the image forming apparatus 3 and the post-processing apparatus 2 in
As illustrated in
Next, the pair of registration rollers 15 and the first conveyance roller pair 117a serving as a first conveyance member including the first pressing roller 17a and the first folding roller 17b conveys the first sheet P1 in a predetermined direction which is called a regular direction. Next, when the trailing edge of the first sheet P1 passes through the fork between the folding processing conveyance path W2 and the switchback conveyance path W3, the conveyance of the first sheet P1 is stopped. Next, the second bifurcating claw 14 pivots in the clockwise direction in
In this way, by conveying the preceding sheet P1 to the switchback conveyance path W3 and withdrawing the preceding sheet P1 from the folding processing conveyance path W2, the preceding sheet P1 does not obstruct the conveyance of a succeeding second sheet P2, thereby enabling smooth conveyances of the second sheet P2.
Next, a leading edge of the second sheet P2 contacts the pair of registration rollers 15. As illustrated in
When the number of overlaid sheets reaches the number set by the user, the folding section B starts the folding processing. On the other hand, when the number of overlaid sheets does not reach a number set by the user, the overlaid sheets are conveyed in the reverse direction when the trailing edge of the overlaid sheets has passed through the second bifurcating claw 14 and evacuates to the switchback conveyance path W3. The sheets P are overlaid by repeating the above operation according to the number of sheets to be overlaid.
In the present embodiment, as described above, the skew of the second sheet P2 is corrected without stopping the rotation of the conveyance roller pair 12, and the pair of registration rollers 15 starts to rotate when the bending amount of the second sheet P2 reaches the predetermined amount. Therefore, it is possible to overlay the preceding first sheet and the following second sheet without reducing the productivity.
While the number of the overlaid sheets does not reach the number set by the user, an overlay process without the skew correction by the pair of registration rollers 15 may be performed, and, when the number of the overlaid sheets reaches the number set by the user, the overlay process with the skew correction by the pair of registration rollers 15 may be performed. In the overlay process with the skew correction, the switchback conveying roller pair 13 strikes the leading edge of the preceding sheet P1 or a preceding sheet bundle against the pair of registration rollers 15 to correct the skew and puts the sheet P1 or the preceding sheet bundle on standby, and, after the conveyance roller pair 12 strikes the leading edge of the second sheet P2 against the pair of registration rollers 15 to correct the skew, the pair of registration rollers 15 conveys the overlaid sheets. On the other hand, in the overlay process without the skew correction, the leading edge of the preceding sheet P1 or the sheet bundle is placed in the switchback conveyance path W3 and put on standby. Then, the switchback conveying roller pair 13 starts to convey the preceding sheet P1 or the preceding sheet bundle so that the preceding sheet P1 or the preceding sheet bundle placed on the switchback conveyance path W3 reaches the pair of registration rollers 15 when the following sheet P2 reaches the pair of registration rollers 15, and the sheets are overlaid. The pair of registration rollers 15 conveys the overlaid sheets.
The leading edge of the sheet bundle Pt conveyed by the pair of registration rollers 15 after the overlay process enters the first conveyance roller pair 117a including the first folding roller 17b and the first pressing roller 17a. Next, when the sheet bundle Pt is conveyed by a predetermined conveyance amount Δ1, a drive motor to drive the folding mechanism 17 reversely rotates. A travel distance at this time is appropriately determined depending on the length of the sheet bundle Pt in the sheet conveyance direction and the content of the folding processing, such as the manner of folding.
Reverse rotation of the drive motor to drive the folding mechanism 17 conveys the sheet bundle Pt sandwiched by the first conveyance roller pair 117a in the reverse direction, that is, the opposite direction to the predetermined direction. This forms a bend in the sheet bundle portion between the pair of registration rollers 15 and the first conveyance roller pair 117a as illustrated in
The first folded portion in the sheet bundle Pt enters the nip between the second conveyance roller pair 18, and when the sheet bundle Pt is conveyed by the predetermined conveyance amount Δ2, the second conveyance roller pair 18 reversely rotates and conveys the sheet bundle Pt sandwiched by the second conveyance roller pair 18 in the reverse direction that is the opposite direction to the predetermined direction. The conveyance amount Δ2 is appropriately determined depending on the length of the sheet bundle Pt in the sheet conveyance direction and a content of the folding processing such as folding manner.
The conveyance of the sheet bundle Pt sandwiched by the second conveyance roller pair 18 in the reverse direction forms a bend in the sheet bundle between the first folding roller pair 117b and the second conveyance roller pair 18. As illustrated in
As illustrated in
In the above description, the sheet bundle Pt after the overlay process is folded. The folding processing operation to fold one sheet is the same. In the above description, Z folding-processing is described. The same operation as the Z-folding processing in which the conveyance amount Δ1 and the conveyance amount Δ2 are appropriately changed enables to carry out the inner three-fold and the outer three-fold. In double folding processing, the third bifurcating claw 16 pivots in the clockwise direction in
The additional folding roller 20 includes a convex shaped pressing portion 20b disposed on a circumferential surface of a pressing roller portion 20a with a certain angle difference from a rotation shaft 20c of the additional folding roller 20. The pressing portion 20b has a V shape symmetrical about the center in the main scanning direction of the additional folding roller 20. This configuration of the additional folding roller 20 according to the present embodiment causes the pressing portion 20b to contact the folded portion of the sheet in two places at the same time. The pressing portion 20b is disposed in an area not more than half of the circumferential surface of the pressing roller portion 20a in the rotation direction.
In the above-described configuration of the pressing portion 20b, when the additional folding roller 20 is driven to rotate, the pressing portion 20b of the additional folding roller 20 continuously presses the folded portion of the sheet P from the center of the sheet to the both ends of the sheet in the main scanning direction. This avoids the dispersion of the pressing force over the entire area of the folded portion in the main scanning direction in additional folding processing, and the pressing portion 20b can intensively apply the pressing force over the entire folded portion of the sheet. Therefore, even when the load applied to the additional folding roller is small, the pressing portion 20b can apply a desired pressing force to the folded portion of the sheet, and the load on the additional folding roller 20 of the above-described pressing portion 20b in the additional folding processing can be set smaller than the load of the pressing portion pressing the entire area of the folded portion of the sheet in the main scanning direction.
The above described additional folding processing can continuously press the folded portion of the sheet in the main scanning direction in a shorter time than additional folding processing in which a pressing roller moves from one end to the other end on the sheet in the main scanning direction and continuously presses the folded portion of the sheet in the main scanning direction. Therefore, the above described additional folding processing can improve productivity and apply enough pressing force to the folded portion of the sheet.
As illustrated in
As illustrated in
Next, the second motor controller 46 controls the additional folding motor 49 to start rotary drive of the additional folding roller 20. As a result, the second folded portion O2 of the sheet P is continuously pressed in both directions from the center in the main scanning direction in such a manner that the second folded portion O2 is sandwiched between the pressing portion 20b of the additional folding roller 20 and the guide plate 51 to put a sharp crease at the second folded portion O2 as illustrated in
In this operation example, the additional folding roller 20 starts to rotate after the sheet stops. However, the additional folding roller 20 may start to rotate without waiting for the sheet to stop so that the pressing portion 20b of the additional folding roller 20 contacts the folded portion of the sheet when the sheet P stops. The above-described control of the rotation of the additional folding roller 20 shortens the additional folding processing time and improves productivity.
When the additional folding roller 20 is separated from the sheet P, the intermediate conveyance roller pair 19 again conveys the sheet P as illustrated in
As illustrated in
The additional folding section C includes a guide retracting member 55 as a moving member to move the guide plate 51 from a contact position in which the guide plate 51 contacts the pressing portion 20b of the additional folding roller 20 to a retracted position in which the guide plate 51 is away from the additional folding roller 20. The guide plate 51 is rotatably attached to the guide retracting member 55 via a single component which is a sheet metal member to fix the spring 52 applying the pressing force to the guide plate 51. A support shaft 55a rotatably supports the downstream end portion, which is the left end portion in
A lock 61 is attached to the guide retracting member 55 so as to be rotatable by a predetermined angle. The lock 61 locks the guide retracting member 55 to position the guide plate 51 at the contact position. In addition, a lever 63 which rotates together with the lock 61 by the predetermined angle is attached coaxially with the lock 61. The lock 61 has a hook 61b. As illustrated in
When a user removes the jammed sheet, the user rotates the lever 63 by a predetermined angle in a direction of the arrow R in
After the user removes the jammed sheet, the user rotates the guide retracting member 55 clockwise around the support shaft 55a as a fulcrum to move the guide plate 51 from the retracted position to the contact position, hook the hook 61b of the lock 61 on the caulking pin 62, and lock the guide plate 51 at the contact position.
An impact sound sometimes occurs during the additional folding operation.
As illustrated in
Additionally, a film 56 is disposed between the additional folding roller 20 and the guide plate 51. The film 56 is made of a member having a friction coefficient lower than that of the sheet. The end of the film 56 on a right side in
If there is no film 56, the pressing portion 20b of the rotating additional folding roller 20 is directly pressed against the folded portion of the stopped sheet. The pressing portion 20b slides on the sheet in the sheet conveyance direction and presses the folded portion of the sheet. In this case, a frictional force between the sheet and the additional folding roller 20 moves the sheet together with the additional folding roller 20 in the rotation direction of the additional folding roller 20, which shifts the folded portion of the sheet from the additional folding position. This may result in a failure of the additional folding processing.
On the other hand, disposing the film 56 between the additional folding roller 20 and the guide plate 51 causes the additional folding roller 20 to slide on the film 56. Since the film 56 is fixed, no force is applied to the sheet in the rotation direction of the additional folding roller 20. This can prevent the sheet from moving during the additional folding processing and satisfactorily perform the additional folding processing on the folded portion of the sheet.
As illustrated in
After the pressing portion 20b hits the guide plate 51, the pressing portion 20b presses the guide plate 51 across the folded portion of the sheet. The guide plate 51 rotates counterclockwise in
After the abutment 51b is away from the stopper 57, the pressing portion 20b continuously presses the folded portion of the sheet in the main scanning direction, as illustrated in
After the other end of the pressing portion 20b in the rotation direction, that is, both ends of the pressing portion 20b in the main scanning direction separate from the sheet immediately before completing the additional folding operation, nothing presses the guide plate 51. Therefore, the biasing force of the spring 52 rotates the guide plate 51 clockwise in
In order to reduce such impact sounds, in the present embodiment, there is a cam 71 serving as a contact member to press the guide plate 51 when the non-pressing portion 20e of the additional folding roller 20 is opposite the guide plate 51, and the cam 71 is provided at both ends of the additional folding roller 20.
As illustrated in
As illustrated in
An outer diameter M1 of the pressing portion 20b of the additional folding roller 20 is equal to an outer diameter C1 of the contact part 71a of the cam 71. This prevents the guide plate 51 from hitting the pressing portion 20b and the contact part 71a of the cam when the object to be contacted by the guide plate 51 is switched to either the cam 71 or the pressing portion 20b, which prevents the generation of the impact sound.
An outer diameter M2 of the pressing roller portion 20a of the additional folding roller 20 is also equal to an outer diameter C2 of the non-contact part 71b of the cam 71. The outer diameter C2 of the non-contact part 71b of the cam 71 may be smaller than the outer diameter M1 of the pressing portion 20b of the additional folding roller 20. Additionally, a shape of the connecting part 71c of the cam 71 is a tangent extending from the non-contact part 71b. A distance between the connecting part 71c and the rotation shaft 20c may be less than the outer diameter M1 of the pressing portion 20b. A shape of the connecting part 71c is not limited to a linear shape and may be a curved shape.
A range θ2 of the contact part 71a of the cam 71, which is a length of the contact part 71a in a circumferential direction of the contact part 71a, is the same as a range θ1 of the non-pressing portion 20e of the additional folding roller 20, which is a length of the non-pressing portion 20e in a circumferential direction of the non-pressing portion 20e.
If the range θ2 of the contact part 71a of the cam 71 is narrower than the range θ1 of the non-pressing portion 20e of the additional folding roller 20, the pressing portion 20b may hit the guide plate 51, or the abutment 51b of the guide plate 51 may hit the stopper 57, which may cause the impact sound.
On the other hand, if the range θ2 of the contact part 71a of the cam 71 is wider than the range θ1 of the non-pressing portion 20e of the additional folding roller 20, a following problem may occur. When the range θ2 of the contact part 71a of the cam 71 is wider than the range θ1 of the non-pressing portion 20e of the additional folding roller 20, a part of the contact part 71a of the cam 71 overlaps with the pressing portion 20b at the center in the main scanning direction and one end in the rotation direction of the additional folding roller 20 which is the right end portion of the pressing portion 20b in
When a part of the contact part 71a of the cam 71 overlaps with the pressing portion 20b at the center in the main scanning direction and one end in the rotation direction of the additional folding roller 20 which is the right end portion of the pressing portion 20b in
Therefore, it is preferable that the range θ2 of the contact part 71a of the cam 71 is equal to the range θ1 of the non-pressing portion 20e of the additional folding roller 20.
When the pressing roller portion 20a of the additional folding roller 20 is longer than the sheet conveyance span and both ends of the pressing portion 20b do not contact the folded portion of the sheet, as illustrated by +a in
As illustrated in
As illustrated in
A length of the film 56 in the main scanning direction that is the axial direction of the additional folding roller 20 is the same as the length of the additional folding roller 20, and the film 56 does not contact the cams 71 disposed at ends of the additional folding roller 20 because, if the film 56 contacts the cam 71, the cam 71 pushes the film 56 to the guide plate 51, and the sheet may not pass between the film 56 and the guide plate 51 even when the non-pressing portion 20e of the additional folding roller 20 is opposed to the guide plate 51 to pass the sheet. In the present embodiment, the length of the film 56 in the main scanning direction that is the axial direction is set to the same as the length of the additional folding roller 20 so that the film 56 does not contact the cam 71. Or, the film 56 may be longer than the additional folding roller 20 and have a hole opposite the cam 71 so that the cam 71 passes through the hole and does not contact the film 56.
As illustrated in
As illustrated in
However, in the above-described configuration, the pressing portion 20b or the contact part 71a of the cam 71 always presses the guide plate 51 at the contact position. Therefore, as illustrated in
Therefore, in the present embodiment, the cam 71 is configured to be rotatable with respect to the additional folding roller 20 so that the contact part 71a of the cam 71 can be retracted from the non-pressing portion 20e in the rotation direction.
As illustrated in
As illustrated in
As illustrated in
When a sheet jam occurs, the additional folding roller 20 rotates forward in the direction of an arrow F1 in
Next, with reference to
Since the user removes the jammed sheet under the state illustrated in
After the user removes the jammed sheet, the additional folding roller 20 rotates in reverse. An end face of the cutout portion 20f on the upstream side in the reverse rotation direction pushes the projection 71d of the cam 71, the cam 71 reversely rotates together with the additional folding roller 20, and the contact part 71a of the cam 71 contacts the guide plate 51. The attitude of the cam 71 returns to the state illustrated in
After the user removes the jammed sheet, the additional folding roller 20 may rotate forward and, together with the cam 71, rotate forward by substantially one turn so that the contact part 71a of the cam 71 contacts the guide plate 51.
In the present embodiment, the projection 71d of the cam 71 enters the cutout portion 20f disposed at the end of the additional folding roller 20, but the projection 71d may enter a groove extending in the rotation direction disposed at the end of the additional folding roller 20.
In the above-described configuration, since the cam 71 is merely rotatably supported by the rotation shaft 20c of the additional folding roller 20, the cam 71 may accidentally rotate relative to the additional folding roller 20. When the additional folding roller 20 rotates in reverse as illustrated in
Therefore, it is preferable that the cam 71 is pressed against the additional folding roller 20 so as not to accidentally rotate relative to the additional folding roller 20.
As illustrated in
As described above, pressing the cam 71 against the end face 20h of the pressing roller portion 20a generates a predetermined frictional force between the cam 71 and the end face 20h and prevents the accidental rotation of the cam 71 relative to the additional folding roller 20. This prevents the rotation of the cam 71 relative to the additional folding roller 20 caused by an impact or the like that occurs during jam processing to remove the jammed sheet and the movement of the cam 71 to the contact position at which the contact part 71a of the cam 71 contacts the guide plate 51. As a result, difficulty in locking the guide plate 51 after the jam processing at the contact position can be reduced.
The frictional force between the cam 71 and the end face 20h is set weaker than a force required to push up the guide plate 51 that is the biasing force of the spring 52 to press the guide plate 51 toward the additional folding roller 20. The frictional force between the cam 71 and the end face 20h can be controlled by an elastic force of the spring 81 or the surface roughness of the cam 71 and the end face 20h.
As illustrated in
The reverse rotation of the cam 71 with the additional folding roller 20 results in contact between the guide plate 51 and one end of the contact part 71a in the reverse rotation direction, as indicated by G in
As described above, the static frictional force between the cam 71 and the end face 20h is set weaker than the force required to push up the guide plate 51 that is the biasing force of the spring 52. Accordingly, when one end of the contact part 71a in the reverse rotation direction contacts the guide plate 51, the reaction force of the guide plate 51 exceeds the static frictional force between the cam 71 and the end face 20h and prevents the cam 71 from reversely rotating. As a result, the cam 71 relatively slides on the end face 20h, and only the additional folding roller 20 rotates in the reverse direction. As illustrated in
In this example, the contact part 71a of the cam 71 contacts the guide plate 51, but, since the contact part 71a pushes up the guide plate 51, the work of locking the guide plate 51 at the contact position after the above-described jam processing is not difficult.
In the above description, the coil spring 81 presses the cam 71 in the axial direction against the end face 20h opposite the cam 71 in the axial direction, but, for example, a radially opposed surface and the cam may be pushed against each other.
As illustrated in
With the above-described configuration as well, the frictional force between the outer circumferential surface of the tubular pressing member 85 and the inner circumferential surface of the support hole 71f prevents the cam 71 from accidentally rotating relative to the additional folding roller 20. This prevents the rotation of the cam 71 relative to the additional folding roller 20 caused by an impact or the like that occurs during the jam processing to remove the jammed sheet and the movement of the cam 71 to the contact position at which the contact part 71a of the cam 71 contacts the guide plate 51. As a result, the difficulty in locking the guide plate 51 after the jam processing at the contact position can be reduced.
The additional folding roller 20 in the first variation includes a plurality of pressers 20d disposed around the rotation shaft with a certain angular difference in the rotation direction of the rotation shaft 20c of the additional folding roller 20 and disposed with a certain interval in the main scanning direction.
Each presser 20d includes a fixing portion 123 to fix the presser on the rotation shaft 20c, a leaf spring 122, and a pressing roller 121 rotatably supported on a shaft parallel to the main scanning direction. The additional folding roller 20 of the first variation has two presser groups symmetrical about the center in the main scanning direction, each of which includes a plurality of pressers 20d disposed around the rotation shaft with a certain angular difference in the rotation direction of the rotation shaft 20c of the additional folding roller 20 and disposed with a certain interval in the main scanning direction. The first presser group includes from a first presser to an eighth presser in
In the first variation, since the pressing rollers 121 serving as the pressing members are disposed around the rotation shaft with the certain angular difference in the rotation direction and disposed with the certain interval in the main scanning direction, the pressing rollers 121 can continuously press the folded portion of the sheet P from the center of the sheet to the both ends of the sheet in the main scanning direction to put the sharp crease in the sheet P.
The folding apparatus of the second variation also includes the through conveyance path W1 to convey the sheet to the post-processing apparatus 2 at the subsequent stage without the additional folding processing. In addition, the folding apparatus of the second variation also includes the folding processing conveyance path W2 that branches from the through conveyance path W1, folds the sheet P, and conveys the sheet P to the post-processing apparatus 2 at the subsequent stage.
An entry roller pair 611 serving as a first conveyance member is disposed on an entrance side, which is the right side in
A second folding roller 615 is disposed in contact with the first forward and reverse rotation roller 613 on an exit side of the folding processing conveyance path W2. On the folding processing conveyance path W2, the second forward and reverse rotation roller pair 616 is disposed opposite the second folding roller 615 with respect to the nip between the first folding roller 612 and the first forward and reverse rotation roller 613 to which the sheet p enters from the through conveyance path W1. The second forward and reverse rotation roller pair 616 includes a pressing roller 616a that is a rotating member and a driving roller 616b that is an opposing member. A driving force of the forward and reverse rotation motor 616m that is a driving source drives and rotates the driving roller 616b.
A folding motor 613m that is the DC motor as a driving source can drive and rotate the first forward and reverse rotation roller 613 so that the first forward and reverse rotation roller 613 can rotate forward and reverse. All of the first folding roller 612, the pressing roller 614 and the second folding roller 615 which are disposed in contact with the first forward and reverse rotation roller 613 are driven rollers that are driven to rotate by the first forward and reverse rotation roller 613.
A forward and reverse rotation motor 616m that is the DC motor as a driving source can drive and rotate the driving roller 616b of the second forward and reverse rotation roller pair 616 so that the driving roller 616b can rotate forward and reverse. The pressing roller 616a of the second forward and reverse rotation roller pair 616 is a driven roller that is driven to rotate by the driving roller 616b.
The pressure springs 611s, 612s, 614s, 615s, and 616s serving as the pressure members press roller shafts of the driven rollers 611a, 612, 614, 615, 616a to form nips between the driven rollers 611a, 612, 614, 615, 616a and the respective opposing rollers.
On the upstream side of the entry roller pair 611 in the sheet conveyance direction, which is the entrance side of the through conveyance path W1, an entry sensor 617 as a sheet end detector to detect the end of the sheet P is disposed. The entry sensor 617 outputs to the controller 40 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 entry sensor 617. As the entry sensor 617, a known sensor can be used.
On the downstream side of a second sheet conveyance unit configured by the first forward and reverse rotation roller 613 and the pressing roller 614 in the sheet conveyance direction, which is the exit side of the through conveyance path W1, a sheet detection sensor 618 as a sheet leading edge detector to detect the leading edge of the sheet P is disposed. The sheet detection sensor 618 outputs to the controller 40 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 detection sensor 618. Similar to the above-described entry sensor 617, a known sensor can be used as the sheet detection sensor 618.
On the downstream side of the second forward and reverse rotation roller pair 616 in the sheet conveyance direction, which is opposite side of the exit side of the folding processing conveyance path W2, a sheet detection sensor 619 to detect the leading edge of the sheet P is disposed. The sheet detection sensor 619 outputs to the controller 40 a leading edge detection signal indicating that the leading edge of the sheet P conveyed from the through conveyance path W1 to the folding processing conveyance path W2 reaches the detection area of the sheet detection sensor 619. Similar to the above-described entry sensor 617 and the sheet detection sensor 618, as the sheet detection sensor 619, a known sensor can be used.
A second conveyance unit is configured by the first forward and reverse rotation roller 613 and the pressing roller 614, and a first folded portion forming unit 620a is configured by the first folding roller 612 and the first forward and reverse rotation roller 613. Additionally, in the present embodiment, a second folded portion forming unit 620b is configured by the first forward and reverse rotation roller 613 and the second folding roller 615.
As the second conveyance unit, an adhesion roller or an attraction belt may be adopted instead of the above-described roller pair. The second conveyance unit including the first forward and reverse rotation rollers 613 and the second folded portion forming unit 620b including the first forward and reverse rotation rollers 613 and the second folding roller 615 has the common roller. However, the second conveyance unit and the second folded portion forming unit 620b may be an independent structure configured by different rollers.
On the downstream side of the second folded portion forming unit 620b in the sheet conveyance direction, which is the exit side of the folding processing conveyance path W2, an additional folding unit 680 that presses the folded portion of the sheet to put the sharp crease is disposed. The additional folding unit 680 has the same configuration as the additional folding section C of the embodiment.
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 613 and the pressing roller 614. After the leading edge of the sheet P pass through the nip, the sheet detection sensor 618 detects the leading edge of the sheet P. The controller 40 receives the leading edge detection signal from the sheet detection sensor 618 which has detected the leading edge of the sheet P and performs the following control. That is, the controller 40 controls the folding motor 613m to stop the rotation of the first forward and reverse rotation roller 613 when the sheet P is conveyed by a predetermined conveyance amount Δ1 from the nip between the first forward and reverse rotation roller 613 and the pressing roller 614 as illustrated in
The conveyance amount Δ1 is appropriately determined depending on the length of the sheet P in the sheet conveyance direction and a content of the folding processing such as folding manner. The conveyance amount Δ1 of the sheet P can be obtained from, for example, a rotation amount of the pressing roller 614 from when the controller 40 receives the leading edge detection signal output from the sheet detection sensor 618.
After the sheet P is conveyed by a predetermined conveyance distance Δ1, the controller 40 controls the folding motor 613m to start a reverse rotation of the first forward and reverse rotation roller 613 which returns the sheet P to the entrance side of the through conveyance path W1 and the entry motor 611m to start the rotation of the entry roller pair 611. As illustrated in
The first folded portion of the sheet P enters the nip of the second forward and reverse rotation roller pair 616 and is detected by the sheet detection sensor 619 after the first folded portion passes through the nip. The controller 40 receives the leading edge detection signal from the sheet detection sensor 619 which has detected the leading edge of the sheet P and performs the following control. That is, the controller 40 controls the folding motor 613m to stop the rotation of the first forward and reverse rotation roller 613 when the sheet P is conveyed by a predetermined conveyance amount Δ2 from the nip between the second forward and reverse rotation roller pair 616 as illustrated in
After the sheet P is conveyed by a predetermined conveyance amount Δ2, the controller 40 controls the forward and reverse rotation motor 616m to start a reverse rotation of the second forward and reverse rotation roller pair 616 which conveys the sheet P to the exit side of the folding processing conveyance path W2, the folding motor 613m to start the reverse rotation of the first forward and reverse rotation roller 613 again, and the entry motor 611m to start the rotation of the entry roller pair 611 again. As illustrated in
As illustrated in
The embodiments described above are examples and provide advantages as below in a plurality of aspects 1 to 19.
First Aspect
The sheet processing apparatus according to a first aspect includes a pressing member such as the additional folding roller 20 rotatably supported. The pressing member includes a pressing portion such as the pressing portion 20b that is disposed in a predetermined range in a rotation direction of the pressing member to press the folded portion of the sheet. The sheet processing apparatus according to the first aspect also includes a guide such as the guide plate 51 opposite the pressing member and a contact member such as the cam 71 to contact the guide. The contact member such as the cam 71 is rotatably disposed at at least one end of the pressing member in an axial direction of the pressing member.
When the user removes the jammed sheet, the user releases the lock of the guide plate 51 that is generally locked and moves the guide plate 51 from the contact position at which the guide plate 51 contacts the pressing portion 20b or the contact part 71a to the retracted position to increase a space between the guide plate 51 and the pressing member and remove the jammed sheet. After the user removes the jammed sheet, the user returns the guide from the retracted position to the contact position and locks the guide so that the guide does not move to the retracted position.
When the user returns the guide plate 51 to the contact position after removing the jammed sheet, if the user returns the guide plate 51 to the contact position at which the contact part 71a or the pressing portion 20b contacts the guide plate 51, since the user pushes the guide plate 51 to the contact part 71a or the pressing portion 20b and locks the guide plate 51, locking the guide plate 51 is difficult, and a jam processing operation to remove the jammed sheet is not easy.
In contrast, according to the first aspect, since the contact member such as the cam 71 can rotate with respect to the pressing member such as the additional folding roller 20, a rotation of the contact member relative to the pressing member can form a region in which both the pressing portion 20b and the contact part 71a at which the contact member contacts the guide such as the guide plate 51 do not exist in the rotation direction. Positioning the above-described region in which both the pressing portion 20b and the contact part 71a do not exist opposite the guide allows locking the guide without pressing the guide, resulting in an easy jam processing operation.
In the present embodiment, as described above, when the user removes the jammed sheet, after the contact member is at a position at which the contact member does not contact the guide, the pressing member rotates relative to the contact member so that a non-pressing portion in which the pressing portion of the pressing member is not arranged is opposite the guide. This rotation forms a region in which both the contact part and the pressing portion do not exist in the rotation direction and positions the region opposite the guide. Or, for example, when the user removes the jammed sheet, the rotation of the pressing member may stop at a position at which the contact member contacts the guide, and, when the user locks the contact member, the user may rotate the contact member relative to the pressing member to form the region in which both the contact part and the pressing portion do not exist in the rotation direction and position the region opposite the guide.
After the guide is locked at the contact position, the contact member rotates relative to the pressing member to position the contact part of the contact member in the region in which both the contact part and the pressing portion do not exist in the rotation direction. After that, the contact member and the pressing member are engaged so that the contact member and the pressing member rotate together. Thus, in the additional folding processing, the contact member and the pressing member rotate together, and the pressing portion can press the folded portion of the sheet. In addition, when a portion opposite the guide is switched from the non-pressing portion to a pressing area which is a predetermined range where the pressing member is disposed, since the pressing portion of the pressing member does not hit the guide, the occurrence of impact sound can be avoided.
Second Aspect
In a second aspect, the contact member such as the cam 71 of the sheet processing apparatus according to the first aspect has a projection such as the projection 71d protruding in the axial direction, and the pressing member such as the additional folding roller 20 has a receiving portion such as the cutout portion 20f at at least one end of the pressing member in the axial direction to receive the projection such as the projection 71d. The receiving portion forms a space in which the projection such as the projection 71d moves in a predetermined range in the rotation direction.
In the second aspect, as described in the embodiment, contact between the projection such as the projection 71d and an end face of the receiving portion such as the cutout portion 20f on an upstream side in the rotation direction can rotate the contact member such as the cam 71 and the pressing member such as the additional folding roller 20 together. As a result, while the sheet processing apparatus processes the sheet, a non-pressing portion such as the non-pressing portion 20e is adjacent to a contact portion such as the contact part 71a of the contact member that contacts the guide, and the contact member such as the cam 71 and the pressing member can rotate together, which can prevent the occurrence of impact sound.
In addition, since the receiving portion forms the space in which the projection such as the projection 71d moves in the predetermined range in the rotation direction, the contact member can rotate relative to the pressing member in the predetermined range from when the projection contacts the end face of the receiving portion on the upstream side in the rotation direction to when the projection contacts an end face of the receiving portion on a downstream side in the rotation direction. Thus, it is possible to form the region in which both the contact portion and the pressing portion do not exist in the rotation direction.
Third Aspect
In a third aspect, the contact member of the sheet processing apparatus according to the second aspect has a contact portion such as the contact part 71a to contact the guide such as the guide plate 51, the pressing member has a non-pressing portion such as the non-pressing portion 20e in which the pressing portion of the pressing member is not disposed in the rotation direction, and, when the projection such as the projection 71d contacts one end face of the receiving portion such as the cutout portion 20f in the rotation direction, the contact portion such as the contact part 71a is adjacent to the non-pressing portion such as the non-pressing portion 20e.
In the third aspect, as described in the embodiment, a non-pressing portion such as the non-pressing portion 20e is adjacent to a contact portion such as the contact part 71a of the contact member that contacts the guide, and the contact member such as the cam 71 and the pressing member can rotate together, which can prevent the occurrence of impact sound.
Fourth Aspect
In a fourth aspect, the contact member such as the cam 71 of the sheet processing apparatus according to the second aspect has a contact portion such as the contact part 71a to contact the guide such as the guide plate 51, the pressing member such as the additional folding roller 20 has a non-pressing portion such as the non-pressing portion 20e in which the pressing portion of the pressing member is not disposed in the rotation direction, and, when the jammed sheet is removed, the contact portion takes a position in which the contact portion is not opposite the guide, the pressing member such as the additional folding roller 20 relatively rotates with respect to the contact member such as the cam 71 so that the non-pressing portion such as the non-pressing portion 20e is opposite the guide such as the guide plate 51.
In the fourth aspect, as described in the embodiment, when the jammed sheet is removed, since the pressing member such as the additional folding roller 20 does not press the guide such as the guide plate 51, the user can easily lock the guide plate 51 at the contact position, that is, the jam processing operation becomes easy.
Fifth Aspect
In a fifth aspect, the contact member such as the cam 71 of the sheet processing apparatus according to the second aspect has the contact portion such as the contact part 71a to contact the guide such as the guide plate 51, the pressing member such as the additional folding roller 20 has the non-pressing portion such as the non-pressing portion 20e in which the pressing portion of the pressing member is not disposed in the rotation direction, and, when the sheet is processed, the pressing member such as the additional folding roller 20 rotates with the contact member such as the cam 71 in which the contact portion such as the contact part 71a is adjacent to the non-pressing portion such as the non-pressing portion 20e.
In the fifth aspect, as described in the embodiment, the pressing portion 20b does not hit the guide such as the guide plate 51 immediately after the start of the additional folding processing, and the abutment 51b does not hit against the stopper 57 to stop a rotation of the guide immediately before the end of the additional folding processing. Therefore, the occurrence of impact sound during the additional folding operation can be reduced.
Sixth Aspect
In a sixth aspect, the sheet processing apparatus according to the first aspect includes a moving member such as the guide retracting member 55 to move the guide such as the guide plate 51 between a contact position at which the guide contacts the pressing portion such as the pressing portion 20b or the contact member such as the cam 71 and a separation position at which the guide separates from the pressing portion and the contact member and a lock such as the lock 61 to lock the moving member that positions the guide at the contact position. In the sixth aspect, when the user removes the jammed sheet, the user releases the lock such as the lock 61 and moves the moving member such as the guide retracting member 55 to move the guide such as the guide plate 51 from the contact position to the retracted position. This movement increases the space between the guide such as the guide plate 51 and the pressing member such as the additional folding roller 20. Therefore, the user can easily remove the jammed sheet.
In addition, since the guide is not pressed, the user can easily lock the moving member by the lock after the user removes the jammed sheet.
Seventh Aspect
In a seventh aspect, the contact member such as the cam 71 of the sheet processing apparatus according to the first aspect has a contact portion to contact the guide when the pressing portion such as the pressing portion 20b contacts the guide.
In the seventh aspect, as described in the embodiment, since the cam 71 or the pressing portion 20b certainly press the guide such as the guide plate 51 during the additional folding operation, the occurrence of the impact sound during the additional folding operation can be reliably avoided.
Eighth Aspect
In an eighth aspect, the contact member such as the cam 71 of the sheet processing apparatus according to the first aspect has a contact portion such as the contact part 71a to contact the guide such as the guide plate 51, and an outer diameter C1 of the contact portion such as the contact part 71a is the same as an outer diameter M1 of the pressing portion such as the pressing portion 20b.
In the eighth aspect, as described in the embodiment, when the contact of the guide such as the guide plate 51 is switched between the pressing portion and the contact portion of the contact member such as the cam, the above-described structure prevents the pressing portion or the contact portion from hitting the guide, which avoids the occurrence of the impact sound during the additional folding operation.
Ninth Aspect
In a ninth aspect, the contact member such as the cam 71 of the sheet processing apparatus according to the first aspect is disposed out of a sheet conveyance span.
In the ninth aspect, when the contact member such as the cam 71 contacts the guide such as the guide plate 51, the contact member does not interfere with sheet passing.
Tenth Aspect
In a tenth aspect, the contact member such as the cam 71 and the pressing member such as the additional folding roller 20 of the sheet processing apparatus according to the first aspect are separate members.
In the tenth aspect, the contact member such as the cam 71 can be configured to be rotatable with respect to the pressing member such as the additional folding roller 20.
Eleventh Aspect
In an eleventh aspect, the pressing portion such as the pressing portion 20b is arranged over a predetermined range in the axial direction, and a position of the pressing portion in the rotation direction is different according to a position in the axial direction.
In the eleventh aspect, as described in the embodiment, the pressing force by the pressing portion during the additional folding process is not distributed over the entire region in the axial direction but is concentrated on the entire folded portion of the sheet. Therefore, even when the load applied to the additional folding member such as the additional folding roller 20 is small, it is possible to apply a desired pressing force to the folded portion of the sheet, and as compared with the case of pressing the entire area in the axial direction during the additional folding processing, the load on the pressing member can be reduced.
Twelfth Aspect
In a twelfth aspect, the pressing portion such as the pressing portion 20b of the sheet processing apparatus according to the eleventh aspect is symmetrical about the center of the pressing member such as the additional folding roller 20 in the axial direction.
In the twelfth aspect, as described in the embodiment, the pressing portion 20b can continuously press the folded portion of the sheet P from the center in the axial direction to the both end portions. This can perform the additional folding processing more efficiently than the case in which the pressing portion continuously presses the folded portion of the sheet from one end to the other end in the axial direction.
Thirteenth Aspect
In a thirteenth aspect, the sheet processing apparatus according to the first aspect includes a film such as the film 56 disposed between the guide such as the guide plate 51 and the pressing member such as the additional folding roller 20.
In the thirteenth aspect, as described in the embodiment, a slide of the pressing portion of the pressing member on the film 56 prevents the folded portion of the sheet from being displaced from the additional folding position by the movement of the sheet.
Fourteenth Aspect
In a fourteenth aspect, the film such as the film 56 of the sheet processing apparatus according to the thirteenth aspect does not contact the contact member such as the cam 71.
In the fourteenth aspect, as described in the embodiment, when the contact member such as the cam 71 contacts the guide such as the guide plate 51, the sheet can pass through the gap between the film and the guide.
Fifteenth Aspect
In a fifteenth aspect, the contact member such as the cam 71 of the sheet processing apparatus according to the first aspect has a contact portion such as the contact part 71a to contact the guide such as the guide plate 51, a non-contact portion such as the non-contact part 71b which does not contact the guide, and a connecting part such as the connecting part 71c to connect the contact portion such as the contact part 71a and the non-contact portion such as the non-contact part 71b. The connecting part such as the connecting part 71c is formed by a tangent line of the non-contact portion.
In the fifteenth aspect, it is possible to prevent the connecting part 71c from contacting the guide such as the guide plate 51.
Sixteenth Aspect
In a sixteenth aspect, a portion connecting the connecting part such as the connecting part 71c and the contact portion such as the contact part 71a of the sheet processing apparatus according to the fifteenth aspect is curved.
In the sixteenth aspect, as described in the embodiment, for example, when the outer diameter of the contact part 71a of the cam 71 serving as the contact member becomes larger than the outer diameter of the pressing portion 20b due to a manufacturing tolerance, the above-described curve guides the guide plate 51 serving as the guide for the guide plate 51 to gradually approach and contact the pressing portion 20b so that the impact sound can be reduced.
Seventeenth Aspect
In a seventeenth aspect, the sheet processing apparatus according to the first aspect further includes at least one of a member to press the contact member such as the cam 71 against a face on which the pressing member is opposite the contact member in at least one of a radial direction of the pressing member and the direction of the rotation axis (end face 20h of the additional folding roller in
In the seventeenth aspect, as described in the embodiment, when the jammed sheet is removed, a predetermined frictional force generated between the face and the contact member prevents the contact member such as the cam 71 from rotating relative to the pressing member such as the additional folding roller 20 and the contact portion of the contact member from moving to a position opposite the guide such as the guide plate 51. This reliably avoids difficulty in locking the guide.
Eighteenth Aspect
In an eighteenth aspect, the static frictional force between the face and the contact member such as the cam 71 in the sheet processing apparatus according to the seventeenth aspect is weaker than a force required for the contact member such as the cam 71 to push up the guide such as the guide plate 51.
In the eighteenth aspect, as described in the embodiment, one end face of the contact portion of the contact member in the rotation direction contacts the guide to rotate the pressing member relative to the contact member. This leads the guide to the non-pressing portion in which the pressing portion of the pressing member is not disposed and the contact member to a position in which the contact member does not push the guide upward.
Nineteenth Aspect
In a nineteenth aspect, the image forming system includes an image forming apparatus to form an image on a sheet and the sheet processing apparatus according to the first aspect to perform processing on the sheet.
In the nineteenth aspect, noise during the sheet processing can be reduced, and the user can easily remove the jammed sheet.
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.
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