The present application claims priority to and incorporates by reference the entire contents of Japanese Patent Application No. 2008-317313 filed in Japan on Dec. 12, 2008.
1. Field of the Invention
The present invention relates to a sheet aligning apparatus that aligns sheet-like recording media (hereinafter, “sheets”) carried thereto such as recording paper and overhead projector (OHP) sheets; a sheet processing apparatus that includes the sheet aligning apparatus and performs predetermined processing such as sorting, stacking, binding, folding, and punching to the sheets; and an image forming apparatus that integrally or separately includes the sheet processing apparatus.
2. Description of the Related Art
A sheet post-processing apparatus performs post-processing in, for example, the following steps. That is, sequentially receiving sheets from an image forming apparatus; aligning the sheets into a sheet bundle composed of a plurality of sheets; and automatically binding, or aligning punched sheets as the sheet bundle and sorting the bundle per unit. The post-processing apparatus is a so-called finisher. Although such a sheet post-processing apparatus can handle various types of sheets, if the sheets are soft sheets (paper) or curled sheets, the sheets cannot be surely moved by pressing of a wall surface of an aligning unit.
The edge surface refers to a cut surface sheet bundle that is formed when a large size sheet bundle is cut to create a small size sheet bundle. The edge surface a corresponds to an end in the longitudinal direction of the sheet and a side in the lateral direction. In this specification, the edge surface is referred to as an end or a side.
A sheet processing apparatus for processing sheets of curled paper and soft paper is disclosed in, for example, Japanese Patent Application Laid-open No. 6-016318 or Japanese Patent No. 3648073.
Japanese Patent Application Laid-open No. 6-016318 discloses a sheet processing apparatus that includes a sheet mounting unit and a pair of sheet side regulation side plates provided on both sides of the sheet on the sheet mounting unit. The sheet mounting unit stores therein or discharges and stacks thereon the sheets. At least one of the sheet side regulation side plates is movable in directions of narrowing and widening the distance to another plate. With the movement, the sheet on the sheet mounting unit is moved to be positioned between the plates, whereby the sheet is aligned. At a contact surface of the sheet side regulation side plate contacting a side end of the sheet in the post-processing apparatus, the friction to the sheet is made to be small in a direction from up to down and to be large in a direction from down to up. As a result, the curled sheet can be appropriately aligned. To provide the large friction, hair implantation sloping downward or saw-toothed concavity and convexity forming are performed.
Japanese Patent No. 3648073 discloses a sheet processing apparatus that teaches processing a holding surface of a pusher mechanism holding the lower end of the sheet so that the lower end of the sheet easily moves in the sheet pressed direction but does not easily return in the opposite direction, thereby preventing the pressed and aligned sheet from moving on the holding surface of the pusher mechanism.
The conventional techniques prevent the edge surface of the sheet from sliding to align the sheet by forming concavity and convexity on the wall surface of the jogger or adjusting a hair implant direction. However, the alignment accuracy of the jogger is affected by the concavity and convexity as a shape of the wall surface or due to hair implantation, and concavity and convexity along the concavity and the convexity are generated on the side surface of the aligned sheet bundle. As a result, the sheet cannot be accurately aligned unlike counterparts aligned by a planer wall surface.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an aspect of the present invention, there is provided a sheet aligning apparatus including an alignment surface formed in a planar shape and that presses an end of a sheet to move and align the sheet; and a holding unit that holds the end of the sheet at a position contacting the alignment surface in a state that a curled end of the sheet contacts the alignment surface and the sheet is thus pressed.
According to another aspect of the present invention, there is provided a sheet processing apparatus including an alignment tray for staking sheets thereon received from a carrying direction; a first aligning device that includes a first lateral direction aligning unit that aligns sheets stacked on the alignment tray in a width direction orthogonal to a carrying direction and a first longitudinal direction aligning unit that aligns the sheets in the carrying direction thereby obtained a first-aligned sheet bundle; a first processing device that performs predetermined processing to the first-aligned sheet bundle stacked on the alignment tray thereby obtaining a first-processed sheet bundle; and a first bundle transporting unit that transports the first-processed sheet bundle on the alignment tray downstream. The first lateral direction aligning unit, the first longitudinal direction aligning unit, and the first bundle transporting unit have respective planer contact surfaces to which a curled end of a sheet contacts, and at least one contact surface of the first lateral direction aligning unit, the first longitudinal direction aligning unit, and the first bundle transporting unit comprises a holding unit that holds the curled end at a position contacting the end of the sheet.
According to still another aspect of the present invention, there is provided an image forming apparatus comprising an image forming unit and a sheet processing apparatus that processes printed sheets received from the image forming unit. The sheet processing apparatus including an alignment tray for staking sheets thereon received from a carrying direction from the image forming unit; a first aligning device that includes a first lateral direction aligning unit that aligns sheets stacked on the alignment tray in a width direction orthogonal to a carrying direction and a first longitudinal direction aligning unit that aligns the sheets in the carrying direction thereby obtained a first-aligned sheet bundle; a first processing device that performs predetermined processing to the first-aligned sheet bundle stacked on the alignment tray thereby obtaining a first-processed sheet bundle; and a first bundle transporting unit that transports the first-processed sheet bundle on the alignment tray downstream. The first lateral direction aligning unit, the first longitudinal direction aligning unit, and the first bundle transporting unit have respective planer contact surfaces to which a curled end of a sheet contacts, and at least one contact surface of the first lateral direction aligning unit, the first longitudinal direction aligning unit, and the first bundle transporting unit comprises a holding unit that holds the curled end at a position contacting the end of the sheet.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
Exemplary embodiments of the present invention will be described below with reference to the accompanying drawings.
As shown in
Although not shown specifically in the diagram, the image forming apparatus PR includes an image processing circuit that converts input image data into printable image data, an optical writing device that performs optical writing to a photoreceptor based on an image signal output from the image processing circuit, a developing device that performs toner developing on a latent image formed by the optical writing on the photoreceptor, a transcription device that transcribes a toner image developed by the developing apparatus to a sheet, and a fixing apparatus that fixes the toner image transcribed on a sheet. The image forming apparatus PR feeds out the sheet on which a toner image is fixed to the sheet post-processing apparatus PD. The sheet post-processing apparatus PD performs certain post-processing on the sheet. As is apparent from the above description, the image forming apparatus PR herein is an electrophotographic system. Instead, all known image forming apparatuses such as an inkjet system and a thermal transfer system can be used. In this embodiment, an image forming unit includes the image processing circuit, the optical writing device, the developing device, the transcription device, and the fixing device.
The sheet is guided to the edge surface stitching tray F through the carrying passages A and D to be, for example, aligned and stapled. After that, a branching guide plate 54 and a movable guide 55 as deviating units distribute the sheet to: the carrying passage C that guides the sheet to the shift tray 202; or to a processing tray G (also referred to as a saddle stitching and saddle folding tray) that performs folding, for example. The sheet folded, for example, in the saddle stitching and saddle folding tray G is guided to a lower tray 203 through a carrying passage H. A branching claw 17 is arranged in the carrying passage D and held in a state of
In the carrying passage A in the upstream of the carrying passages B, C, and D and commonly connected thereto, an entrance sensor 301 that detects a sheet carried from the image forming apparatus PR, an entrance roller 1, a punching unit 100, a punching dust hopper 101, a carrying roller 2, the branching claws 15 and 16 are arranged in this order. The branching claws 15 and 16 are held in a state of
To guide the sheet to the carrying passage B, the solenoids of both claws are turned off to keep the branching claws in the state of
For example, the sheet post-processing apparatus can perform the following processing on a sheet: punching (by the punching unit 100); sheet alignment and end stitching (by jogger fences 53 and an edge surface stitching stapler S1); sheet alignment and saddle stitching (by the saddle stitching upper jogger fence 250a, the saddle stitching lower jogger fence 250b, and a saddle stitching stapler S2); sheet sorting (by the shift tray 202); and saddle folding (by a folding plate 74 and a folding roller 81).
A shift tray paper discharging unit I positioned at the most downstream in the direction of conveyance of a sheet in the sheet post-processing apparatus PD includes the shift paper discharging rollers 6 (6a and 6b), a returning roller 13, a paper surface detecting sensor 330, the shift tray 202, a shifting mechanism J illustrated in
Referring to
Although the detail is not shown in
In this embodiment, the paper surface detecting sensor 330a (for a stapled sheet) and the paper surface detecting sensor 330b (for a non-stapled sheet) are turned on when being shielded by the fan-shaped shield 30b. Accordingly, when the shift tray 202 rises and the contacting unit 30a of the paper surface detecting lever 30 rotates upward, the paper surface detecting sensor 330a (for a stapled sheet) is turned off, and if the contacting unit 30a further rotates, the paper surface detecting sensor 330b (for a non-stapled sheet) is turned on. When the paper surface detecting sensor 330a (for a stapled sheet) and the paper surface detecting sensor 330b (for a non-stapled sheet) detect that the amount of the stacked sheets has reached a predetermined height, the tray elevating motor 168 drives the shift tray 202 to fall by a predetermined amount. Consequently, the paper surface position of the shift tray 202 is kept approximately constant.
The elevating mechanism of the shift tray 202 will be described in detail.
As illustrated in
The driving unit L includes the tray elevating motor 168 and a worm gear 25. The power generated by the reversible tray elevating motor 168 as a drive source is transmitted to the final gear in a gear train fixed on the drive shaft 21 through the worm gear 25 to move the shift tray 202 in the vertical direction. The shift tray 202 can be held at a certain position because the power is transmitted through the worm gear 25. Thus, the shift tray 202 can be prevented from an unexpected falling accident, for example.
A shield plate 24a is integrally formed on the side plate 24 of the shift tray 202, and a full detecting sensor 334 that detects fill of the stacked sheets and a lower limit sensor 335 that detects a lower limit position are provided at the lower position of the shift tray 202. The full detecting sensor 334 and the lower limit sensor 335 are turned on/off by the shield plate 24a. The full detecting sensor 334 and the lower limit sensor 335 are photosensors that are turned on when shielded by the shield plate 24a. The shift paper discharging roller 6 is omitted in
The swing (shift) mechanism of the shift tray 202 includes a shift motor 169 and a shift cam 31 as illustrated in
The shift paper discharging roller 6 has a drive roller 6a and a driven roller 6b. As illustrated in
A projection 32c for guiding the shift tray 202 is provided on the front surface side of the end fence 32. The rear end of the shift tray 202 freely fits the projection 32c so as to be movable in the vertical direction. Accordingly, the shift tray 202 is supported by the end fence 32 so as to be movable in the vertical direction and be reciprocatable in the direction orthogonal to the sheet carrying direction. The end fence 32 guides the rear end of the stacked paper on the shift tray 202 to align the rear end of the paper.
Referring to
The structure of the edge surface stitching tray F that performs staple processing will be described in detail.
As illustrated in
A home position of the release claw 52a is detected by a release belt home-position sensor 311 as illustrated in
As illustrated in
Referring to
Referring to
Components of the edge surface stitching tray F are provided between the side plates 64a and 64b in
Referring to
In this embodiment, the rear end pressing lever 400 at the center has a double structure, and a pressing surface of the rear end pressing lever is biforked. In other words, the rear end pressing lever at the center includes the rear end pressing lever 400 and an auxiliary rear end pressing lever 401. Biforked pressing surfaces 400a, 400b, of the rear end pressing lever 400, and biforked pressing surfaces 401a, and 401b of the rear end pressing lever 401 can press wide range of area around the center of the sheet. In addition, the rear end pressing lever 400 and the auxiliary rear end pressing lever 401 are arranged so that both levers can press the sheet surface at positions symmetrical to the sheet center. Accordingly, the levers can press the rear-end bulk of the sheet in a balanced manner.
As described above, the release claw 52a discharges a sheet bundle in the releasing direction by lifting the center of the sheet bundle. Upon lifting, the release claw 52a passes between the biforked pressing surfaces 400a, 400b, of the rear end pressing lever 400, and the biforked pressing surfaces 401a, and 401b of the auxiliary rear end pressing lever 401. Therefore, a size a between the biforked pressing surfaces 400a and 400b, a size b between the biforked pressing surfaces 401a and 401b, and a depth of the biforked pressing surfaces are so determined that the release claw 52a can pass therebetween without contacting the surfaces. As a result, even when the release claw 52a becomes out of control and moves in the releasing direction while the rear end pressing lever 400 and the auxiliary rear end pressing lever 401 are pressing the rear end of the sheet bundle, the rear end pressing lever 400 and the auxiliary rear end pressing lever 401 do not interfere with the release claw 52a.
Referring to
When operating in the rear end pressing direction, the auxiliary rear end pressing lever 401 contacts and pushes the rear end pressing lever 400. Therefore, the sheet rear end pressing lever 400 is also operated by the auxiliary rear end pressing lever 401 so that the rear end of the sheet is pressed by the two pressing levers 400 and 401. The rear end pressing lever 400 is coupled to the auxiliary rear end pressing lever 401 by a pulling spring 408. If the auxiliary rear end pressing lever 401 returns to the home position (moves in the direction opposite to the rear end pressing direction), the rear end pressing lever 400 is pulled by the pulling spring 408, and therefore, both levers return to a standby position.
The biforked pressing surfaces 400a and 400b of the rear end pressing lever 400 and the biforked pressing surfaces 401a and 401b of the auxiliary rear end pressing lever 401 are approximately parallel to the stacked sheet surface, i.e., parallel to the sheet stacked surface of the edge surface stitching tray F, thereby preventing force in a direction of pushing up the sheet to be applied upon pressing.
The sheet bundle saddle stitched in the edge surface stitching tray F is saddle folded. The saddle folding is performed in a saddle stitching and saddle folding tray G. To this end, the aligned sheet bundle needs to be carried to the saddle stitching and saddle folding tray G. In this embodiment, a sheet bundle deviating unit that carries the sheet bundle to the saddle stitching and saddle folding tray G side is provided on the most downstream side in the carrying direction of the edge surface stitching tray F.
The sheet bundle deviation mechanism includes the branching guide plate 54 and the movable guide 55 as illustrated in
The movable guide 55 is swingably supported with a rotation shaft of the release roller 56. A link arm 60 is rotatably coupled to one end (the end opposite to the branching guide plate 54) of the movable guide 55 via a coupling unit 60a. A shaft of the link arm 60 fixed to the front-side plate 64a illustrated in
A bundle branching guide home-position sensor 315 detects a shield 61c of the cam 61 to detect the home position of the cam 61. Accordingly, the cam 61 counts a drive pulse of the bundle branching drive motor 161 based on the home position to control the stop position.
In this embodiment, the branching guide plate 54 and the movable guide 55 are operated by a single drive motor. Instead, the branching guide plate 54 and the movable guide 55 may be operated by different drive motors, and therefore, the moving timing and the stop position may be controlled according to the sheet size and the number of binding sheet.
The saddle stitching and saddle folding tray G is provided on the downstream side of the sheet bundle deviation mechanism including the movable guide 55 and the release roller 56 as illustrated in
Each of the bundle carrying upper roller 71 and the bundle carrying lower roller 72 is formed of a pair of a drive roller and a driven roller, and a measuring sensor for measuring the distance between the nips of the roller pair is provided on the bundle carrying upper roller 71. The measuring sensor detects the distance between the nips when the rollers pinch the sheet bundle and sends the distance to a CPU 360 described later. Thus, a controller 350 can obtain the thickness information of the sheet bundle. The CPU 360 can perform mode setting described later based on the obtained thickness information.
The movable rear end fence 73 is provided so as to be arranged across the bundle carrying guide lower plate 91, and can be moved in the sheet carrying direction (vertical direction in
The saddle folding mechanism is provided approximately at the center of the saddle stitching and saddle folding tray G and includes the folding plate 74, the folding roller 81, and a carrying passage H for carrying the folded sheet bundle.
The folding plate 74 is supported by freely fitting two shafts 64c provided to stand from the front-side plate 64a and the rear-side plate 64b, respectively, into slots 74a. In addition, a shaft 74b provided to stand from the folding plate 74 is freely fit in a slot 76b of a link arm 76, and the folding plate 74 reciprocates in the horizontal direction in
In other words, a shaft 75b of a folding plate drive cam 75 is freely fit in a slot 76c of the link arm 76, and the link arm 76 is swung by the rotation of the folding plate drive cam 75. Accordingly, in
The folding plate drive cam 75 rotates in the direction of an arrow in
In this embodiment, the saddle folding is performed on the sheet bundle. Instead, the saddle folding may be performed on a single sheet. In this case, the saddle stitching is not required because the sheet is only one. A single discharged sheet is carried to the saddle stitching and saddle folding tray G side to be folded by the folding plate 74 and the folding roller and then discharged to the lower tray 203. The reference numeral 323 indicates a folding unit passing sensor that detects a folded sheet, the reference numeral 321 indicates a bundle detection sensor that detects that the sheet bundle have reached the saddle folding position, and the reference numeral 322 indicates a movable rear end fence home-position sensor that detects the home position of the movable rear end fence 73. Moreover, in this embodiment, a detection lever 501 that detects a stacking height of the saddle folded sheet bundle on the lower tray 203 is swingably provided by a fulcrum 501a. A paper surface sensor 505 detects the angle of the detection lever 501 to elevate the lower tray 203 and to detect an overflow of the lower tray 203.
The controller 350 includes a microcomputer having the CPU 360, an input/output (I/O) interface 370, and the like as illustrated in
Based on the input signal, the CPU 360 controls the drive of: the tray elevating motor 168 for the shift tray 202; the paper discharging guide plate open/close motor 167 that opens or closes the open/close guide plate; the shift motor 169 that moves the shift tray 202; a tapping roller motor (not shown) that drives the tapping roller 12; the solenoids of the tapping SOL 170 and the like; the carrying motor that drives the carrying rollers; the paper discharging motor that drives the paper discharging rollers; the release motor 157 that drives the release belt 52; the stapler moving motor 159 that moves the edge surface stitching stapler S1; the obliquely drive motor 160 that obliquely rotates the edge surface stitching stapler S1; the jogger motor 158 that moves the jogger fences 53; the bundle branching drive motor 161 that rotates the branching guide plate 54 and the movable guide 55; the bundle carrying motor (not shown) that drives the carrying roller carrying the bundle; the rear end fence moving motor (not shown) that moves the movable rear end fence 73; the folding plate drive motor 166 that moves the folding plate 74; and the folding roller drive motor that drives the folding roller 81. The pulse signal of a staple carrying motor, not shown, that drives the staple paper discharging roller is input to the CPU 360 to be counted, and the tapping SOL 170 and the jogger motor 158 is controlled based on the counting.
The folding roller drive motor is a stepping motor directly controlled by the CPU 360 through a motor driver or indirectly controlled via the I/O interface 370 and the motor driver. The punching unit performs punching based on the instruction from the CPU 360 by controlling a clutch or a motor.
The CPU 360 executes the computer program written into a ROM not shown using a RAM not shown as a work area to control the sheet post-processing apparatus PD.
An operation performed by the sheet post-processing apparatus according to the embodiment through the CPU 360 will now be described.
In this embodiment, the sheets are discharged according to the following five post-processing modes:
Non-staple mode a: a mode in which a sheet is discharged to the upper tray 201 through the carrying passages A and B;
Non-staple mode b: a mode in which a sheet is discharged to the shift tray 202 through the carrying passages A and C;
Sort and stack mode: a mode in which a sheet is discharged to the shift tray 202 through the carrying passages A and C and the shift tray 202 swings in a direction orthogonal to the paper discharging direction every time a set of sheets is discharged to sort the discharged sheets;
Staple mode: a mode in which the sheet bundle that have passed through the carrying passages A and D is aligned and bound at the edge surface stitching tray F, and then discharged to the shift tray 202 through the carrying passage C; and
Saddle stitch binding mode: a mode in which the sheet bundle that have passed through the carrying passages A and D is aligned and saddle stitched at the edge surface stitching tray F, folded at the saddle stitching and saddle folding tray G, and discharged to the lower tray 203 through the carrying passage H.
The operations of the modes are described below.
(1) Operation of the Non-Staple Mode a
The sheet from the carrying passage A is distributed to the carrying passage B by the branching claw 15 to be discharged to the upper tray 201 by the carrying roller 3 and the upper paper discharging roller 4. A paper discharging condition is monitored by the upper paper discharging sensor 302, which detects the sheet discharging, arranged close to the upper paper discharging roller 4.
(2) Operation of the Non-Staple Mode b
The sheet from the carrying passage A is distributed to the carrying passage C by the branching claws 15 and 16 to be discharged to the shift tray 202 by the carrying roller 5 and the shift paper discharging roller 6. The paper discharging condition is monitored by the shift paper discharging sensor 303, which detects the sheet discharging, arranged close to the shift paper discharging roller 6.
(3) Operation of the Sort and Stack Mode
The sheet is carried and discharged in the same manner as that of the non-staple mode b. At this time, the shift tray 202 swings in the paper discharging direction and the direction orthogonal thereto for every set of sheets to sort the discharged sheets.
(4) Operation of the Staple Mode
The sheet from the carrying passage A is distributed to the carrying passage D by the branching claws 15 and 16 and discharged to the edge surface stitching tray F by the carrying rollers 7, 9, and 10 and the staple paper discharging roller 11. The edge surface stitching tray F aligns the sheets sequentially discharged by the staple paper discharging roller 11, and performs binding by the edge surface stitching stapler S1 when the number of the discharged sheets reaches a predetermined amount. Subsequently, the bound sheet bundle is carried downward by the release claw 52a and discharged to the shift tray 202 by the shift paper discharging roller 6. The paper discharging state is monitored by the shift paper discharging sensor 303 that is arranged close to the shift paper discharging roller 6 and detects the sheet discharging.
When the staple mode is selected, as shown in
When a predetermined time has passed after the tapping SOL 170 is turned off, the jogger fences 53 are further moved inward by 2.6 millimeters by the jogger motor 158 and stops. The alignment in the lateral direction is thus completed. Subsequently, the jogger fences 53 move outward by 7.6 millimeters to return to the standby positions and wait for the next sheet. This operation is continued until the final sheet is aligned. Subsequently, the jogger fences 53 move inward again by 7 millimeters and stop and then holds both ends of the sheet bundle to prepare for the stapling. The edge surface stitching stapler S1 is operated by a staple motor not shown after a predetermined time and the binding is performed. At this time, if two or more positions for binding are specified, the stapler moving motor 159 is driven after the binding at the first position to move the edge surface stitching stapler S1 to the appropriate position along the sheet rear end and the binding is performed at the second position. If three or more positions are specified, this operation is repeated.
When the binding processing is completed, the release motor 157 is driven to drive the release belt 52. At this time, the paper discharging motor is also driven to rotate the shift paper discharging roller 6 to receive the sheet bundle that is lifted by the release claw 52a. The jogger fences 53 are controlled differently depending on the sheet size and the number of binding sheets. For example, if the number of the binding sheets is smaller than the set number or the size of the binding sheets is smaller than the set size, the release claw 52a hooks the rear end of the sheet bundle to carry while the jogger fences 53 hold the sheet bundle. Upon receiving a predetermined amount of pulse after the detection of the paper presence/absence sensor 310 or the release belt home-position sensor 311, the jogger fences 53 retreat by 2 millimeters to release the sheet. The predetermined amount of pulse is set to be sent during the period starting when the release claw 52a becomes in contact with the rear end of the sheet and until the release claw 52a passes through the front end of the jogger fences 53. If the number of the binding sheets is larger than the set number or the size of the binding sheets is larger than the set size, the jogger fences 53 are retreated by 2 millimeters in advance and the sheet is released. In both cases, when the sheet bundle have completely passed through the jogger fences 53, the jogger fences 53 further move outward by 5 millimeters to return to the standby position and prepare for the next sheet. Binding force may be adjusted based on the distance between the sheet and the jogger fences 53.
(5) Operation of the Saddle Stitch Binding Mode
Referring to
After the sheet bundle is temporarily aligned in the edge surface stitching tray F, the sheet bundle is lifted by the release claw 52a as illustrated in
After that, the sheet bundle is carried by the release claw 52a until the rear end of the sheet bundle passes through the release roller 56. Then, the sheet bundle is further carried to the position illustrated in
The pressing amount of the stopper (the movable rear end fence 73) or the saddle stitching jogger fences 250 are changed to the optimal amount for aligning based on the size information, the information about the number of the sheets, and the information about the bundle thickness. If the thickness of the bundle is large, the space in the carrying passage is decreased, and therefore, the sheets are less likely to be aligned by only one alignment operation. Thus, the number of the alignment operations can be increased to achieve the alignment with high accuracy.
It is to be noted that if the number of sheets is larger, a longer time is required for sequentially overlapping the sheets on the upstream side making the interval until the next bundle can be received longer. As a result, the increase of the number of the alignment does not cause the time loss in the system, thereby achieving the alignment with high accuracy efficiently. Note that the effective processing can also be performed by controlling the number of alignment depending on the processing time at the upstream side.
The aligned sheet bundle is saddle stitched by the saddle stitching stapler S2 (
The movable rear end fence 73 is positioned by the pulse control from the movable rear end fence home-position sensor 322, and the rear end tapping claw 251 is positioned by the pulse control from the rear end tapping claw home-position sensor 326. As illustrated in
The sheet bundle can be surely carried by only moving the movable rear end fence 73 because the saddle stitched sheet bundle moves upward to be folded. Moving the sheet bundle downward to be folded may not be achieved only with the movement of the movable rear end fence 73 because the friction and the static electricity may hamper the sheet bundle from following the downward movement of the movable rear end fence 73, thereby providing less stable carrying. Accordingly, to move the movable rear end fence 73 downward, other units such as a carrying roller are required and the configuration becomes complicated.
As illustrated in
As illustrated in
The operation for aligning such a sheet using a jogger has been described with reference to
Fh=F*cos
Fv=F*sin
When the above Equations are applied to the acceptable angle of the curl, that is, 45 degrees, the relationship between the two component forces Fh and Fv is expressed by Equation (1):
Fh:Fv=1:1 (1)
The component force Fh corresponds to resistance force FSf generated by the friction coefficient between the sheets attempting to move. To move the sheets, the relationship:
Fh>FSf (2)
is required.
On the other hand, the component force Fv for sliding the edge surface a of the sheet Sn on the alignment surface 53z of the jogger 53b corresponds to resistance force FJf generated by the friction coefficient between the sheet and the jogger 53b. To move the sheet in the horizontal direction without sliding on the alignment surface 53z of the jogger 53b, the relationship:
Fv<FSf (3)
is required. If the angle β of the curled portion is 45 degrees, the following relationship is required:
FSf<FJf (4)
To make it simpler, the following relationship is required:
the friction coefficient between the sheets<the friction coefficient between the sheet and the alignment surface of the jogger (5)
In general, the friction coefficient of the sheet Sn is approximately 0.8 at maximum. If the friction coefficient between the edge surface a of the sheet Sn and the alignment surface 53z of the jogger 53 is set to be equal to or more than 0.8, the condition of Equation (5) can be satisfied.
In this example, the angle β of the curled portion SC is 45 degrees, which is the allowable limit. In the sheet post-processing apparatus PD in which the angle β of the curled portion SC is approximately 30 degrees at maximum, the friction coefficient between the edge surface a of the sheet and the jogger 53b may be set to be equal to or more than 0.46. Accordingly, the friction coefficient of the alignment surface 53z between the joggers 53a and 53b is set based on the maximum angle β of the curled portion SC in the sheet post-processing apparatus PD to be used. To obtain the friction coefficient, a coating material is selected. In this embodiment, urethane is used as the coating material. The urethane coating layer 53coat is formed on the surface of the alignment surface 53z to make the friction coefficient between the edge surface a and the alignment surface 53z equal to or more than 0.8. Moreover, the urethane coating layer 53coat is made to have conductivity. The conductivity can be obtained by mixing carbon powder into urethane, for example.
Meanwhile, in
In the examples illustrated in
The present embodiment can provide the following effects.
1) Each alignment surface 53z of the joggers 53a and 53b that aligns the sheet is in a planar shape. When the curled end (edge surface a) of the sheet Sn contacts the alignment surface 53z and the sheet Sn is pressed, because the joggers 53a and 53b holds the edge surface a at the position contacting the alignment surface 53z, the edge surface a does not slide on the alignment surface 53z upon aligning the sheet. Therefore, reliable and highly accurate alignment is possible.
2) The sheet holding function (the function for preventing the sheet from sliding) on the alignment surface 53z is set based on the friction coefficient between the angle of the curled portion SC of the sheet Sn and the alignment surface 53z. Thus, the friction coefficient required for holding sheets can be calculated. Accordingly, the alignment surface 53z can be designed easily based on the friction coefficient.
3) The angle of the curled portion SC used at the setting of the friction coefficient is equal to or less than 45 degrees. Accordingly, the quality required as a product can be provided.
4) The sheet holding function of the alignment surface 53z can be obtained by coating. Accordingly, the required holding function can be obtained by only selecting the coating material.
5) The alignment surface 53z only requires to be coated with urethane that is a material having relatively high friction coefficient. Accordingly, the highly accurate alignment can be achieved without adding a special member or forming concavity and convexity on the alignment surface 53z.
6) The urethane coating 53coat has enough uniform film thickness and durability to be used for a carrying roller that generally requires high accuracy. The friction coefficient can be easily adjusted by compounding. Accordingly, the friction coefficient can be set that is most suitable for the edge surface a in terms of strength and durability.
7) The urethane coating 53coat has conductivity, and thus is capable of eliminating the effect of static electricity. As a result, even the sheet having static electricity can be aligned with high accuracy without sticking and floating.
8) The curled edge surface a of the sheet or the sheet bundle does not slide on the alignment surface 53z. Accordingly, a curled sheet or a soft sheet can be aligned on the planer alignment surface 53z with high accuracy.
9) The alignment surface 53z is formed of a plate or a molded material and required to have high planer characteristics. The coating of a film having a thickness of about 40 microns does not undermine the essential characteristics (flatness). Accordingly, the excellent alignment can be performed.
10) By providing the pressing Mylers 53c and 53d and a retractable pressurizing plate 110 to press the vicinity of the wall surface in the sheet bundle thickness direction, the alignment with even higher accuracy can be performed.
11) The urethane coating is performed on the release claw 52a, the front end aligning claw 52b′, the sheet contact surfaces 52acoat and 52b′coat of the rear end fences 51, and the like to obtain a predetermined friction coefficient. Accordingly, the end of the sheet (edge surface of the sheet) does not slide on the contact surface, and therefore, highly accurate alignment in the sheet carrying direction can be performed.
In the above embodiment, the sheet corresponds to a sheet Sn, the sheet bundle corresponds to a reference character S, the alignment member corresponds to jogger fences 53, 53a, and 53b, the alignment surface corresponds to a reference numeral 53z and contact surfaces 52acoat and 52b′coat, the curled end corresponds to an edge surface a, the coating corresponds to a coating layer 53coat, the first lateral direction aligning unit corresponds to the joggers 53, 53a, and 53b, the first longitudinal direction aligning unit corresponds to rear end fences 51, 51a, and 51b and a front end aligning claw 52b, the first processing apparatus corresponds to a edge surface binding stapler S1, the bundle transferring unit corresponds to a release claw 52a and a release belt 52, the second processing apparatus corresponds to a saddle stitching stapler S2 or a folding plate 74 and a folding roller 81, the second lateral direction aligning unit corresponds to a saddle stitching upper jogger fence 250a and a saddle stitching lower jogger fence 250b, the second longitudinal direction aligning unit corresponds to a movable rear end fence 73 and a rear end tapping claw 251, the bundle carrying unit corresponds to the movable rear end fence 73, the pressing unit corresponds to a rear end pressing lever 110 or pressing Mylars 53c and 53d, the sheet processing apparatus corresponds to a sheet post-processing apparatus PD, and the image forming apparatus corresponds to a reference character PR.
Note that the prevent invention is not limited to the embodiment and all technical matters included in the technical idea described in the scope of the appended claims are included in the present invention.
In the present invention, an alignment member has a holding function that holds the end of a sheet at a position contacting an alignment surface when the alignment member performs pressing to align the sheet. Consequently, even with curl or soft paper, a sheet bundle aligned with high accuracy can be obtained by the pressing of a planer wall.
Although the invention has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
Number | Date | Country | Kind |
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2008-317313 | Dec 2008 | JP | national |