Sheet treating apparatus and image forming apparatus having the same

Information

  • Patent Grant
  • 6505829
  • Patent Number
    6,505,829
  • Date Filed
    Tuesday, November 23, 1999
    25 years ago
  • Date Issued
    Tuesday, January 14, 2003
    21 years ago
Abstract
A sheet treating apparatus for avoiding electrostatic charge accumulation discharges the sheet P, bearing an image thereon, onto discharge sheet stacking trays provided on the side part of the main body, and receives the trailing end of the sheet by the side part of the main body, and is provided with a grounding member for grounding the sheet by contact with the trailing end of the sheet.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to a sheet treating apparatus for discharging a sheet, and an image forming apparatus provided with such sheet treating apparatus.




2. Related Background Art




There is conventionally known a sheet treating apparatus capable of discharging sheets, on which images are formed in an image forming apparatus, in the shape of a bundle.




Such sheet treating apparatus discharges sheets, bearing images thereon, onto discharge sheet stacking means provided on a lateral part of the main body, wherein the trailing ends of the sheets are received by the lateral part of the main body.




The image forming apparatus can be a copying machine, a facsimile apparatus, a printer or a composite apparatus thereof.




Also the sheet can be a plain paper, a thin resinous sheet used as a substitute for the plain paper, a postcard, a cardboard, an envelope or a thin plastic plate.




However, such sheet discharged by the sheet treating apparatus may be electrostatically charged when the sheet is subjected to the image formation in the image forming apparatus or conveyed in the sheet treating apparatus.




The sheet tends to bear electrostatic charge particularly when the sheet treating apparatus is used in a dry environment.




In the sheet discharging operation under such condition, the electrostatic charge may become resistive against the sheet discharge, eventually leading to defective sheet discharge.




Also the electrostatic charge on the sheets causes the sheet to stick mutually, whereby the separation of the sheet becomes difficult.




SUMMARY OF THE INVENTION




The object of the present invention is to provide a sheet treating apparatus capable of preventing electrostatic charging of the sheet, and an image forming apparatus provided with such sheet treating apparatus.




The sheet treating apparatus of the present invention is so constructed as to discharge sheets, bearing images thereon, onto discharge sheet stacking means provided on a lateral part of the main body and to receive the trailing ends of the sheets by the lateral part of the main body, and the lateral part is provided with a grounding member for contacting the trailing end of the sheet thereby grounding the sheet.




The trailing ends of the sheets, discharged onto the discharge sheet stacking means, are received on the lateral part of the main body of the apparatus, and, in such state, the trailing ends of the sheets are received by the grounding member.




Therefore, the electrostatic charge eventually present on the sheets is dissipated through the grounding member, whereby the sheets can be made free of the electrostatic charge.




The above-mentioned sheets are discharged in a shape of a bundle onto the discharge sheet stacking means.




The electrostatic charge is more easily accumulated in the sheets when the sheets are in the shape of the bundle, but such electrostatic charge can be dissipated by the grounding member.




The grounding member may be provided with an elastic finger capable of engaging with and disengaging from an engaging hole provided in the main body of the apparatus.




The grounding member may be formed separately from the main body and be mounted on the main body.




The grounding member may be made of a metal.




The grounding member may be provided with a grounded metal plate in a portion adapted to receive the trailing ends of the sheets.




The grounding member may also be composed of molded plastics in which metal powder is mixed.




The grounding member may also be composed of molded plastics plated with a metal.




The image forming apparatus of the present invention may be provided with image forming means for forming an image on a sheet, and any sheet treating apparatus mentioned above.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a schematic front cross-sectional view showing an entire configuration of a sheet treating apparatus of the present invention;





FIG. 2

is a side view of a stapler and a treating tray unit;





FIG. 3

is a plan view of a stapler moving mechanism looking in a direction indicated by arrow III in

FIG. 2

;





FIG. 4

is a rear view of the stapler looking in a direction indicated by arrow IV in

FIG. 2

;





FIG. 5

is a vertical cross-sectional side view of a pivotally movable guide and a treating tray;





FIG. 6

is a plan view showing an arrangement of a trailing end dropping member and a knurled belt;





FIG. 7

is a view illustrating an operation when the trailing end dropping member is positioned inside an arrangement of the knurled belt;





FIG. 8

is a view illustrating an operation when the trailing end dropping member is positioned outside an arrangement of the knurled belt;





FIGS. 9 and 10

are views illustrating an operation of the trailing end dropping member in

FIG. 5

;





FIG. 11

is a plan view of a treating tray and an alignment member moving mechanism;





FIG. 12

is a bottom view of the treating tray and the alignment member moving mechanism;





FIG. 13

is a rear view of a retractable tray;





FIG. 14

is a horizontal cross-sectional view of a stacking tray moving mechanism;





FIG. 15

is a view showing an arrangement of sensors around the stacking tray;





FIGS. 16 and 17

are side views of.a punch unit;





FIG. 18

is a plan view of the punch unit;





FIGS. 19 and 20

are views showing a lateral registration sensor moving mechanism of the punch unit;





FIG. 21

is a view illustrating an operation of the sheet treating apparatus in a non-sort mode;





FIGS. 22

to


28


are views illustrating an operation of the sheet treating apparatus in a staple sort mode;





FIG. 29A

is a view illustrating an operation of the sheet treating apparatus when the pivotally movable guide is elevated in the staple sort mode;





FIG. 29B

is a view illustrating an operation of the sheet treating apparatus when the pivotally movable guide is lowered in the staple sort mode;





FIGS. 30 and 31

are views illustrating an operation of the sheet treating apparatus in a sort mode;





FIG. 32

is a view showing stacked sheet bundles;





FIG. 33

is a plan view showing a sheet bundle aligning operation of the treating tray;





FIG. 34

is a side view showing the sheet bundle aligning operation of the treating tray;





FIGS. 35 and 36

are plan views showing the sheet bundle aligning operation of the treating tray;





FIGS. 37 and 38

are views showing stacked sheet bundles;





FIGS. 39

,


40


and


41


are views showing sheet bundle stapling operation of the treating tray;





FIG. 42

is a flowchart of a punch mode; and





FIG. 43

is an elevation view of an image forming apparatus in which the sheet treating apparatus of the present invention is applicable.











DESCRIPTION OF THE PREFERRED EMBODIMENTS





FIG. 43

shows an example of an image forming apparatus (copying machine)


310


in which a sheet treating apparatus


1


of the present invention is provided in a main body


300


of the image forming apparatus (main body of the copying machine).




The main body


300


of the image forming apparatus (copying machine) is provided with a platen glass


906


serving as an original stocking plate; a light source


907


; a lens system


908


; a sheet feeding portion


909


; an image forming portion (image forming means)


902


; an auto original feeder (recycling document feeder (RDF))


500


for feeding the original to the platen glass


906


; and a sheet treating apparatus


1


of the embodiment of the present invention, for stacking the sheet, discharged from the main body


300


and bearing images thereon.




The sheet treating apparatus


1


of the embodiment of the present invention may be incorporated not only in the main body of the copying machine but also in that of a facsimile apparatus, a printer or a composite apparatus thereof. Consequently, the image forming apparatus used herein includes not only the main body of the copying machine but also the facsimile apparatus, the printer and the composite apparatus thereof.




Also the sheet includes plain paper, thin resinous sheet used as a substitute for the plain paper, postcard, cardboard, envelope, thin plastic sheet etc.




The sheet feeding portion


909


is provided with cassettes


910


,


911


containing recording sheets P and detachably mounted on the main body


300


of the apparatus, and a deck


913


provided on a pedestal


912


. The image forming portion


902


is provided with a cylindrical photosensitive drum


914


, and a developing device


915


, a transfer charger


916


, a separation charger


917


, a cleaner


918


and a primary charger


919


provided around the photosensitive drum


914


. At the downstream side of the image forming portion


902


, there are provided a conveying device


920


, a fixing device


904


and a pair of discharge rollers


905


.




The details of the auto original feeder (RDF)


500


will be omitted.




In the following there will be explained the operation of the main body


300


of the image forming apparatus.




In response to a sheet feed signal supplied from a controlling device


930


of the main body


300


, a sheet P is fed from the cassette


910


,


911


or the deck


913


. On the other hand, the original D placed on the original stocking plate


906


is illuminated by the light from the light source


907


, and the reflected light irradiates the photosensitive drum


914


through the lens system


908


. The photosensitive drum


914


is in advance charged by the primary charger


919


and forms an electrostatic latent image thereon by the exposure to light, and the electrostatic latent image is developed by the developing device


915


to form a toner image.




The sheet P fed from the sheet feeding portion


909


is subjected to correction of skew feed by the registration rollers


901


, and is fed to the image forming portion


902


in a registered timing. In the image forming portion


902


, the toner image on the photosensitive drum


914


is transferred onto the fed sheet P by the transfer charger


916


, and the sheet P bearing the transferred toner image is charged by the separation charger


917


in a polarity opposite to that of the transfer charger


916


and is thus separated from the photosensitive drum


914


.




Thus separated sheet P is conveyed by the conveying device


920


to the fixing device


904


, in which the transferred image is permanently fixed to the sheet P. The sheet P bearing the fixed image is discharged by the pair of discharge rollers


905


from the main body


300


of the apparatus.




In this manner, the sheet P fed from the sheet feeding portion


909


is subjected to image formation and is discharged to the sheet treating apparatus


1


of the present invention.




In the following there will be explained the sheet treating apparatus of the embodiment of the present invention.




Referring to

FIG. 1

, the finisher (sheet treating apparatus)


1


is equipped in the main body


300


of the image forming apparatus.




In

FIG. 1

, there are shown paired discharge rollers


905


of the main body


300


of the image forming apparatus; paired entrance rollers


2


of the finisher


1


; paired conveying rollers


3


; a sheet sensor


31


; a punch unit


50


for punching holes in the vicinity of the trailing end of the conveyed sheet; a large conveying roller


5


; and depressing rollers


12


,


13


,


14


adapted to be depressed for conveying the sheet.




A change-over flapper


11


executes switching between a non-sort path


21


and a sort path


22


. A change-over flapper


10


executes switching between the sort path


22


and a buffer path


23


for temporarily storing the sheets. There are also provided conveying rollers


6


. Temporary stacking, alignment and stapling of the sheets can be executed on an intermediate tray (hereinafter referred to as “treating tray”)


130


.




Discharge rollers


7


serve to discharge the sheet onto the treating tray


130


. A bundle discharge roller


180




b


is supported by the pivotally movable guide


150


, and, when it moves to a closed position, the bundle discharge roller


180




b


cooperates with a roller


180




a


provided on the treating tray


130


to discharge the bundle of sheets on the treating tray


130


onto a stacking tray


200


.




In the following there will be explained the stapling unit


100


with reference to

FIGS. 2

,


3


and


4


.





FIG. 2

is an elevation cross-sectional view of the stapling unit


100


,

FIG. 3

is a view looking in a direction indicated by arrow III in

FIG. 2

, and

FIG. 4

is a view looking in a direction indicated by arrow IV in FIG.


2


.




A stapler


101


is fixed to a movable table


103


through a holder


102


. Shafts


104


,


105


(

FIG. 4

) fixed to the movable table


103


respectively rotatably support rollers


106


,


107


which fit into aperture-shaped rails


108




a


,


108




b


,


108




c


(

FIG. 3

) formed in a fixed table


108


.




The rollers


106


,


107


are respectively provided with flanges


106




a


,


107




a


larger than the aperture-shaped rails


108




a


,


108




b


,


108




c


of the fixed table


108


. Under the movable table


103


, supporting rollers are provided in three positions. The movable table


103


, supporting the stapler


101


, can move on the fixed table


108


along the rails


108




a


,


108




b


,


108




c


without coming away from the fixed table


108


. The movable table


103


can move, by rollers


109


rotatably provided thereon, on the fixed table


108


.




The aperture-shaped rails


108




a


,


108




b


,


108




c


mentioned above branch in the front and rear parts to constitute two parallel rails. When the stapler


101


is positioned in front, based on the shape of these rails, the roller


106


fits in the rail portion


108




b


while the roller


107


fits in the rail portion


108




a


whereby the stapler


101


is inclined, corresponding to a corner of the sheet. When the stapler


101


is positioned at the central position, both rollers


106


,


107


engage with the rail portion


108




a


whereby the stapler


101


is positioned parallel to the edge of the sheet.




When the stapler


101


is positioned at rear, the roller


106


fits in the rail portion


108




a


while the roller


107


fits in the rail portion


108




c


whereby the stapler


101


is inclined in a direction opposite to that when the stapler


101


is positioned in front, thereby being positioned corresponding to another corner of the sheet.




After the two rollers


106


,


107


respectively fit into the parallel two rails, the stapler moves while maintaining its attitude, and the change in the direction is started by an unrepresented cam.




In the following there will be explained a moving mechanism for the stapler


101


.




A pinion


106




b


of the roller


106


of the aforementioned movable table


103


is integrally constructed with a belt pulley


106




c


. The pinion


106




b


is connected, by a belt


123


supported by the pulley


106




c


, to a motor M


100


which is fixed to the movable table


103


from above. On the other hand, on the lower surface of the fixed table


108


, there is fixed a rack


110


along the aperture-shaped rail so as to mesh with the pinion


106




b


, whereby the movable table


103


moves forward and backward together with the stapler


101


, by the forward and reverse rotation of the motor M


100


.




A shaft


111


, extending downwards from the movable table


103


, supports a stopper turn-down roller


112


, which, as will be explained in more details, serves to rotate a trailing end stopper


131


of the treating tray


130


in order to prevent the stapler


101


from colliding against the trailing end stopper


131


.




The stapler unit


100


is provided with a sensor for detecting a home position of the stapler


101


, and the stapler


101


normally waits in the home position (frontmost position in the present embodiment).




In the following there will be explained, with reference to

FIGS. 2 and 3

, the trailing end stopper


131


for receiving the trailing end of the sheets P stacked on the treating tray


130


.




The trailing end stopper


131


has a surface perpendicular to the stacking surface of the treating tray


130


, and is provided with a supporting surface


131




a


for receiving the trailing end of the sheet, a pin


131




b


fitted in a circular hole provided in the treating tray


130


and constituting a center of pivotal movement of the trailing end stopper


131


, and a pin


131




c


connected to a link mechanism


137


to be explained later. The link mechanism


137


is constituted by a main link member


132


having a cam surface


132




a


to be brought into contact with and pressed by the roller


112


mounted on the movable table


103


of the stapler, and a connecting link member


133


connecting a pin


132




b


provided on the upper end of the main link member


132


and the pin


131




c


of the trailing end stopper


131


.




The main link member


132


is adapted to execute pivotal movement about a shaft


134


fixed on an unrepresented frame. The main link member


132


is provided, at the lower end thereof, with a extension spring


135


for clockwise biasing the main link member


132


, and is positioned by an abutting plate


136


. Therefore, the trailing end stopper


131


normally maintains its attitude perpendicular to the treating tray.




When the movable table


103


of the stapler moves, the turn-down roller


112


provided thereon presses down the cam surface


132




a


of the main link member


132


, connected to the trailing end stopper


131


which is in interference with the stapler


101


, whereby the trailing end stopper


131


is pulled by the connecting link member


133


and is rotated to a position not in interference with the stapler


101


. A plurality of the turn-down rollers


112


are provided (three in the present embodiment shown in FIG.


3


), in order that the trailing end stopper


131


maintains the retracted position during the movement of the stapler


101


.




On both sides of the holder


102


supporting the stapler


101


, there are provided staple stoppers


113


(represented by an alternate long and two short dashes line in

FIG. 2

) having a supporting surface in the same shape as the trailing end stopper


131


. The staple stoppers


113


serve to receive the trailing end of the sheets, instead of the trailing end stopper


131


, when the trailing end stopper


131


is pressed down by the stapler


101


positioned at the central position in FIG.


3


and becomes incapable of receiving the trailing end of the sheets.




In the following there will be explained a treating tray unit


129


with reference to

FIGS. 5

to


10


.




The treating tray unit


129


is positioned between the conveying portion for conveying the sheet from the main body


300


of the image forming apparatus and the stack tray


200


for receiving and supporting the bundle of sheets handled on the treating tray


130


.




In the sort path


22


in the vicinity of the paired discharge rollers


7


,


7


of the conveying portion, a sensor


183


is provided for detecting the sheet moving in the sort path


22


. The sensor


183


is connected to a controlling circuit


301


of the sheet treating apparatus


1


. The controlling circuit


301


is connected to the controlling device


930


in the main body of the copying machine, in order to control not only the operation of the sheet treating apparatus but also the smooth cooperative operation with the main body of the copying machine.




Also based on the sheet detection signal generated by the sensor


183


each time the sensor


183


detects the sheet, the controlling circuit


301


counts the number of sheets and controls motors M


141


, M


142


for rotating pinions


143


,


144


to be explained later according to the counted number of sheets, thereby moving a front-side aligning mechanism


141


and an aligning member


142


.




In the vicinity of the downstream end of the sort path


22


where the paired discharge rollers


7


,


7


of the conveying portion are provided, there are provided a trailing end dropping member


181


and a knurled belt


182


.




As shown in

FIG. 6

, four trailing end dropping member


181


and four knurled belt


182


are provided along a direction crossing the sheet conveying direction. In this case, the trailing end dropping member


181


at each end is positioned outside the knurled belt


182


.




The trailing end dropping member


181


is pivotally movable in the vertical direction about a shaft


181




a


constituting the center of the pivotal movement. It normally waits in the solid-lined position by being received by the stopper


181




b


, and, when a sheet is discharged by the paired discharge rollers


7


,


7


, it is elevated to a broken-lined position by a plunger PL


181


so as not to hinder the discharge of the sheet from the paired rollers


7


,


7


.




The knurled belt


182


is composed of an annular elastic member (made of rubber or plastics) having knurls on the external periphery thereof, and is pinched between unrepresented rotary shafts of the paired discharge rollers


7


,


7


thereby being rotated in a direction indicated by an arrow.




The lowermost end


181




c


of the trailing end dropping member


181


is positioned lower than the center


182




a


of the knurled belt


182


when the knurled belt


182


is in a truly circular state and within the area of the knurled belt


182


. Therefore, a sheet guiding surface


181




d


of the trailing end dropping member


181


is positioned close to the tangential line to the knurled belt


182


and a distal end


181




e


of the trailing end dropping member


181


protrudes from the external periphery of the knurled belt


182


.




The treating tray unit


129


is composed of a treating tray


130


, a trailing end stopper


131


, an aligning device


140


, a pivotally movable guide


150


, a pull-in paddle


160


, a retractable tray


170


, and paired bundle discharge rollers


180




a


,


180




b


as discharge means, and so on.




The treating tray


130


is so inclined that the downstream side (left side in the drawing) is higher and the upstream side (right side in the drawing) is lower, and the aforementioned trailing end stopper


131


is fitted on the lower end.




A lower bundle discharge roller


180




a


is provided at the upper end of the treating tray


130


, while an upper bundle discharge roller


180




b


engageable with the roller


180




a


is provided on the pivotally movable guide


150


to be explained later, and these rollers


180




a


,


180




b


are rotated in the forward and reverse direction by a motor M


180


.




In the following there will be explained an operation of the trailing end dropping member


181


, and an operation of the treating tray unit


129


will be explained later.




Referring to

FIGS. 5 and 9

, a sheet P is ejected by the paired discharge rollers


7


,


7


of the conveying portion onto the treating tray


130


while the trailing end dropping member


181


is elevated to the broken-lined position. After the discharge of the sheet P, the trailing end dropping member


181


is lowered (

FIGS. 5

,


10


). The discharged sheet P slides on the treating tray


130


by its weight and by the function of the paddle


160


to be explained later until the trailing end of the sheet P abuts against the trailing end stopper


131


.




In this operation, even if the trailing end of the sheet P is bent (curled) upwards and floats from the treating tray


130


, it is guided to the trailing end stopper


131


by the guiding function of the inclined sheet guiding surface


181




d


of the trailing end dropping member


181


in the lowered state and the rotary guiding function of the knurled belt


182


. Also in case the sheet curling is large, the trailing end dropping member


181


in the course of descent to the solid-lined position presses the trailing end of the sheet from above, thereby correcting the curling.




It is therefore possible to prevent a phenomenon that the trailing end of the sheet comes into contact with the trailing end dropping member


181


and is curled more in the sliding motion of the sheet, thereby eventually folded back and is jammed between the trailing end dropping member


181


and the treating tray


130


, and to securely stack the sheets on the treating tray


130


.




Also, since the trailing end dropping members


181


on both sides are positioned outside the knurled belts


182


, even if the end portions of the sheet, positioned outside such trailing end dropping members


181


, are curled, such curled portions can be securely guided as shown in FIG.


8


. Such curled portions of the sheet may not be securely guided if the trailing end dropping members


181


are not positioned outside the knurled belts


182


as shown in FIG.


7


.




In the following there will be explained the upper and lower sides of the aligning device


140


with reference to

FIGS. 11 and 12

.




The front-side aligning mechanism


141


and the rear-side aligning member


142


, constituting the aligning device


140


, are rendered independently movable forward and backward.




The front-side aligning mechanism


141


is provided with a movable plate


145


, a front-side aligning member


146


; guide shafts


147


,


147


protruded from the front-side aligning member


146


and penetrating through the movable plate


145


; compression coil springs


148


,


148


loosely fitted on the guide shafts


147


between the movable plate


145


and the front-side aligning member


146


and biasing the front-side aligning member


146


in a direction apart from the movable plate


145


; stoppers


149


provided on the guide shafts


147


in order to avoid escaping of the guide shafts


147


from the movable plate


145


; a rack


141




b


provided on the movable plate


145


and extending in a direction from the front-side to the rear-side; and three rollers


141




d


provided on the movable plate


145


and the rack


141




b


and movable in a guide hole


130




a


formed in the treating tray


130


. The edges of the guide hole


130




a


are recessed so that the rollers


141




d


are not in contact with the lower surface of the sheet.




The front-side aligning member


146


of the front-side aligning mechanism


141


and the rear-side aligning member


142


are respectively provided with aligning surfaces


146




a


,


142




a


upstanding on the treating tray


130


and pressing the side edges of the sheets, and supporting surfaces


146




c


,


142




c


perpendicularly connected to the aligning surfaces


146




a


,


142




a


and supporting the lower surface of the sheets P.




The rear-side aligning member


142


is provided with a rack


142




b


extending in a direction from the front-side to the rear-side. The rear-side aligning member


142


and the rack


142




b


are provided with three rollers


142




d


movable in a guide hole


130




b


formed in the treating tray


130


. The edges of the guide hole


130




b


are recessed so that the rollers


142




d


are not in contact with the lower surface of the sheet.




The front-side aligning member


141


and the aligning member


142


are respectively supported by an open guide


140


extending in a direction from the front-side to the rear-side of the treating tray


130


and are so assembled that the aligning surfaces


146




a


,


142




a


are positioned on the upper surface of the treating tray


130


while the racks


141




b


,


142




b


are positioned on the lower surface of the treating tray


130


.




The racks


141




b


,


142




b


respectively engage with pinions


143


,


144


which are respectively connected to motors M


141


, M


142


through pulleys and belts. The front-side aligning mechanism


141


and the aligning member


142


are moved forward and backward by the forward and reverse rotation of the motors.




The front-side aligning mechanism


141


and the aligning member


142


are provided with sensors (not shown) for detecting the home positions, and normally wait in the home positions.




The aligning member


142


at the rear-side may be formed into the same structure as the front-side aligning mechanism.




It is also possible to form the front-side aligning mechanism into the same structure as the rear-side aligning member and to form the rear-side aligning member into the same structure as the front-side aligning mechanism.




Stated differently, at least one of the members for laterally aligning the sheets has to be formed into the same structure as the front-side aligning mechanism


141


.




In the present embodiment, the front-side aligning mechanism


141


has its home position at the forehand position and the rear-side aligning member


142


has its home position at the backmost position.




In the following there will be explained the pivotally movable guide


150


(

FIG. 5

) of the treating tray unit


129


.




The pivotally movable guide


150


is provided at the upstream side (right side in the drawing) with a pivot shaft


151


, and, at the downstream side (left side) with the upper bundle discharge roller


180




b


. The pivotally movable guide


150


is in an open state (the bundle discharge rollers


180




a


,


180




b


are not in contact with each other) when the sheets P are discharged one by one onto the treating tray


130


, thereby not hindering the sheet discharge and dropping onto the treating tray


130


or the aligning operation, but assumes a closed state (the bundle discharge rollers in mutual contact) when the sheet bundle is discharged from the treating tray


130


onto the stack tray


200


.




A rotary cam


152


(

FIG. 5

) is provided in a position corresponding to the lateral side of the pivotally movable guide


150


. The pivotally movable guide


150


assumes the open state by pivotally moving about the shaft


151


when the rotary cam


152


is rotated and pushes up the lateral side of the guide


150


, and assumes the closed state when the rotary cam


152


rotates through 180° from this state and leaves from the lateral side of the guide


150


. The rotary cam


152


is rotated by a motor M


150


which is connected through an unrepresented driving system to the rotary cam


152


.




The closed state of the pivotally movable guide


150


is taken as its home position, and a sensor for detecting the home position is provided (not shown).




In the following there will be explained the pull-in paddle


160


(

FIG. 5

) of the treating tray unit


129


.




The pull-in paddle


160


is fixed to a shaft


161


, which is rotatably supported by lateral plates on both sides. The paddle shaft


161


is connected to a motor M


160


and is rotated counterclockwise when driven by the motor M


160


.




The length of the paddle


160


is selected somewhat longer than the distance to the treating tray


130


. The home position of the paddle


160


is selected at a position (solid-line position in the drawing) not coming into contact with the sheet P discharged by the discharge rollers


180




a


,


180




b


onto the treating tray


130


. When the sheet P is discharged in this state and falls on the treating tray


130


, the paddle is rotated counterclockwise by the motor M


160


, thereby pulling in the sheet P until the sheet P comes into contact with the trailing end stopper


131


. After the lapse of a predetermined time thereafter, the paddle


160


stops at the home position, thereby preparing for the next sheet discharge.




In the following there will be explained the retractable tray


170


with reference to

FIG. 13

, looking in a direction indicated by arrow XIII in FIG.


5


.




The retractable tray


170


is positioned under the lower bundle discharge roller


180




a


and can be extended and retracted in the sheet conveying direction (direction indicated by double-headed arrow X in FIGS.


5


and


13


), substantially along the inclination of the treating tray


130


. The retractable tray


170


, in the extended state, has the distal end overlapping the stack tray


200


(the alternate long and two short dashes line in FIG.


5


), and, in the retracted state, has the distal end retracted to the right-hand side from the bundle discharge rollers. The distal end position in the extended state is so selected as not to be exceeded by the center of gravity of the sheet P discharged onto the treating tray


130


.




The retractable tray


170


is supported by rails


172


fixed to a frame


171


, and is rendered movable in the sheet discharging direction. A rotary link member


173


rotates about a shaft


174


and engages with a groove formed on the lower surface of the retractable tray


170


. Therefore the retractable tray


170


is extended and retracted as explained above, through one revolution of the rotary link member


173


.




The rotary link member


173


is rotated by a motor M


170


through an unrepresented drive mechanism. The home position of the retractable tray


170


is selected at the retracted position (solid-lined position), and is detected by an unrepresented sensor.




In the following there will be explained a stack tray


200


and a sample tray


201


with reference to

FIGS. 14 and 15

.




These two trays


200


,


201


are selected according to the situation. The stack tray


200


in the lower position is selected in case of receiving the copied or printed sheet. The sample tray


201


in the upper position is selected in case of receiving a sample sheet, an interruption processed sheet, a sheet in case of overflow of the stack tray, a sheet by function sorting, or a sheet in job mixed loading.




These two trays


200


,


201


are respectively provided with motors


202


so as to be independently movable in the vertical direction, and are mounted on a rack


210


which serves also as a roller retainer mounted vertically on a frame


250


of the sheet treating apparatus


1


.




A regulating member


215


regulates the play of the trays in the front-side direction and the rear-side direction. A tray base plate


211


supports a stepping motor


202


, and a pulley force-fitted onto the motor shaft drives a pulley


203


through a timing belt


212


.




A shaft


213


, connected to the pulley


203


with parallel pins, transmits rotary driving force to a ratchet


205


similarly connected to the shaft


213


with parallel pins, thereby biasing an idler gear


204


by a spring


206


. The ratchet


205


is connected to the idler gear


204


thereby transmitting driving force thereto. The idler gear


204


is also connected to a gear


207


. Another gear


207


is provided on a shaft


208


in order to drive the rack


210


at both front and rear-sides, whereby the rack


210


can be moved through a gear


209


. On the tray, two rollers


214


on each side are housed in the roller retainer


210


, which also serves as a rack. The trays are mounted on a base plate


211


to constitute a tray unit.




On a lateral portion


219




a


, serving as a position regulating member, of a stacking wall


219


(FIG.


14


), a plurality of grounding members


216


,


216


extending through the two trays


200


,


201


in the vertical direction are mounted from the front-side to the rear-side. The grounding member


216


is mounted on the stacking wall


219


by inserting elastic fingers


216




a


,


216




a


in holes


217


formed in the stacking wall


219


. The elastic fingers


216




a


are protruded from plural positions of the grounding member


216


arranged in a longitudinal direction of the grounding member


216


.




The grounding member


216


is made of a metal plate, a plastic mold on the surface of which a metal plate is incorporated, a plastic mold in which metal powder is mixed or a plastic mold which is plated with a metal, and is provided for receiving the trailing end of the sheets stacked on the trays


200


,


201


(

FIG. 1

) for dissipating the electrostatic charge accumulated on the sheets and is connected to an unrepresented grounding wire connected to the exterior of the sheet treating apparatus


1


.




In order that the sheet can be discharged onto the trays


200


,


201


, the grounding members


216


are not provided in the vicinity of the rollers


9


,


180




a


as shown in

FIG. 1

, thereby not disturbing the sheet discharge.




The grounding members


216


serve to dissipate the electrostatic charge accumulated on the sheets, whereby, at the sheet discharge onto the trays, there is reduced the sliding resistance resulting from the mutual sticking of the sheets by the electrostatic charge, thereby resolving the defective sheet discharge. Also the sheets discharged onto the tray


200


or


201


do not mutually stick by the electrostatic charge and can be easily separated.




The electrostatic charge tends to accumulate on the sheets particularly when a large number of sheets are stacked on the tray


200


or


201


, and in such situation the grounding members


216


exhibit their function of dissipating the electrostatic charge.




As the grounding members


216


are mounted by the elastic fingers


216




a


on the stacking wall


219


, it is possible to separately prepare the stacking wall


219


generally by plastic molding and the grounding members


216


requiring high electric conductivity, thereby reducing the manufacturing cost.




Also in case the grounding member


216


is damaged, it can be easily detached from the stacking wall


219


and replaced by bending the elastic fingers


216




a.






Referring again to

FIG. 14

, the aforementioned ratchet


205


is rendered capable of idle rotation, against the force of the spring


206


, only in a direction to lift the tray, in order to prevent damage to the tray driving system by the presence of an obstacle at the descent of the tray. When such idle rotation is carried out, a sensor S


201


detects a slit, incorporated in the idler gear, thereby immediately stopping the motor. This sensor is used also for detecting a desynchronization. In order to make it possible that the tray passes vertically by an opening portion of the treating tray


130


(FIG.


5


), the pivotally movable guide


150


serves as a part of the stacking wall of the tray when the pivotally movable guide


150


is in the closed position. Only when a sensor (not shown) detects the closed position, the tray can be moved.




An area sensor S


202


(

FIG. 14

) detects the flag in an area from an upper limit sensor S


203




a


(

FIG. 15

) for preventing the excessive elevation of the tray to a treating tray sheet surface sensor S


205


. A sensor S


203




b


for detecting the 1000 sheet position on the sample tray is provided in a position corresponding to 1000 sheets from the non-sort sheet surface sensor S


204


, and serves to limit the stacking amount on the sample tray


201


by the height.




Also a sensor S


203




c


is provided to limit the stacking amount by the height when the sample tray


201


receives sheets from the treating tray


130


, and is provided at a position corresponding to 1000 sheets from the sheet surface sensor S


205


. A sensor S


203




d


is provided to limit the stacking amount by the height when the stack tray


200


receives sheets from the treating tray


130


, and is provided at a position corresponding to 2000 sheets from the sheet surface sensor S


205


. A lower limit sensor S


203




e


is provided for preventing excessive descent of the stack tray


200


. Among the above-mentioned sensors, the sheet surface sensors S


204


, S


205


alone are composed of transmissive sensors between the front and rear sides. Also each tray is provided with a sheet present/absent sensor


206


.




The sheet surface detection is achieved by at first elevating the tray to a position until the sheet surface sensor is covered, and, after the sheet stacking, lowering the tray until the optical axis of the sheet surface sensor is uncovered and elevating the tray until the optical axis of the sheet surface sensor is again covered. This operation is reiterated.




In the following there will be explained the punch unit


50


with reference to

FIGS. 15

to


20


.




The punch unit


50


is provided with punching means


60


and lateral registration detection means


80


. A punch


61


and a die


62


of the punching means


60


are respectively supported in casings


63


and are rendered rotatable in directions indicated by arrows B, C in mutual synchronization by mutually meshing respective gears


64


,


65


driven by a punch drive motor


66


. The punch


61


and the die


62


normally wait in a home position shown in FIG.


16


. After the detection of the trailing end of the sheet by the sheet sensor


31


, the punch drive motor


66


(

FIG. 18

) is driven at a predetermined timing whereby the punch


61


and the die


62


respectively rotate in the directions indicated by the arrows B, C as shown in FIG.


16


and the punch


61


engages with a die hole


62




a


provided in the die


62


thereby punching the conveying sheet.




In this operation, the punching of the sheet in conveyance can be achieved by maintaining the rotating speed of the punch


61


and the die


62


the same as that of the aforementioned conveying rollers


3


. Guide portions


67


are provided for moving the punching means


60


perpendicularly to the conveying direction A of the sheet. Rollers


68


rotating in contact with the guide portions


67


are caulked to the casings


63


by roller shafts


69


.




A rack


63




a


, formed in a part of the casing


63


(FIG.


19


), meshes with a pinion


70


provided in an unrepresented punching means moving motor. A punching means initial position sensor


71


, having a light-receiving portion


71




a


parallel to the sheet conveying direction indicated by arrow A, is mounted on the casing


63


.




Thus, by the driving force of the unrepresented punching means driving motor, the punching means


60


can move in directions indicated by double-headed arrow D, E perpendicularly to the sheet conveying direction A. A punching means initial position defining portion


52


can be detected by the light-receiving portion


71




a


by a movement of the punching means initial position sensor


71


in the direction E. The initial position of the punching means is selected several millimeters in front of the sheet reference position, corresponding to the declination resulting from skewed feed or aberration in lateral registration.




The lateral registration detection means


80


is mounted on the punching means


60


. The lateral registration detection means


80


is provided, at the front end of a sensor arm


82


, with a lateral registration sensor


81


having a light-receiving portion


81




a


parallel to the sheet conveying direction A and adapted to detect the side edge of the sheets.




The sensor arm


82


is provided, in a part thereof, with a rack


82




a


, meshing with a pinion


83


provided on an unrepresented lateral registration moving motor which is mounted on the casing


63


. On the rear end of the sensor arm


82


, there is mounted a lateral registration initial position sensor


84


having a light-receiving portion


84




a


parallel to the light receiving portion


81




a.






Thus, by the driving force of the unrepresented lateral registration movement motor, the lateral registration sensor


81


and the lateral registration initial position sensor


84


can be moved in the direction indicated by the double-headed arrow D, E perpendicular to the sheet conveying direction A. A lateral registration initial position defining portion


63




b


provided on the casing


63


can be detected by the light-receiving portion


84




a


by the movement of the lateral registration initial position sensor


84


in the direction E. Also the lateral registration sensor


81


can be set at a position corresponding to the selected sheet size, by the movement of the lateral registration sensor


81


in the direction D.




In detecting the side edge of the sheet, after the aforementioned sheet sensor


31


detects the leading end of the sheet, the unrepresented punching means moving motor is driven at a predetermined timing to move the punching means


60


and the lateral registration sensor


81


in the direction D, and the movement is terminated upon detection of the side edge of the sheet when the light-receiving portion


81




a


of the lateral registration sensor


81


is intercepted by the side edge of the sheet. It is therefore possible to regulate the punching position according to the side edge of the sheet.




In the following there will be explained the flow of the sheet P.




In

FIGS. 21

to


26


,


30


and


31


, the operations of the trailing end dropping member


181


, the knurled belt


182


etc. are the same as those already explained with reference to

FIGS. 5

to


10


and will not, therefore, be explained further.




When the user selects the non-sort mode on an operation unit (not shown) of the main body of the image forming apparatus, the paired entrance rollers


2


, conveying rollers


3


and large conveying roller


5


are rotated to convey the sheet P, conveyed from the main body


300


of the image forming apparatus and bearing the image thereon, as shown in FIG.


21


. The flapper


11


is shifted by a solenoid (not shown) to the illustrated position to convey the sheet P to the non-sort path


21


. When the sensor


33


detects the trailing end of the sheet P, the rollers


9


are rotated at a speed suitable for stacking, thereby discharging the sheet P onto the sample tray


201


. The discharged sheet P is received, at the trailing end thereof, by the grounding member


216


and is grounded, whereby the electrostatic charge accumulated on the sheet is dissipated.




Consequently the sheets P do not stick mutually and can be easily separated one by one. Also the user can be relieved from the electrical shock when grabbing the sheet P.




In the following there will be explained the operation when the staple sort mode is selected by the user.




As shown in

FIG. 22

, the paired entrance rollers


2


, the conveying rollers


3


and the large conveying roller


5


are rotated to convey the sheet P conveyed from the main body


300


of the image forming apparatus. The flappers


10


,


11


are maintained in positions shown in FIG.


22


. The sheet P passes the sort path


22


and is discharged by the discharge rollers


7


to the stapler


101


. In this state, the retractable tray


170


is in the protruding position, thereby receiving the leading end of the sheet P discharged from the discharge rollers


7


and preventing the sheet P from hanging, thus avoiding insufficient recovery of the sheet P and improving the sheet alignment on the treating tray.




The discharged sheet P starts to move, by the self-weight thereof, toward the trailing end stopper


31


(FIG.


5


), and the paddle


160


, stopped at the home position, starts to rotate counterclockwise by the motor M


160


to assist the sheet movement mentioned above. When the trailing end of the sheet P is stopped by securely abutting against the stopper


131


, the rotation of the paddle


160


is stopped and the discharged sheet is aligned by the front-side alignment mechanism


141


and the alignment member


142


.




The aligning operation for the sheet P will be explained later.




When all the sheets of a first copy are discharged and aligned on the treating tray


130


, the pivotally movable guide


150


is lowered as shown in

FIG. 23

whereupon the roller


180




b


rests on the sheet bundle and the stapler


101


staples the bundle of the sheets.




On the other hand, a sheet P


1


discharged in the meantime from the main body


300


of the image forming apparatus is guided by the flapper


10


and wound around the large conveying roller


5


as shown in FIG.


23


and is stopped at a predetermined distance after the sensor


32


. When a next sheet P


2


advances by a predetermined distance from the sheet sensor


31


, the large conveying roller


5


is rotated as shown in

FIG. 24

to superpose the second sheet P


2


on the first sheet P


1


in such a manner that the second sheet P


2


precedes the first sheet P


1


by a predetermined distance, and the second sheet P


2


is wound around the large conveying roller


5


as shown in FIG.


25


and is stopped after advancement by a predetermined distance. On the other hand, the sheet bundle on the treating tray


130


is discharge onto the stack tray


200


as shown in FIG.


25


and the electrostatic charge eventually accumulated on the sheet bundle is dissipated by the grounding members


216


.




In this operation, the retractable tray


170


is moved to the home position, before the sheet bundle passes through the discharged sheet bundle rollers, in order to drop the sheet bundle onto the stack tray


200


. When a third sheet P


3


reaches a predetermined position, the large conveying roller


5


is rotated as shown in

FIG. 26

to superpose the sheet P


3


with a displacement by a predetermined distance, and the flapper


10


pivots to convey the three sheets P to the sort path


22


.




The three sheets P are received by the rollers


180




a


,


180




b


while the pivotally movable guide


150


is in the lowered state as shown in

FIG. 27

, and, when the trailing end of the sheets P passes through the rollers


7


, the rollers


180




a


,


180




b


are reversely rotated as shown in

FIG. 28

, and, before the trailing end comes into contact with the stopper


131


, the pivotally movable guide


150


is elevated as shown in

FIG. 29A

whereby the roller


180




b


is separated from the sheet surface. Fourth and subsequent sheets P are discharged, in the same manner as the sheets of the first copy, onto the treating tray


130


through the sort path


22


. The operations for the third or subsequent copies are treated in the same manner as the second copy, and the predetermined number of copies are thus stacked on the stack tray


200


to finish the operation.




In the above-described conveying of superposed plural sheets, the sheets P are mutually offset in the conveying direction as shown in FIG.


29


B. The sheet P


2


is offset in the downstream side with respect to the sheet P


1


, and the sheet P


3


is offset in the downstream side with respect to the sheet P


2


.




The offset amount of the sheets P and the timing of elevation of the pivotally movable guide


150


are related to the sitting time of the sheets, dependent on the returning speed of the bundle discharge rollers


180




a


,


180




b


, and are therefore determined by the processing ability of the main body


300


of the image forming apparatus. In the present embodiment, for a sheet conveying speed of 750 mm/s, an offset amount b of about 20 mm and a returning speed 500 mm/s of the bundle discharge rollers, the bundle discharge rollers are designed to be separated at a timing when the sheet P


1


reaches a position of about 40 mm (valve of “a”) in front of the contact position with the stopper


131


.




In the following there will be explained the sort mode.




The user sets the originals on the RDF


500


, selects the sort mode on the operation unit (not shown) and depressed a start key (not shown). The entrance rollers


2


and the conveying rollers


3


rotate as shown in

FIG. 30

, as in the staple sort mode, thereby stacking the sheets on the treating tray


130


. The sheets P on the treating tray


130


are aligned by the aligning device


140


. After a small number of sheets P are stacked and aligned on the treating tray


130


, the pivotally movable guide


150


is lowered as shown in

FIG. 31

to convey the bundle of the sheets of small number.




A next sheet P passes over the flapper


10


, is wound around the large roller


5


as in the staple sort mode and is discharged onto the treating tray


130


after the discharge of the bundle. When the number of sheets in the discharged bundle of small sheet number is for example 20 sheets or less, such number is so selected as to satisfy a relation:






number of originals≧sheet number in a discharged bundle≦20






(however, this relation is not binding when the sheets are stapled). Thus, for example if the number of sheets in the bundle is selected as 5 sheets in programming, each bundle is discharged with 4 sheets in case the number of originals is 4. In case the number of the originals is larger than 5, for example 14, the sheets are divided into bundles of 5+5+4 which are respectively aligned and discharged.




In the present embodiment, the number of sheets in a bundle may exceed 20 in case the bundle is stapled.




The controlling circuit


301


receives, from the controlling means


930


of the main body


300


of the copying machine, the number of sheets per bundle, entered by the user. For example, if a bundle contains 39 sheets, there is executed offset control. In case a bundle contains 40 or more sheets, the offset control is not executed but the sheet bundles P are stacked as shown in FIG.


38


.




In case the offset control is executed, after the discharge of the first stapled bundle, the front-side aligning mechanism


141


is moved together with the rear-side aligning member


142


, whereby the aligning position for the second copy is offset with respect to that for the first copy. This operation will be explained later in more details.




The second copy is aligned in thus offset position, stapled in the same manner as the first copy and discharged as a bundle. After the discharge of the second bundle, the rear-side aligning member


142


moves to a further rearward position, and the front-side aligning mechanism


141


aligns the sheets, using the rear-side aligning member


142


as reference, thereby further offsetting the aligning position for the third copy with respect to that for the second copy.




The third copy is aligned in thus offset position, stapled in the same manner as the second copy and discharged as a bundle.




After the discharge of the third bundle, the front-side aligning member


141


moves to a near position together with the rear-side aligning member


142


, thereby returning the aligning position for the fourth copy to that for the first copy.




Thereafter the procedure is repeated in a similar manner to offset the fifth copy to a position same as that for the second copy.




In this manner all the copies are offset in the unit of a bundle, as shown in FIG.


32


.




Now there will be explained the aligning operation.




The controlling circuit


301


executes following three controls, based on the number of sheets in a bundle, designated by the user, and the presence or absence of selection of the sheet stapling mode.




Firstly, the controlling circuit


301


executes offset control as shown in

FIG. 32

or


37


, in case the user designates the number of sheets in the bundle not exceeding a predetermined number (for example 39 sheets or less) and does not select the sheet stapling mode.




Secondly, the controlling circuit


301


executes offset control as shown in

FIG. 32

or


37


also in case the user designates the number of sheets in the bundle not exceeding a predetermined number (for example 39 sheets or less) and selects the sheet stapling mode.




Thirdly, the controlling circuit


301


executes offset control as shown in

FIG. 32

or


37


also in case the user designates the number of sheets in the bundle exceeding a predetermined number (for example 40 sheets or more) and does not select the sheet stapling mode.




Fourthly, the controlling circuit


301


does not execute offset control but executes such control as to stack the sheet bundles in a same position as shown in

FIG. 38

, in case the user designates the number of sheets in the bundle exceeding a predetermined number (for example 40 sheets or more) and selects the sheet stapling mode.




The first and second controls mentioned above are only different in that the sheets are stapled or not, and hardly need be distinguished in the explanation of the aligning operation. Therefore, the aligning operation will be explained in the following principally on the first control, but the operation based on the second control will also be explained at the same time.




The controlling circuit


301


selects one of the above-described controls, based on the number of sheets designated by the user in the bundle and the presence or absence of selection of the stapling mode.




In the present embodiment, there will be explained a case of offsetting in three positions, but the number of offset positions is not restrictive. The offsetting in three positions is achieved by taking the sheet bundle in the center as reference.




At first, in the absence of sheet on the treating tray


130


, as shown in

FIG. 33

, the front-side aligning member


146


and the rear-side aligning member


142


wait in home positions PS


11


, PS


21


which are mutually apart somewhat wider than the width of the sheet conveyed from the sort path


22


.




When the first sheet P is to be discharged, the front-side aligning mechanism


141


moves from the home position to a first aligning position PS


12


, but the rear-side aligning member


142


still wait in the home position PS


21


.




When the first sheet P is discharged onto the treating tray


130


, the first sheet P is supported by the supporting surfaces


146




c


,


142




c


of the aligning members, and the trailing end of the sheet is received by the trailing end stopper


131


. In this state, the rear-side aligning member


142


moves to a first aligning position PS


22


, and the sheet is aligned to the first aligning position by the aligning surface


142




a


of the rear-side aligning member


142


and the aligning surface


146




a


of the front-side aligning member


146


. In this state, the distance between the aligning surfaces


142




a


,


146




a


, namely the distance between the first aligning positions PS


22


, PS


12


, is slightly wider than the sheet width, more specifically by about 2 mm.




Then, in preparation for the discharge of a next sheet, the front-side aligning mechanism


141


waits in the position PS


12


, but the rear-side aligning member


142


returns to the home position PS


21


. When the next sheet is discharged, the rear-side aligning member


142


moves to the first aligning position PS


22


to align the sheet.




Thus, for each sheet discharge, the rear-side aligning member


142


moves between the home position PS


21


and the first aligning position PS


22


, thereby aligning the sheet in the direction of width in cooperation with the front-side aligning member


142


. During this operation, the front-side aligning member


146


stops at the first aligning position PS


21


, constituting the reference position for the first aligning position.




The above-described operation is continued until the last sheet in the same bundle, but, because the number of sheet in the bundle is relatively limited (39 sheets or less), the aligning member


142


can move to the first aligning position PS


22


properly selected for the sheet width and can align the sheets, without pressing the sheets, against the force of the spring


148


provided in the compressed state on the front-side aligning mechanism


141


.




The spring


148


is provided for absorbing the shock of the aligning operation.




The spring


148


is provided in the compressed state because, if provided in a state of free length, it is compressed to a length balanced with the slight pressure of the sheets whereby the front-side aligning member


146


is displaced from the reference position for the first aligning position.




The position of the rear-side aligning member


142


is controlled by detecting the sheet with the sensor


183


provided in the sort path


22


shown in

FIG. 5

, counting the sheets by the controlling circuit


301


of the sheet treating apparatus based on the sheet detection signals from the sensor


183


until the count reaches the predetermined number of sheet in the bundle, and controlling the motor M


142


shown in

FIG. 12

by the controlling circuit


301


thereby rotating the pinion


144


shown in

FIGS. 11 and 12

.




For the above-described aligning operation, in order to prevent that the side edge of the sheet in movement collides with the end of the supporting surface


146




c


and is creased, the length L


1


of the supporting surfaces


142




c


,


146




c


is selected larger than the offset amount L


2


shown in FIG.


32


. However, the length of the supporting surfaces


142




c


,


146




c


is illustrated smaller than the offset amount L


2


for the purpose of brevity and clarity.




Thus aligned sheet bundle of the first copy (stapled in this state in case of the second control) is discharged as a bundle as explained before and is conveyed to the stack tray


200


as shown in FIG.


32


.




Then the sheets of the second copy are discharged onto the treating tray


130


, and, in this state, the front-side aligning mechanism


141


and the rear-side aligning member


142


return to the home positions PS


11


, PS


21


as shown in FIG.


36


. When the first sheet is discharged onto the treating tray


130


, the front-side aligning member


146


remains at the home position PS


11


as the reference position for the second aligning position, while the rear-side aligning member


142


moves to the second aligning position PS


23


shown in

FIG. 36

, thereby aligning the sheet. In this state, the distance between the home position PS


11


and the second aligning position PS


23


is somewhat wider than the sheet width.




For each sheet discharge thereafter, the rear-side aligning member


142


reciprocates between the home position PS


21


and the second aligning position PS


23


to align the sheets.




Thus aligned sheet bundle of the second copy (stapled in this state in case of the second control) is discharged as a bundle as explained before and is conveyed to the stack tray


200


as shown in FIG.


32


and is stacked as the second bundle from the bottom.




Subsequently the sheets of the third copy are discharged onto the treating tray


130


, and, in this state, the front-side aligning mechanism


141


remains at the home position PS


11


while the rear-side aligning member


142


moves to the third aligning position PS


24


as shown in FIG.


35


. When the sheets of the third copy is discharged onto the treating tray


130


, the front-side aligning member


146


moves from the home position PS


11


to the third aligning position PS


14


, thereby aligning the sheet in contact with the rear-side aligning member


142


. In this state, the rear-side aligning member


142


remains at the third aligning position PS


24


, constituting the reference position for the third aligning position. In this state, the distance between the third aligning positions PS


14


and PS


24


is substantially the same as the sheet width.




For each sheet discharge thereafter, the front-side aligning member


141


reciprocates between the home position PS


11


and the third aligning position PS


14


to align the sheets.




Thus aligned sheet bundle of the third copy is stapled if desired and is discharged as a bundle as explained before. It is then conveyed to the stack tray


200


as shown in FIG.


32


and is stacked as the third bundle from the bottom.




The sheets of fourth, fifth and sixth copies are discharged to the stack tray


200


with offsets similarly to those of first, second and third copies, respectively and are stacked as shown in FIG.


32


.




It is however not essential to execute offsetting for every three copies. For example, if the number of sheets in each bundle is smaller, it is possible to execute offsetting in a larger number of positions.




With such offsetting in a larger number of positions, the entire sheets become inclined to the right in

FIG. 32

, to bring the right-hand end of the sheets into contact with the stack tray


200


, whereby the sheet bundles become arranged similar to the slates on the roof, and the entire height of the sheets can be reduced.




In the foregoing description, in the second control, the sheets are aligned in the offset position on the treating tray


130


, then stapled and discharged onto the stack tray


200


, but, in the first control, the controlling circuit


301


may execute control in such a manner as to align the sheets in the offset position and to stack the sheets in bundles on the stack tray


200


.




The above-mentioned offset amount L


2


may be varied between the sort mode and the staple mode. For example, in the staple mode, the offset amount may be so selected as to avoid mutual overlapping of the staples of the neighboring bundles after stacking (about 15 mm), and, in the sort mode, the offset amount may be so selected that the bundles can be clearly distinguished under visual observation (about 20 to 30 mm), whereby it is made possible to shorten the moving distance for alignment in the staple mode and to improve the processing speed.




In the above-mentioned second control (staple mode), the stapler


101


waits in advance in a desired clinch position with respect to the aligned sheets, and execute the stapling operation upon completion of the discharge of the last sheet of the bundle. The aligning position of the sheet bundle is changed by the offset amount for each bundle, and the stapler moves accordingly.




As already explained in the foregoing, the stapler


101


moves, with a change in the direction thereof, according to the stapling mode (diagonal stapling in the front corner, diagonal stapling in the rear corner or two-position stapling). However, in the aforementioned configuration, a same staple attitude (horizontal or inclined state) can be maintained only within a certain range, and the sheets to be stapled may have various widths, so that the stapling operation may not be achievable at a same alignment position for the stapling modes mentioned above. For this reason, the first, second and third aligning positions may be suitably varied according to the stapling mode.





FIGS. 39

,


40


and


41


show the aligning positions respectively for the two-position stapling, diagonal stapling in the rear corner and diagonal stapling in the front corner, wherein an alternate long and two short dashes line indicates the first aligning position while a solid line indicates the second aligning position. The third aligning position is not illustrated but is positioned more rear than the second aligning position.




In this operation, if the aligning position is present closer to the discharge position, the sheet is conveyed toward the front-side aligning mechanism


141


utilizing the rear-side aligning member


142


as reference, but, if the aligning position is present more rear than the discharge position, the sheet discharge is executed as explained in the foregoing.




Thus the sheet can be moved to a position corresponding to the stapler


101


by switching the aligning position according to the stapling mode.




It is thus rendered possible, in case each sheet bundle is stapled, to prevent mutual interference of the neighboring sheet bundles by offsetting, for each sheet bundle, the aligning position of the front-side aligning mechanism


141


and the aligning member


142


for aligning the bundle of the sheets discharged onto the treating tray


130


by the bundle discharge rollers


180


.




The above-described aligning operation is executed in the first and second controls, and the distance between the front-side aligning member


146


and the rear-side aligning member


142


is made slightly wider than the sheet width in case of sheet alignment utilizing, as reference, the front-side aligning member


146


of the front-side aligning mechanism


141


having the spring


148


but is made substantially the same as the sheet width in case sheet alignment utilizing the rear-side aligning member


142


as reference. In the aforementioned third control, the aligning operation is executed in the same manner as in the first or second control until the number of sheets reaches a predetermined number, and beyond such number, the aligning operation is executed by selecting the distance of the front-side aligning member


146


and the rear-side aligning member


142


substantially the same as the sheet width, regardless whether the front-side aligning member


146


or the rear-side aligning member


142


is used as the reference.




More specifically, in the sheet bundle alignment in the third control corresponding to

FIG. 33

, when the number of sheets exceeds a predetermined number, the rear-side aligning member


142


moves to a position closer to the front-side aligning member


141


than the first aligning position PS


22


in the first or second control. In this state, the distance between the front-side aligning member


146


of the front-side aligning mechanism


141


and the rear-side aligning member


142


is substantially the same as the sheet width.




Likewise, in the sheet bundle alignment corresponding to

FIG. 36

, when the number of sheets exceeds a predetermined number, the rear-side aligning member


142


moves to a position closer to the front-side aligning member


141


than the second aligning position PS


23


in the first or second control. In this state, the distance between the front-side aligning member


146


of the front-side aligning mechanism


141


and the rear-side aligning member


142


is also substantially the same as the sheet width.




Also in case of sheet bundle alignment corresponding to

FIG. 35

, when the predetermined sheet number is exceeded, the front-side aligning member


146


moves to a position same as the third aligning position PS


14


in the first or second control. In this state, the distance between the front-side aligning member


146


of the front-side aligning mechanism


141


and the rear-side aligning member


142


is also substantially the same as the sheet width.




In the fourth control, the sheet aligning operation is executed in the same manner as in the first or second control until the number of sheets reaches a predetermined number, and beyond the predetermined number, the aligning operation corresponding to the third control as shown in

FIG. 36

is executed and the sheet bundle is stapled. More specifically, the aligning member


146


of the front-side aligning mechanism


141


is taken as the reference and the rear-side aligning member


142


comes closer to the front-side aligning member


146


. Also in this case, the distance of the front-side aligning member


146


of the front-side aligning mechanism


141


and the rear-side aligning member


142


is substantially the same as the sheet width.




In the following there will be explained the movement of the stack tray


200


and the sample tray


201


(FIGS.


14


and


15


).




Prior to the start of operation, these trays normally wait in the positions of respective sheet surface sensors.




As explained in the foregoing, the stack tray


200


is normally used for stacking the copied or printed sheets. It can receive the sheets treated for example by the stapler


101


or the unstapled sheet bundle discharged with a limited number of sheets, and can support up to 2000 sheets at maximum, which is detected by the sensor


203




d.






If the printing output still continues, the stack tray


200


is lowered by a height corresponding to 1000 sheets from the position of the sensor S


203




d


(namely to a position S


203




d


′). Then the sample tray


201


is lowered to the position of the sheet surface sensor S


205


for the treating tray, and the sheet receiving is started again. The sample tray


201


can support up to 1000 sheets at maximum, which is detected by the sensor


203




c.






In case of starting a next job without removing the sheets on the stack tray


200


after the completion of the job not exceeding 2000 sheets or executing a job by interrupting the current job, the sample tray


201


may be used for sheet stacking from the non-sort path


21


, though the treating operation is not possible.




The normal output operation to the sample tray


201


through the non-sort path


21


may be used for the output of a copy only for sample purpose without treating, or in case the output to the sample tray is selected in the function sorting.




In the following there will be explained the punch mode, principally according to a flow chart in

FIG. 42

, showing the operation sequence of the punch unit


50


.




When the power supply of the apparatus is turned on in S


1


, a step S


2


activates the unrepresented punching means moving motor to move the punching means


60


in the direction E (FIG.


19


), whereby the light-receiving portion


71




a


of the punching means initial position sensor


71


is intercepted by the punching means initial position defining portion


52


provided in the main body


1


, whereupon the initial position is detected and the movement is terminated.




Similarly the unrepresented lateral registration movement motor is activated to move the sensor arm


82


in the direction E, whereby the light-receiving portion


84




a


of the lateral registration initial position sensor


84


is intercepted by the lateral registration initial position defining portion


63




b


provided in the casing


63


, whereupon the initial position is detected and the movement is terminated. There is thus reached an input waiting state (S


3


).




Then the user selects an unrepresented punch selection button in the main body


300


of the image forming apparatus and depressed the unrepresented start button (S


4


), whereby the sheet conveying and the image formation are started in the main body


300


of the image forming apparatus (S


6


).




At the same time, the unrepresented lateral registration movement motor is activated to move the sensor arm


82


in the direction D, thereby moving the lateral registration sensor


81


to a position corresponding to the selected sheet size (S


5


).




Subsequently the sheet, bearing the formed image, is conveyed into the finisher


1


, and, the leading end of the sheet passes through the sheet sensor


31


and at a predetermined timing after the detection of the leading end of the sheet by the sheet sensor


31


, the unrepresented punching means moving motor is activated to move the punching means


60


and the lateral registration sensor


81


in the direction D. When the light-receiving portion


81




a


of the lateral registration sensor


81


is intercepted by the side edge of the sheet, the side edge of the sheet is detected and the movement is terminated (S


8


).




Subsequently, the trailing end of the sheet passes through the sheet sensor


31


, and upon detection of the trailing end of the sheet by the sheet sensor


31


(S


9


), the punch driving motor


66


is activated after a predetermined time to rotate the punch


61


and the die


62


respectively in the directions B, C, whereupon the punch


61


engages with the die hole


62




a


provided in the die


62


to punch a hole in the conveying sheet (S


10


). thereafter, the sheet is discharged according to any of the discharge modes described in the foregoing.




In case the number of sheets becomes relatively large (for example in excess of 40 sheets), the aligning member


142


once moves closer to the front-side aligning member


146


than the first aligning position PS


22


. Consequently the sheets are supported between the aligning members


146


and


142


by the elastic force of the spring


148


, thus assuming an upward bent state. Subsequently the aligning member


142


moves to the first aligning position PS


22


, and the multiple sheets return to the flat state by the elasticity thereof, thus being securely aligned.




The aligning device


140


explained in the foregoing is provided on the treating tray


130


and serves to align the image-bearing sheets, but the aligning device


140


may also be provided on a tray which is provided in the automatic original feeder (RDF)


500


on the main body


300


of the copying machine (the main body of the image forming apparatus) and which serves to receive the originals discharged after information reading.




The sheet treating apparatus of the present invention is capable of dissipating, through the grounding members, the electrostatic charge eventually accumulated on the sheets and thus maintaining the sheets in charge-free state, whereby the sheets discharged onto the tray are not subjected to resistance by the electrostatic charge and are free from defective discharge.




Even when the sheets are discharged in a bundled state onto the discharge sheet stacking means are therefore more easily charged, the electrostatic charge can be securely dissipated by the grounding members.




Also the sheets do not mutually stick by the electrostatic charge and can be easily separated.




Also the grounding member may be provided with an elastic finger capable of engaging with an engaging hole provided in the main body of the apparatus, so that the grounding member can be manufactured separately from the main body and mounted on the main body, and the manufacturing cost of the sheet treating apparatus can therefore be lowered.




Furthermore, the grounding member is replaceable.




The image forming apparatus of the present invention, being provided with the sheet treating apparatus, can prevent the defective sheet discharge, resulting from the electrostatic charge accumulated on the sheets.



Claims
  • 1. A sheet stacking apparatus comprising:discharge means for discharging a sheet; stacking means for stacking the sheet discharged by said discharge means; and a grounding member for contacting the sheet stacked on said stacking means, thereby grounding said sheet, wherein said grounding member is disposed in a position in which said grounding member is out of contact with a discharging sheet being discharged by said discharge means, and wherein said grounding member comes into contact only with a trailing end of all the sheet.
  • 2. A sheet stacking apparatus according to claim 1, wherein said discharge means discharges the sheet on said stacking means, and the discharged sheet is stacked on said stacking means.
  • 3. A sheet stacking apparatus according to claim 1, wherein said sheet is discharged in a shape of a bundle onto said stacking means.
  • 4. A sheet stacking apparatus according to claim 1, wherein said grounding member is composed of a metal.
  • 5. A sheet stacking apparatus according to claim 1, wherein said grounding member includes a molded plastic member in which metal powder is mixed.
  • 6. A sheet stacking apparatus according to claim 1, wherein said grounding member includes a molded plastic member which is plated with a metal.
  • 7. A sheet stacking apparatus comprising:a tray which is movable in the vertical direction; a roller for discharging a sheet on said tray; a grounding member for contacting the sheet stacked on said tray, thereby grounding said sheet, wherein said grounding member extends from underside of said tray to upper side of said tray.
  • 8. A sheet stacking apparatus according to claim 1, wherein said stacking means has a stacking surface being inclined so that said stacking surface is lowered on a side of said grounding member of said stacking surface, and wherein the sheet discharged by said discharge means drops onto said stacking surface.
  • 9. A sheet stacking apparatus according to claim 1, wherein said grounding member has a vertically extending surface to come simultaneously into contact with al ends of sheets of a stack stacked on said stacking means.
  • 10. A sheet stacking apparatus according to claim 1, further comprising:a position regulating member for regulating a position of an end of the sheet stacked on said stacking means.
  • 11. A sheet stacking apparatus according to claim 10, wherein said grounding member is provided on said position regulating member.
  • 12. A sheet stacking apparatus according to claim 10, wherein said grounding member includes an elastic finger engageable with and disengageable from an engaging hole formed in said position regulating member.
  • 13. A sheet stacking apparatus according to claim 10, wherein said grounding member includes a grounded metal plate provided in a portion receiving a trailing end of said sheet of said position regulating member.
  • 14. A sheet stacking apparatus comprising:a tray; a roller for discharging a sheet on said tray; and a grounding member for contacting the sheet stacked on said tray, thereby wherein said grounding member is disposed in a position in which said grounding member is out of contact with a discharging sheet discharged by said roller, and wherein said grounding member comes into contact with a trailing end of the sheet, and out of contact with an under surface of the sheet stacked on said tray.
  • 15. A sheet stacking apparatus according to claim 14, wherein said sheet is discharged in a shape of a bundle onto said tray.
  • 16. A sheet stacking apparatus according to claim 14, wherein said grounding member is provided on a position regulating member for regulating the position of the sheet stacked on said tray.
  • 17. A sheet stacking apparatus according to claim 14, wherein said grounding member includes a metal plate.
  • 18. A sheet stacking apparatus according to claim 14, wherein said grounding member has a vertically extending surface to come simultaneously into contact with all ends of sheets of a stack stacked on said tray.
  • 19. A sheet stacking apparatus according to claim 14, further comprising image forming means for forming an image on the sheet, wherein said roller discharges the sheet on which the image is formed by said image forming means.
  • 20. A sheet stacking apparatus comprising:a tray which is movable in the vertical direction; a roller for discharging a sheet on said tray; a grounding member for contacting the sheet stacked on said tray, thereby grounding said sheet, wherein said grounding member extends from underside of said tray to upper side of said tray.
  • 21. A sheet stacking apparatus according to claim 20, wherein said sheet is discharged in a shape of a bundle onto said tray.
  • 22. A sheet stacking apparatus according to claim 20, wherein said grounding member is provided on a position regulating member for regulating the position of the sheet stacked on said tray.
  • 23. A sheet stacking apparatus according to claim 20, wherein said grounding member includes a metal plate.
  • 24. A sheet stacking apparatus according to claim 20, wherein said grounding member has a vertically extending surface to come simultaneously into contact with all ends of sheets of a stack stacked on said tray.
  • 25. A sheet stacking apparatus according to claim 20, wherein said grounding member extends through said tray in the vertical direction.
  • 26. A sheet stacking apparatus according to claim 20, further comprising image forming means for forming an image on the sheet, wherein said roller discharges the sheet on which the image is formed by said image forming means.
Priority Claims (1)
Number Date Country Kind
10-338205 Nov 1998 JP
US Referenced Citations (8)
Number Name Date Kind
3612515 Bergeson Oct 1971 A
3826379 Wright Jul 1974 A
4339119 Sasaki et al. Jul 1982 A
4501418 Ariga et al. Feb 1985 A
4660824 Hermkens et al. Apr 1987 A
5407188 Ida et al. Apr 1995 A
5911414 Kato et al. Jun 1999 A
20020060896 Liu Sep 2001 A1
Foreign Referenced Citations (3)
Number Date Country
0 024 712 Aug 1980 EP
0 850 866 Jul 1998 EP
57-027272 Feb 1982 JP