Sheet finishing method, sheet finisher and image forming apparatus for use therewith

Information

  • Patent Grant
  • 6746390
  • Patent Number
    6,746,390
  • Date Filed
    Monday, August 12, 2002
    22 years ago
  • Date Issued
    Tuesday, June 8, 2004
    20 years ago
Abstract
A sheet finishing method in which a sheet delivered from an image forming apparatus main body is conveyed and stacked on a sheet placement table, and the stacked sheets are positioned and aligned, and then folded by a folding means composed of a paired folding rollers and a folding plate. The sheet finishing method is controlled such that a rotation motion of the paired folding rollers is switched between a state to be rotated along with an advancing motion of the folding plate and a state to be stopped in accordance with the number of sheets stacked on the sheet placement table.
Description




BACKGROUND OF THE INVENTION




The present invention relates to a sheet finisher provided with a function by which a sheet delivered from an image forming apparatus such as an electrophotographic copier, printer, facsimile device and a hybrid machine having these many functions is received, stacked in a sheet accommodation section and a finishing such as a folding processing is conducted, and delivered onto a sheet delivery section.




There is provided a sheet finisher by which many number of sheets on which images are recorded by an image forming apparatus main body such as a copier, printer, facsimile device or hybrid machine of these devices are collated for each number of printed volumes, stapled by a stapler and bookbound. This sheet finisher is connected to a print function of the image forming apparatus main body and driven.




As a sheet finisher to conduct the staple processing on a sheet bundle which is a set formed of a plurality of sheets, Japanese Patent Publication Tokkaihei No. 2-276691, 8-319054, or Japanese Patent Publication Tokkohei No. 5-41991 are disclosed.




As the sheet finisher by which a central portion of the sheet bundle is center-stapled, and center-folded at the center-stapled portion and a simple bookbinding is conducted, a sheet finisher written in Japanese Patent Publication Tokkaihei NO. 10-181990 is well known.




This sheet finisher is provided with, for the center-stapling and center-fold processing of the sheet bundle, a center-fold processing section composed of a pair of center-folding rollers which are rotated in pressure-contact with each other, and a center-folding plate to push the center-stapled portion of the sheet bundle in the nip position of the center-folding rollers.




In the sheet finisher to conduct the center-fold processing, there are following problems.





FIG. 18

is a sectional view of the conventional center-fold processing section. The center-fold processing section is structured by a pair of folding rollers composed of an upper roller


83


A and lower roller


84


A, and a folding plate


82


A.




In the center-fold processing section, the center-stapling and center-fold processing, center-fold processing of a small number of sheets, and three-fold processing of a small number of sheets are conducted.




In the case where the center-fold processing is conducted without conducting the staple processing on the small number of sheets, when, while the upper roller


83


A and lower roller


84


A are rotated, the folding plate


82


A is pushed in a nip portion N of the folding roller pair, the sheet S


1


in contact with the outer peripheral surface of the upper roller


83


A and lower roller


84


A reaches the nip position N earlier and is folded, and in a folded portion between it and the sheet S


2


in contact with the sheet S


1


, the slippage between sheets as shown in the drawing, is generated. Particularly, when the advancing speed of the folding plate


82


A is lower than the peripheral velocity of the outer peripheral surface of the upper roller


83


A and lower roller


84


A, the slippage between sheets is conspicuous.




When the advancing speed of the folding plate


82


A is made higher than the peripheral velocity of the outer peripheral surface of the upper roller


83


A and lower roller


84


A, the sheets S


1


and S


2


which are pushed in by the folding plate


82


A are forcibly pushed in the nip position N, and there is a case where a breakage is generated in the sheet bundle.




SUMMARY OF THE INVENTION




The object of the present invention is to solve the above problems and to provide a sheet finisher for use with an image forming apparatus by which a good folding processing can be conducted on the sheet bundle.




The above object can be solved by the following sheet finishing method, sheet finisher, and image forming apparatus.




(1) A sheet finishing method in which a sheet delivered from an image forming apparatus main body is conveyed and stacked on a sheet placement table, and the stacked sheets are positioned and aligned, and then folded by a folding means composed of a paired folding rollers and a folding plate, the sheet finishing method is characterized in that it is controlled such that a rotation motion of the paired folding rollers is switched between a state to be rotated along with an advancing motion of the folding plate and a state to be stopped in accordance with the number of sheets stacked on the sheet placement table.




(2) A sheet finisher in which a sheet delivered from an image forming apparatus main body is conveyed and stacked on a sheet placement table, and the stacked sheets are positioned and aligned, and folded by a folding means composed of a paired folding rollers and a folding plate, the sheet finisher is characterized in that it has a detection means for detecting the number of sheets, the first drive means for rotating the paired folding rollers, the second drive means for making the folding plate to advance and retreat, and a control means for controlling the drive of the first drive means and the second drive means, and it is controlled such that a rotation motion of the paired folding rollers is switched between a state to be rotated along with an advancing motion of the folding plate and a state to be stopped in accordance with the number of sheets detected by the detection means.




(3) An image forming apparatus which is characterized in that it is provided with an image forming apparatus main body composed of an image writing means, image forming means, and sheet conveying means and the sheet finisher described in (2).











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is an overall structural view of an image forming system structured by an image forming apparatus main body, image reading apparatus, and finisher.





FIG. 2

is an overall structural view showing a conveying path of a sheet in the finisher according to the present invention.





FIG. 3

is a sectional view of the finishing unit composed of a stapling section and fold processing section.




FIGS.


4


(


a


)-


4


(


c


) are plan views showing an arrangement of a stapling means and a sheet bundle when each kind of stapling is conducted.





FIG. 5

is a front view of a fold processing section.





FIG. 6

is a perspective view of the fold processing section.





FIG. 7

is a structural view of a folding roller drive means.





FIG. 8

is a plan view of a folding plate drive means.





FIG. 9

is a sectional view of the folding plate drive means.




FIGS.


10


(


a


)-


10


(


c


) are sectional views showing a process of a two-fold processing by a fold processing section.




FIGS.


11


(


a


)-


11


(


c


) are a perspective view of a sheet bundle on which the finishing of a center-stapling and two-folding is conducted (FIG.


11


(


a


)), a perspective view of the sheet bundle in the double-opened condition (FIG.


11


(


b


)), and a typical sectional view of the sheet bundle (FIG.


11


(


c


)).




FIG.


12


(


a


) is a developed plan view to be tree-fold processed sheet, FIG.


12


(


b


) is a perspective view of the three-fold processed sheet, and FIG.


12


(


c


) is a perspective view of the three-fold processed sheet into Z-shape.




FIGS.


13


(


a


)-


13


(


d


) are sectional views showing the three-fold processing process.





FIG. 14

is a block diagram showing the control of an image forming apparatus main body and finisher.





FIG. 15

is an enlarged sectional view showing a fold processing of a small number of sheets by a folding plate, upper roller, and lower roller.





FIG. 16

is a typical view showing the arrangement of a motor and sensor in a stapling section and fold processing section.




FIGS.


17


(


a


)-


17


(


i


) are timing charts showing the control of the fold processing.





FIG. 18

is a sectional view of the conventional center-fold processing section.











DETAILED DESCRIPTION OF THE PREFERRED INVENTION




Next, referring to the drawing, a sheet finisher of the present invention and an image forming apparatus equipped with the sheet finisher will be described.




An Embodiment of the Image Forming Apparatus





FIG. 1

is a overall structural view of an image forming system composed of an image forming apparatus main body A, image reading apparatus B, and sheet finisher (hereinafter, called finisher) FS.




The forming apparatus main body A has an image forming section in which a charging means


2


, image exposure means (writing means)


3


, developing means


4


, transfer means


5


A, discharging means


5


B, separation claw


5


C, and cleaning means


6


are arranged around a rotating image carrier (hereinafter, called photoreceptor)


1


, and after uniform charging is conducted on the surface of the photoreceptor


1


by the charging means


2


, an exposure scanning according to the image data read from the document is conducted by the laser beam of the image exposure means


3


, and a latent image is formed, and the latent image is reversal developed by the developing means


4


, and a toner image is formed on the surface of the photoreceptor


1


.




On the one hand, a sheet S fed from a sheet accommodation means


7


A is sent to a transfer position. In the transfer position, the toner image is transferred onto the sheet S by the transfer means


5


A. After that, electric charges of the rear surface of the sheet S is eliminated by the discharging means


5


B, separated from the photoreceptor


1


by the separation claw


5


C, conveyed by an intermediate conveying section


7


B, succeedingly, heating fixed by the fixing means


8


, and delivered from a sheet delivery section


7


C.




When the image formation is conducted on double sides of the sheet S, the sheet S which is heating fixed by the fixing means


8


, is branched from a normal sheet delivery path by a conveying path switching plate


7


D, and after it is switched back and front and rear surfaces are reversed in the reversal conveying


7


E, it is delivered to the outside of the apparatus by the sheet delivery section


7


C. The sheet S delivered from the sheet delivery section


7


C, is sent to the finisher FS.




On the one hand, on the surface after the image processing of the photoreceptor


1


, the developing agent remained on the surface is removed by the cleaning means


6


in the downstream of the separation claw


5


C, and the photoreceptor


1


stands by the next image formation.




On the front surface side of the upper portion of the image forming apparatus main body A, an operation section


9


to select and set an image formation mode and sheet finishing mode is arranged.




On the upper portion of the image forming apparatus main body A, there is arranged an image reading apparatus B equipped with an automatic document feeding apparatus of a document movement type reading-out system.




Sheet Finishing Apparatus





FIG. 2

is an overall structural view showing a conveying path of the sheet S in the sheet finisher FS according to the present invention.




In the finisher FS, on the upper stage in the drawing, the first sheet feeding means


20


A and the second sheet feeding means


20


B and fixed sheet delivery table


30


are arranged, and on the middle stage, a punching means


40


, shift means


50


and sheet delivery means


60


are serially arranged on the almost horizontal same plane, and on the lower stage, a staple processing section


70


and fold processing section


80


are serially arranged on the slanting same plane.




Further, on the left side surface in the drawing of the finisher FS, there are arranged an elevation sheet delivery table


91


on which a shift processed sheet S and end staple processed sheet bundle Sa are stacked, and a fixed sheet delivery table


92


on which three-folding or two-folding processed sheet bundle Sb is stacked.




The position and height of the finisher FS are adjusted in such a manner that a receiving section


11


of the sheet S conveyed from the image forming apparatus main body A coincides with the sheet delivery section


7


C of the image forming apparatus main body A, and the finisher FS is arranged.




The sheet S which is image forming processed, supplied from the image forming apparatus main body A, an interleaf K


1


which partitions between sheet bundles supplied from the first sheet feeding means


20


A, and a cover sheet K


2


supplied from the second sheet feeding means


20


B are introduced into the receiving section


11


.




Sheet Feeding Means




The interleaf K


1


accommodated in the sheet feeding tray of the first sheet feeding means


20


A is separated and fed by a sheet feeding section


21


, nipped by conveying rollers


22


,


23


,


24


, and introduced into the receiving section


11


. Further, the cover sheet K


2


accommodated in the sheet feeding tray of the second sheet feeding means


20


B is separated and fed by the sheet feeding section


25


, nipped by the conveying rollers


23


and


24


, and introduced into receiving section


11


.




Sheet Branching Means




A sheet branching means composed of switching means G


1


and G


2


is provided on the downstream side in the sheet conveying direction of the punching means


40


. The switching means G


1


and G


2


are selectively branched to any one of three sheet conveying paths, that is, the first conveying path (


1


) for the upper stage sheet delivery, the second conveying path (


2


) for the middle stage, and the third conveying path (


3


) for the lower stage, by the drive of a solenoid which is not shown.




Simple Sheet Delivery




When this sheet conveying is set, the switching means G


1


shuts off the second conveying path (


2


), and the third conveying path (


3


), and only the first conveying path (


1


) is opened.




The sheet S which passes the first conveying path (


1


) is nipped by the conveying roller


31


and elevated, delivered by the delivery roller


32


, placed on the fixed sheet delivery table


30


, and succeedingly stacked.




On the fixed sheet delivery table


30


, maximum about 200 sheets S can be stacked.




Shift Processing




When the sequence is set to this conveying mode, the switching means G


1


is withdrawn upward, the switching means G


2


shuts off the third conveying path (


3


) and opens the second conveying path (


2


), thereby, the pass of the sheet S is made possible. The sheet S passes the sheet path formed between the switching means G


1


and G


2


.




The sheet S which is delivered from the image forming apparatus main body A and on which the image is formed, or the interleaf K


1


fed from the first sheet feed means


20


A, or the cover sheet K


2


fed from the second sheet feed means


20


B, passes the intermediate sheet path of the switching means G


1


and G


2


, and by the shifting means


50


, it is shifting processed so that a predetermined amount is moved in the direction perpendicular to the sheet conveying direction, and conveyed in the sheet delivery direction.




The shifting means


50


conducts the shift processing by which the sheet delivery position of the sheet S is changed in the conveying width direction for each predetermined number of sheets. The shift processed sheet S is delivered on the elevation sheet delivery table


91


outside the apparatus by the sheet delivery means


60


and succeedingly stacked. This elevation sheet delivery table


91


is structured in such a manner that, when many number of sheets S are delivered, it is succeedingly lowered, and can accommodate sheets S of maximum about 3000 sheets (A


4


, B


5


).




Staple Processing





FIG. 3

is a sectional view of a finisher unit


10


composed of a staple processing section


70


and fold processing section


80


.




In the operation section


9


, when the staple processing (refer to FIGS.


4


(


a


)-


4


(


d


)) or fold processing is set, the image formed sheet S which is image forming processed in the image forming apparatus main body A and sent into the receiving section


11


of the finisher FS, passes a punching means


40


(refer to FIG.


2


), and is sent into the third conveying path (


2


) below the switching means G


2


, held by the conveying roller


12


, and conveyed downward.




In the third conveying path (


3


), when the sheet S whose size is larger than A


4


, or B


5


size, is conveyed, the solenoid SD


1


is driven and the sheet S passes the path


13


A on the left side in the drawing of the switching means G


3


and held by the conveying roller


14


, and conveyed downward. The sheet S is nipped by inlet conveying roller pair


15


located further downstream and sent out, delivered to the upper space of the sheet placement table


71


slantingly arranged, and comes into contact with the sheet placement table


71


or the upper surface of the sheet S which is stacked on the sheet placement table


71


, and conveyed to the obliquely upward portion. After the trailing edge portion in the advancing direction of the sheet S is delivered from the holding position of the conveying roller


14


, it turns to the lowering by the self weight of the sheet S, conveyed on the slant surface of the sheet placement table


71


, and trailing edge of the sheet S comes into contact with the sheet contact surface of the sheet trailing edge contact member (hereinafter, called also the first contact member)


72


for the end-stapling in the vicinity of the staple means composed of a staple-pin striking mechanism


701


and a staple-pin receiving mechanism


702


, and is stopped. Numeral


16


is a rotating endless belt-like sheet guiding member (hereinafter, called a winding-in belt), which slide-contacts with the leading edge portion of the sheet S and winds-in it and sends to the first contact member


72


. In this connection, the sheet guiding member


16


may also be a rotatable vane wheel.




In the third conveying path (


3


), in order to effectively and continuously convey the small sized sheet S such as A


4


or B


5


, and increase the copy productivity, a movable switching means G


3


and a sheet path


13


B parallel to the sheet path


13


A on the left side in the drawing of the switching means G


3


are provided.




When the solenoid SD


1


connected to the switching means G


3


is driven, the sheet path


13


A is shut off, and the sheet path


13


B is opened.




The leading edge portion of the small sized sheet S of the first sheet sent from the conveying roller


12


passes the sheet path


13


B, and is brought into contact with the peripheral surface of the inlet conveying roller pair which are in the rotation stop condition, and stopped.




Next, the electric power of the solenoid SD


1


is turned off, the leading edge portion of the switching means G


3


is moved clockwise and shuts off the sheet path


13


B, and opens the sheet path


13


A. The leading edge portion of the second sheet S sent from the conveying roller


12


passes the sheet path


13


A and is brought into contact with the peripheral surface of the inlet conveying roller pair


15


in the rotation stop condition and stopped. Accordingly, in the vicinity of the nip position of the inlet conveying roller pair


15


, each of leading edge portions of the first sheet S and the second sheet S is overlapped with each other and stopped, and on standby the next operation.




In the predetermined timing, the inlet conveying roller pair


15


is rotated, and two sheets S are held and simultaneously conveyed and delivered onto a sheet placement table


71


. After the third sheet, the inlet conveying roller pair


15


delivers the sheet S one by one sheet.




Numeral


73


is a pair of width alignment members of the upstream side provided movably on both side surfaces of the sheet placement table


71


. The width alignment member


73


can be moved in the sheet width direction perpendicular to the sheet conveying direction, and at the time of the sheet receiving at which the sheet S is conveyed onto the sheet placement table


71


, it is opened more widely than the sheet width. The sheet S is conveyed on the sheet placement table


71


, and when the sheet S is brought into contact with the first contact member


72


and stopped, the width alignment member


73


taps the side edge in the width direction of the sheet S and conducts the width alignment (the width adjustment) of the sheet bundle Sa. In this stop position, when a predetermined number of the sheets S are stacked and adjusted on the sheet placement table


71


, the staple processing is conducted by the staple means composed of a staple-pin striking mechanism


701


and staple-pin receiving mechanism


702


, and the sheet bundle Sa is stapled.




In a portion of the sheet placement surface of the sheet placement table


71


, a cutout portion is formed, and a delivery belt


75


trained around the drive pulley


74


A and driven pulley


74


B is rotatably driven. In a portion of the delivery belt


75


, a delivery claw


76


is integrally formed, and its leading edge portion draws a locus X of an ellipse as shown by one-dotted chain line in the drawing. The trailing edge of the sheet S of the staple processed sheet bundle Sa is held by the delivery claw


76


of the delivery belt


75


, placed on the delivery belt


75


, and slides on the placement surface of the sheet placement table


71


and is pushed oblique-upwardly and advances to the holding position of the delivery roller


61


(refer to

FIG. 2

) of the sheet delivery means


60


. The sheet bundle Sa held by the rotating delivery roller


61


is delivered and stacked onto the elevation sheet delivery table


91


(refer to FIG.


2


).




The sheet placement table


71


on which the sheet bundle Sa is placed, staple processing section


70


, and folding section


80


are arranged on a frame of the finishing unit


10


, and can be pulled out on the front surface side of the finisher FS by being guided by slide rails R


1


and R


2


.




FIGS.


4


(


a


)-


4


(


c


) are plan views showing the arrangement of the staple means


700


composed of the staple-pin striking mechanism


701


and staple-pin receiving mechanism


702


, and the sheet bundle Sa, when each kind of stapling is conducted. FIG.


4


(


a


) is a plan view showing the flat staple processing by which, in the vicinity of a side edge of the sheet bundle Sa, the staple pins SP are stapled at two portions distributed at the center, FIG.


4


(


b


) is a plan view showing the edge staple processing by which, in one portion near the corner portion of the sheet bundle Sa, the staple pin SP is stapled, and FIG.


4


(


c


) is a plan view showing the center staple processing by which the staple pins SP are stapled at two portions of the central portion.




Center Staple Processing




The staple means


700


is structured into the two dividing structure of the staple-pin striking mechanism


701


and staple-pin receiving mechanism


702


, and the sheet path


77


A on which the sheet S can pass, is formed between them (refer to FIG.


3


).




Two sets of the stapling means


700


are arranged in the sheet width direction perpendicular to the sheet conveying direction, and can be moved in the sheet width direction by the drive means which is not shown.




When the flat staple processing shown in FIG.


4


(


a


) is set, by two sets of the stapling means


700


, the staple pins SP are stapled at two center distributed portions in the sheet width direction of the sheet bundle Sa.




When the end staple processing shown in FIG.


4


(


b


) is set, the stapling means


700


straightly advanced in the sheet width direction, and the staple pins SP are struck at one portion of the corner portion of the sheet bundle Sa corresponding to the sheet size. When the center-stapling and the center-fold processing shown in FIG.


4


(


c


) is set, the staple pins SP are struck at two central portions of the sheet bundle Sa.




When the stapling is set to the center staple processing, the first contact member


72


in the vicinity of the staple processing position (the staple-pin striking position) of the stapling means


700


is withdrawn from the conveying path, and almost simultaneously, the second contact member


78


for the combined use of the center stapling and center-fold processing positioned downstream it, is moved in the extension surface direction of the sheet path


77


A, and shuts off the sheet path


77


B.




The center stapling stopper unit having the second contact member


78


, when the size of the cover sheet K


2


and sheet S (length in the conveying direction) is set or detected, is moved to a position contacted with the lower edge portion of the sheet bundle Sa which is to be center-staple processed, and stopped.




After the cover sheet K


2


is placed at a predetermined stop position on the sheet placement table


71


, the sheet S conveyed from the image forming apparatus main body A passes the third conveying path (


3


) from the receiving section


11


of the finisher FS and successively stacked on the upper surface of the cover sheet K


2


placed on the sheet placement table


71


, and the leading edge portion of the sheet S is brought into contact with the second contact member


78


, and positioned.




After the final sheet S is positioned and placed on the sheet placement table


71


, the sheet bundle Sa formed of the cover sheet K


2


and all of the sheets S is center-staple processed by the stapling means


700


. By this center-staple processing, the staple pins SP is struck at the central portion in the conveying direction of the cover sheet K


2


and sheets S. The staple pins SP are struck from the staple-pin striking mechanism


701


of the staple pin drive side toward the staple-pin receiving mechanism


702


of the staple-pin clinch side.




Fold Processing





FIG. 5

is a front view of the fold processing section


80


, and

FIG. 6

is a perspective view of the fold processing section


80


.




The fold processing section


80


is arranged at the obliquely lower portion of the staple processing section


70


. After the center-staple processing, the second contact member


78


is linearly moved toward the conveying downstream direction of the sheet bundle Sa, and opens the path of the downstream of the sheet path


77


A. The movable second contact member


78


regulates the stop position of the sheet bundle Sa at the time of the center staple processing at the upper position, and regulates the stop position of the sheet bundle Sa at the time of the center fold processing at the lower position.




The center staple processed sheet bundle Sa formed of the cover sheet K


2


and sheet Sa is conveyed in the sheet path


81


A whose oblique lower portion is formed of the guiding plate


81


, and the edge portion in the conveying direction of the sheet bundle Sa is brought into contact with the second contact member


78


, and stops at the predetermined position. The second contact member


78


can be moved to the predetermined position by the setting of the sheet size or detection result and the drive means.




The sheet placement table


71


of the finishing unit


10


, sheet paths


77


A,


77


B, and


81


A are formed on the almost same plane, and form a steep slope of about 70°.




The fold processing section


80


is composed of the folding plate


82


, the first folding upper roller (hereinafter, called upper roller)


83


, the first folding lower roller (hereinafter, called lower roller)


84


, the second folding roller (hereinafter, called second roller)


85


, conveying belt


86


, tension roller


861


, conveying path switching member


87


, guiding plate


88


, and sheet leading edge stop member


89


, and the sheet bundle Sb is two-fold processed or three-fold processed.




The upper roller


83


and lower roller


84


are supported by one pair of left and right pressing means which form almost symmetrical forms. One side pressing means is composed of the upper roller


83


, support plate


832


which rotatably supports this upper roller, and can oscillate around the support axis


831


, and spring


833


which is engaged at one end of this support plate


832


and which urges the upper roller


83


toward the nip position direction. The lower roller


84


forms almost the symmetrical form with the upper roller


83


, and is composed of the support axis


841


, support plate


842


, and spring


843


. The upper roller


83


and the lower roller


84


are rotated by the first drive means


801


which will be described later.




Each outer peripheral surface of the upper roller


83


and lower roller


84


is formed of a high frictional resistant material.




Drive Mechanism of the Fold Processing Section





FIG. 7

is a structural view of the upper roller


83


, lower roller


84


, and folding roller drive means (first drive means)


801


to rotate the second roller


85


, of the fold processing section


80


. In this connection, the one-doted chain line shown in the drawing shows a pitch circle of a gear.




A motor M


1


drives the lower roller


84


through a gear train composed of gears g


1


, g


2


A, g


2


B, g


3


A, g


3


B, g


4


, g


5


, and g


6


. Further, the motor M


1


drives the upper roller


83


through a gear train composed of gears g


1


, g


2


A, g


2


B, g


3


A, g


3


B, g


4


, g


7


, g


8


, and g


9


.




The second roller


85


is brought into pressure-contact with the lower roller


84


by the spring


851


, and driven.




Drive Mechanism of the Folding Plate





FIG. 8

is a plan view of a folding plate drive means (second drive means)


802


to move the folding plate


82


. In this connection, because the folding plate drive means


802


forms the line symmetry to the center line CL in the drawing, a portion of the drawing is neglected. In this connection, the drive members forming the symmetry are denoted by the same reference numerals.





FIG. 9

is a sectional view of the folding plate drive means (second drive mean)


802


. Both of

FIG. 8 ands



FIG. 9

show a condition just before the sheet bundle Sa is center-fold processed.




A motor M


2


rotates a large diameter gear g


13


through gears g


10


, g


11


and g


12


. The gear g


13


is rotatably supported by the support axis


824


planted on the fixed base plate


826


. On the base portion of the gear g


13


, an eccentric cylinder member


823


is integrally formed. A ring-like concave portion


823


A provided in the eccentric cylinder member


823


is, by the rotation of the gear g


13


, eccentrically moved around an eccentric axis


823


B whose rotation center is different from that of the support axis


824


.




On an inner wall portion of the ring-like concave portion


823


A, a roller


825


planted on the moveable holding member


821


is movably provided. A sign Y is an eccentric circle locus of the center of the roller


825


.




The movable holding member


821


is supported in such a manner that it can conduct the straight advance reciprocal movement along two guiding members


822


parallely arranged on the fixed base plate


826


. By the rotation of the gear g


13


, when the ring-like concave portion


823


A is eccentrically moved, the roller


825


is moved along the inner wall of the ring-like concave portion


823


A and the movable holding member


821


conducts the straight advance reciprocal movement along the two guiding members


822


. The folding plate


82


fixed on the movable holding member


821


also conducts simultaneously the straight advance reciprocal movement.




Center-fold Processing of the Sheet




FIGS.


10


(


a


)-


10


(


c


) are sectional views showing processes of two-fold processing by the fold processing section


80


, and FIG.


10


(


a


) shows a condition that the folding plate


82


presses the sheet bundle Sa and makes it bring into contact-pressure with the upper roller


83


and lower roller


84


. FIG.


10


(


b


) shows a condition that the folding plate


82


enters a position beyond the nip position N between the upper roller


83


and lower roller


84


and the sheet bundle Sa is two-fold processed. FIG.


10


(


c


) shows a condition that the folding plate


82


is withdrawn from the nip position N between the upper roller


83


and lower roller


84


and returns to the initial position, and the two-fold processed sheet bundle Sa is delivered from the upper roller


83


and lower roller


84


.




By a two-fold processing start signal, the folding plate


82


connected to the drive source projects in the left direction in the drawing from the sheet placement surface. The folding plate


82


forms a 0.3 mm thick thin-type knife shape in the present embodiment, and its leading edge portion forms a sharp angle.




The leading edge portion of the folding plate


82


which is straightly advanced in the left direction in the drawing and is projected, pushes the central portion of the sheet bundle Sa, and widens the nip position N between the upper roller


83


and lower roller


84


through the sheet bundle Sa and separates them from each other.




After the leading edge portion of the folding plate


82


passes the nip position N between the upper roller


83


and lower roller


84


, the folding plate


82


is retreated and the central portion of the sheet bundle Sa is narrowed and pressed by the upper roller


83


and lower roller


84


, and a fold portion “c” is formed. This fold portion “c” almost coincides with the stapling position of the staple pin SP onto the sheet bundle Sa by the center-staple processing.




The sheet bundle Sa on which the fold portion “c” is formed by being narrow-pressed, is conveyed by the rotating upper roller


83


and lower roller


84


, and placed on the fixed sheet delivery table


92


outside the apparatus.




FIG.


11


(


a


) is a perspective view of the sheet bundle Sb on which the finishing of the center-stapling and two-folding is conducted, FIG.


11


(


b


) is a perspective view showing a condition in which the finished sheet bundle Sb is opened into two-leaves, and FIG.


11


(


c


) is typical sectional view of the sheet bundle Sb.




In the sheet bundle Sb made by the center-staple processing and two-fold processing, the first surface (p


1


, p


8


) of the cover sheet K


2


faces outward, and on its rear surface side, the second surface (p


2


, p


7


) is arranged, and further, in its inner side, the first surface (p


3


, p


6


) of the sheet S which is the content, is arranged, and in its inner side, the second surface (p


4


, p


5


) of the sheet S is arranged, and as shown in the drawing, a booklet Sb formed of 8 pages (p


1


-p


8


) can be collated.




Three-fold Processing




The fold processing section


80


shown in

FIG. 5

can conduct two modes of the two-fold processing and three-fold processing. The fold processing section


80


has the first folding means by which the sheet bundle Sa is two-fold processed, and the second folding means by which the sheet bundle Sa is three-fold processed.




The first folding means is composed of the upper roller


83


, lower roller


84


, and folding plate


82


. The second folding means is composed of the second roller


85


, conveying belt


86


, conveying path switching member


87


, guiding plate


88


, and sheet leading edge stop member


89


.




The position of the sheet leading edge stop member


89


is set so that the sheet conveying distance from the nip position N (refer to FIGS.


10


(


a


)-


10


(


c


)) between the upper roller


83


and lower roller


84


, to the sheet contact surface of the sheet leading edge stop member


89


is ⅓ of the conveying direction length of the sheet S.




The lower roller


84


and the second roller


85


are rotatably supported by the support plate


842


, and connected to the first drive means


801


(refer to FIG.


7


). The conveying belt


86


is trained around the outer peripheral surface of the lower roller


84


and second roller


85


, and tension roller


861


.




FIG.


12


(


a


) is a developed plan view of the sheet S to be three-fold processed, and FIG.


12


(


b


) is a perspective view of the three-fold processed sheet S. Folds “a”, “b” by which the length of the longitudinal direction of the sheet S is divided into about three equal parts, fold the sheet S into the surface A, surface B, and surface C. The sheet S to be tree-fold processed, is initially folded by a fold “a”, and next, folded by the fold “b” to the inside.




FIG.


12


(


c


) is a perspective view of the sheet S which is three-fold processed into a Z-letter shape. The sheet S to be three-fold processed is initially folded by the fold “b”, and next, folded by the fold “a” to the outside.




In this connection, the three-fold processing can fold simultaneously a small number of sheets, for example, about three sheets S. The sheet S which is three-fold processed is folded into a small size, and can be accommodated in the envelope of the ordinary mail.




FIGS.


13


(


a


)-


13


(


d


) are sectional views showing the three-fold processing process. In this connection, in this three-fold processing process, the inner side folding shown in FIG.


12


(


b


) is formed. When the three-fold processing is conducted into the Z-letter shape, the arrangement position of the second contact member


78


is changed, and the fold portion “b” is folded by the upper roller


83


and lower roller


84


.




(1) In FIG.


13


(


a


), the leading edge portion of the folding plate


82


presses the position of the fold “a” formed on the sheet S and inserts it into the nip position N (refer to FIGS.


10


(


a


)-


10


(


c


)) between the upper roller


83


and lower roller


84


. The upper roller


83


and lower roller


84


is rotated in the solid line arrowed direction, and while forming the fold portion “a” of the sheet S, the sheet S is nipped. After the fold portion “a” is formed by the upper roller


83


and lower roller


84


, the folding plate


82


is withdrawn from the nip position N, and returns to initial position.




(2) As shown in FIG.


13


(


b


), the sheet S whose fold “a” is formed between the upper roller


83


and lower roller


84


, is conveyed in the solid line arrowed direction by the rotating upper roller


83


and lower roller


84


, advances along the upper surface of the conveying path switching member


87


, and the fold portion “a” of the sheet S is brought into contact with the sheet leading edge stop member


89


.




(3) As shown in FIG.


13


(


c


), when the upper roller


83


and lower roller


84


are successively rotated, although the fold portion “a” of the sheet S is brought into contact with the sheet leading edge stop member


89


and its advance is blocked, a ⅓ portion of the length of the trailing edge of the sheet S is wound around the outer peripheral surface of the lower roller


84


whose frictional resistance is large, and conveyed to the nip position at which the lower roller


84


and the second roller


85


are pressure-contacted, and the fold portion “b” is formed on the sheet S.




(4) As shown in FIG.


13


(


b


), the fold portion “a” and fold portion “b” are formed at the nip position between the lower roller


84


and the second roller


85


, and the leading edge portion and trailing edge portion are folded back and the three-fold processed sheet S is nipped by the lower roller


84


, second roller


85


, tension roller


861


and conveying belt


86


, and conveyed, and placed on the fixed sheet delivery table


92


outside the apparatus.




Control Means of the Finisher





FIG. 14

is a block diagram showing the control of the image forming apparatus main body A and finisher FS.




A communication means


101


of a main control means


100


of the image forming apparatus main body A and a communication means


201


of a finishing control means


200


of the finisher Fs are electrically connected, and the sending and receiving of the control signal is mutually conducted.




By the selection means of the operation section


9


, the sheet feeding by the first sheet feed means


20


A and the second sheet feed means


20


B of the finisher FS, punch processing by the punching means


40


, shift processing by the shift means


50


, each processing of the end stapling and center-stapling by the staple processing section


70


, and each of the center-fold processing and three-folding, are set.




By this setting, the main control means


100


sends the control signal to the finisher FS through the communication means


101


. The control signal is transmitted to the finishing control means


200


through the communication means


201


. The finishing control means


200


drives the set each means.




The sheet conveying control in the fold processing section


80


will be described below.




Fold Processing of a Small Number of Sheets





FIG. 15

is an enlarged sectional view showing the fold processing of a small number of sheets by the folding plate


82


, upper roller


83


, and lower roller


84


.




When any one of the center-fold processing, three-fold processing, or Z-fold processing is conducted on the sheets S of a small number of sheets (1-3 sheets) on which center-staple processing is not conducted, initially, the drive of the motor Ml of the first drive means


801


shown in

FIG. 7

is stopped, and the rotation of the upper roller


83


and lower roller


84


is maintained to the stop condition. In this condition, the drive of the motor M


2


of the second drive means


802


shown in FIG.


8


and

FIG. 9

is started, and the folding plate


82


is advanced from the stand-by position to the hollow arrowed direction shown in the drawing.




The leading edge portion of the folding plate


82


projects the fold “a” of the small number of sheets (sheets S


1


, S


2


in the drawing), and while making the sheet surface sliding contact with the outer peripheral surface of the upper roller


83


and lower roller


84


, pushes it into the vicinity of the nip position N, and simultaneously folds the sheets S


1


and S


2


and forms the fold “c”.




When the leading edge portion of the folding plate


82


projects the fold portion “c” of the sheets S


1


and S


2


, and making it sliding contact with the outer peripheral surface of the upper roller


83


and lower roller


84


and sends it to the vicinity of the nip position N, by one way rotation clutches CA and CB provided on each of axis ends of the upper roller


83


and lower roller


84


, the upper roller


83


and lower roller


84


sliding contact with the moving sheets S


1


and S


2


, and are driven only in the sheet conveying direction (refer to FIG.


6


).




When an initial position sensor (not shown) of the second drive means


802


and a timer clocking (or step clocking) detect that the leading edge portion of the folding plate


82


reaches a predetermined distance L on this side of the nip position N, the drive of the motor M


2


is stopped, and the folding plate


82


is temporarily stopped at a predetermined position. The predetermined distance L between the folding plate


82


leading edge portion and nip position N at the time of temporary stop of the folding plate


82


, is 1-2 mm.




When it is detected that the leading edge portion of the folding plate


82


reaches the predetermined distance L on this side of the nip position N, the finishing control means


200


starts the drive of the motor M


1


. By the drive start of the motor M


1


, the rotation of the upper roller


83


and lower roller


84


is started.




At almost the same time, by the reversal drive of the motor M


2


, the folding plate


82


starts the withdrawal, and the leading edge portion of the folding plate


82


is pulled from the fold portion “c” of the sheets S


1


and S


2


, and the fold portion “c” of the sheets S


1


and S


2


is nipped and held on the outer peripheral surface of the upper roller


83


and lower roller


84


, and the fold portion “c” is strongly formed.




In this connection, the withdrawal start of the folding plate


82


may be conducted at the time of drive start of the motor M


1


, or after the path of a predetermined time period. When the leading edge portion of the folding plate


82


is pulled from the fold portion “c” of the sheets S


1


and S


2


, because the upper roller


83


and lower roller


84


are prevented from reversing the rotation by the one way rotation clutches CA and CB, the sheets S


1


and S


2


are not withdrawn.




As described above, in the case where the number of sheets to be fold processed is small (1-5 sheets), when the sheets S are pushed into the vicinity of the nip position N between the upper roller


83


and lower roller


84


whose rotation is stopped, by the folding plate


82


, and the fold portion “c” is formed on the sheet S, the slippage between the sheets is dissolved.




Further, because the leading edge portion of the folding plate


82


is not pushed into the position beyond the nip position N between the rotating upper roller


83


and lower roller


84


, when the folding plate


82


is inserted into the nip position N, the drive torque of the second drive means


802


can be reduced.




When the center-fold processing is conducted on the volume of the small number (2-5 sheets) of sheets S on which the center-staple processing is conducted, the slippage between the sheets at the time of folding processing of the sheet bundle on which the center-staple processing is conducted, is smaller than the sheet bundle on which the center-staple processing is not conducted. However, because the sheet slippage other than the stapling section is generated, the above fold processing control is applied on the small number (2-5 sheets) of sheets S.




Fold Processing of a Large Number of Sheets




When the center-fold processing is conducted on the bundle of many number (6-20) of sheets S on which the center-staple processing is conducted, it is difficult that the thick sheet bundle is pushed into the vicinity of the nip position N between the upper roller


83


and lower roller


84


whose rotation is stopped, as the above folding control of the small number of sheets. On the volume of many number of sheets S which is center-staple processed, the folding plate


82


is advanced, pushed, and it is pushed into the vicinity of the nip position N between the rotating upper roller


83


and lower roller


84


, and the fold portion “c” is formed and the booklet is made.




Each mode switching of the fold processing of the small number of sheets S, or the fold processing of the many number of sheets S is conducted by the number of sheets signal of the image forming apparatus main body A and the sheet path detection means of the finisher FS.




Control of the Fold Processing





FIG. 16

is a typical view showing the arrangement of the motor and sensor in the staple processing section


70


, and fold processing section


80


. FIGS.


17


(


a


)-


17


(


f


) are timing charts showing the control of the fold processing.




When, on the sheet placement table


71


shown in

FIG. 2

, the final sheet S reaches and is brought into contact with the second contact member


78


, the motor M


3


is driven and the width alignment member


73


pressed the side edge in the width direction of the sheet bundle and the width is aligned (final alignment (FIG.


17


(


a


)). When the final alignment is completed, the drive of the motor M


4


is stopped, and the rotation of the inlet conveying roller pair


15


and the winding-in belt


16


is stopped (FIG.


17


(


b


)).




After the drive stop of the motor M


4


, the drive of the motor MS is started, the second contact member


78


is moved from the stop position at the time of the center-staple processing to the stop position at the time of the center-fold processing (FIG.


17


(


c


)).




By an AND condition (FIG.


17


(


i


)) of the drive stop signal of the motor MS and a signal detecting the path of the sheet S of the sheet path detection sensor PS


1


arranged on the sheet placement table


71


, the drive start of the motor Ml and the motor M


2


is controlled.




When the center-fold processing is conducted on 6-20 sheets S which are center-staple processed, the drive of the motor M


1


is started after the path of the predetermined time T


1


by the timer clocking from the drive stop time of the motor MS, and the upper roller


83


and lower roller


84


are low speed rotated (FIG.


17


(


d


)).




When the center-fold processing is conducted on 2-5 small number of sheets S which are center-staple processed, or the center-fold processing is conducted on 1-3 small number of sheets S which are not staple processed, the drive of the M


1


is started from the detection signal generation of the sensor PS


3


to detect the initial position of the folding plate


82


, and the upper roller


83


and lower roller


84


are low speed rotated (FIG.


17


(


e


)).




Under the AND condition, after the predetermined time T


2


path by the timer clocking from the drive stop signal of the motor M


5


, the drive of the motor M


2


is started (FIG.


17


(


g


)), and the folding plate


82


is advanced to the vicinity of the nip position N. After the folding plate


82


is advanced by the normal drive of the motor M


2


and cam mechanism, it is retreated and returns to the initial position (FIG.


17


(


g


)).




When the center-fold processing is conducted on 6-20 sheets S which are center-staple processed, the folding plate


82


is made advance to the nip position N between the upper roller


83


and lower roller


84


which are rotating at the low speed, and is inserted into the position.




When the center-fold processing is conducted on 2-5 small number of sheets S which are center-staple processed, or the center-fold processing is conducted on 1-3 small number of sheets S which are not stapled, the folding plate


82


is made advance to the nip position N between the upper roller


83


and lower roller


84


which are in the stopped condition, and is inserted into the position.




When the initial position returning of the folding plate


82


is detected by the sensor PS


3


(FIG.


17


(


h


)), the drive of the motor M


2


is stopped. At almost the same time, the motor M


1


is switched from the low speed rotation (for example, 500 rpm) to the high speed rotation (for example, 2500 rpm) (FIGS.


17


(


d


) and


17


(


e


)), and the upper roller


83


and lower roller


84


are rotated at the high speed, and the sheet bundle on which the fold processing is completed, is delivered at the high speed.




After the predetermined time T


3


by the timer clocking is passed from the time when the sensor PS


2


arranged on the delivery side of the fold processing section


80


detects the trailing edge path of the sheet bundle on which fold processing is conducted (FIG.


17


(


f


)), the drive of the motor M


1


is stopped (FIG.


17


(


c


)).




In this connection, in the embodiment of the present invention, the finisher connected to the copier main body is described, however, the present invention can also be applied to the finisher connected to the image forming apparatus main body such as the printer, facsimile device, or hybrid machine.




As clearly be seen from the above description, by the sheet finishing method, finisher and image forming apparatus of the present invention, the following effects can be attained.




(1) the small number of sheets are pushed in the nip position between the upper roller and lower roller by the folding plate, and when a fold portion is formed, the slippage between the sheets can be solved.




(2) when the folding plate is inserted into the nip position between the upper roller and lower roller and the small number of sheets are fold processed, the drive torque of the drive means can be reduced.




(3) In the finisher connected to the image forming apparatus main body such as the copier or printer, the desired digital processing is conducted by the image forming apparatus main body, and even the sheets which is high speed delivered generate a bend, after the fixing processing, by the finisher of the present invention, the sheet conveying is correctly conducted at high speed, the high productivity is maintained, and the finishing such as the fold processing is conducted at high speed.



Claims
  • 1. A sheet finishing method comprising the steps of:(a) stacking sheets delivered and conveyed from an image forming apparatus main body onto a sheet placement table; (b) positioning and aligning the stacked sheets; (c) folding the aligned sheets by a folding device composed of paired folding rollers and a folding plate; and (d) switching a rotation motion of the paired folding rollers between a first state wherein the paired folding rollers are rotated and the folding plate is advancing and a second state wherein the paired folding rollers are stopped and the folding plate is advancing, the switching between the first state and the second state, in accordance with the number of sheets stacked on the sheet placement table.
  • 2. A sheet finisher comprising:(a) a sheet placement table on which sheets delivered and conveyed from an image forming apparatus main body, are stacked; (b) a folding device for folding the stacked sheets which have been positioned and aligned, a folding device comprising paired folding rollers and a folding plate; (c) a detector for detecting the number of sheets stacked; (d) a first driving device for rotating the paired folding rollers; (e) a second driving device for making the folding plate to advance or retreat; and (f) a controller for controlling the first driving device and the second driving device, wherein the controller controls the first driving device and the second driving device such that a rotation motion of the paired folding rollers is switched between a first state wherein the paired folding rollers are rotated and the folding plate is advancing and a second state wherein the paired folding rollers are stopped and the folding plate is advancing, the switching between the first state and the second state, in accordance with the number of sheets stacked on the sheet placement table.
  • 3. The sheet finisher of claim 2, wherein when the number of sheets that have not been stapled is 1 to 3 or the number of sheets that have been stapled is 2 to 5, the controller controls the first driving device and the second driving device such that the paired folding rollers are switched to the second state, and the folding plate is made to advance and a leading end thereof is inserted into an interposing position of the paired rollers, while when the number is sheets that have been stapled is 6 or more, the controller controls the first driving device such that the paired folding rollers are switched to the first state, and the leading end of the folding plate is inserted into the interposing position of the paired rollers which are being rotated.
  • 4. An image forming apparatus comprising:an image forming apparatus main body composed of an image writing station, and sheet conveying station; and a sheet finisher comprising: (a) a sheet placement table on which sheets delivered and conveyed from an image forming apparatus main body, are stacked; (b) a folding device for folding the stacked sheets which have been positioned and aligned, a folding device comprising paired folding rollers and a folding plate; (c) a detector for detecting the number of sheets stacked; (d) a first driving device for rotating the paired folding rollers; (e) a second driving device for making the folding plate to advance or retreat; and (f) a controller for controlling the first driving device and the second driving device, wherein the controller controls the first driving device and the second driving device such that a rotation motion of the paired folding rollers is switched between a first state wherein the paired folding rollers are rotated and the folding plate is advancing and a second state wherein the paired folding rollers are stopped and the folding plate is advancing, the switching between the first state and the second state, in accordance with the number of sheets stacked on the sheet placement table.
Priority Claims (1)
Number Date Country Kind
2001-250246 Aug 2001 JP
US Referenced Citations (6)
Number Name Date Kind
5169376 Ries et al. Dec 1992 A
5738620 Ebner et al. Apr 1998 A
5993369 Sekita et al. Nov 1999 A
6004254 Murata Dec 1999 A
6022011 Hirose Feb 2000 A
6276677 Hommochi et al. Aug 2001 B1