1. Field of the Invention
The present invention relates to a sheet processing apparatus in which booklet-like bundles of folded sheets are stacked and an image forming apparatus provided with such a sheet processing apparatus in its main body. In particular, the present invention relates to a sheet processing apparatus in which the folded portion of a succeeding sheet bundle is prevented from entering an open portion opposed to the folded portion of a preceding sheet bundle.
2. Description of the Related Art
In some conventional image forming apparatuses for forming an image on a sheet, a sheet processing apparatus is equipped as a component of the apparatus. The sheet processing apparatus bundles sheets onto which images have been formed in the main body of the apparatus, binds the bundle and then folds it into a booklet form. In such a sheet processing apparatus, sheets are sequentially received on a tray to align edges of sheets to make a sheet bundle, binds the sheet bundle near a central portion in an edge part of the bundle, pushes the central portion by a pushing member to thrust the sheet bundle into the nip of a pair of rollers, and folds the sheet bundle by the pair of rollers while conveying it. In addition, Japanese Patent Application Laid-Open No. 2003-182928 discloses a sheet processing apparatus that performs a fold line processing to form a neat fold line.
The operation of such a conventional sheet processing apparatus will be described with reference to
Then fold line enhancing process is performed using second folding rollers that are different from the first pair of folding rollers 83, 84 by holding the folded portion between a second folding roller or second folding rollers 85, and moving a holding member 851 that supports the second folding rollers 85 along the fold line (i.e. in the direction perpendicular to the conveyance direction). Thus, a center-folded sheet bundle (hereinafter referred to as “folded sheet bundle”) that is folded at its center is obtained. Subsequently, the operation of the first folding roller pair 83, 84 is restarted, so that the sheet bundle is conveyed and discharged onto a tray 63.
In the conventional sheet processing apparatus, the sheet bundles must be stacked on the tray 63 in such a way that the trailing edge of the folded sheet bundle is positioned outside the operation region of the holding member 851 i.e., downstream with respect to the conveyance direction, so as not to interfere with the moving holding member 851 of the second folding roller 85. However, keeping such a positional relationship leads to a broad spacing between the trailing edge of the sheet bundles stacked on the tray 63 and the first folding roller pair 83, 84.
Accordingly, in some cases, the folded portion of the succeeding folded sheet bundle that is being discharged droops down and gets stuck with the rear edge of the preceding folded sheet bundle stacked on the tray 63. Consequently, the succeeding folded sheet bundle may abut the preceding folded sheet bundle or get into the open trailing end of the preceding folded sheet bundle, so that jamming of the folded sheet bundles, stack failure or bending of sheets sometimes occur.
The smaller the thickness of the sheets that constitute the folded sheet bundle is, the lower the stiffness of the sheets is, and the smaller the number of the folded sheets is, the more likely the folded sheet bundle droops down, and the more prominent the above-described problem is.
The above-described phenomenon also occurs in the case of a type of sheet processing apparatus in which the holding member 851 of the second folding roller 85 is not provided and the folded sheet bundle is delivered onto the tray 63 by the first folding roller pair 83, 84 without undergoing a fold line enhancing process.
As per the above discussion, in conventional sheet processing apparatuses, improper stacking of the folded sheet bundles sometimes occurs.
Provision of a sheet processing apparatus that suffers from improper stacking of folded sheet bundles in an image forming apparatus leads to a low image processing efficiency of the image forming apparatus as a whole.
An object of the invention is to provide a sheet processing apparatus in which when folded sheet bundles are stacked, the folded portion of a succeeding sheet bundle can be placed on an open portion opposed to the folded portion of a preceding sheet bundle in an overlapping manner whereby the folded portion of the succeeding sheet bundle is prevented from entering the open portion of the preceding sheet bundle.
Another object of the present invention is to provide an image forming apparatus having an improved image forming efficiency equipped with a sheet processing apparatus that can stack folded sheet bundles with reliability.
A further object of the present invention is to provide a sheet processing apparatus comprising a sheet discharge portion that discharges a folded sheet bundle with a folded portion being the leading edge and a sheet stack portion which stacks the folded sheet bundle discharged from said sheet discharge portion, the sheet stack portion being enabled to move the atacked sheet bundle in a sheet discharge direction, and in an opposite direction to the sheet discharge direction, wherein the sheet stack portion moves a preceding sheet bundle in the opposite direction so that the folded portion of a succeeding sheet bundle abuts an upper surface of the preceding sheet bundle, before the folded portion of the succeeding sheet bundle abuts the preceding sheet bundle stacked on the sheet stack portion.
An image forming apparatus according to the present invention is provided with an image forming portion that forms an image on a sheet and a sheet processing apparatus on which a sheet bundle formed by arranging the sheets into a bundle and folding it is stacked, the sheet processing apparatus being the above-described sheet processing apparatus.
In the sheet processing apparatus according to the present invention, the sheet stack portion is adapted to move the preceding sheet bundle to the upstream direction in the sheet discharging direction to position the open portion opposed to the folded portion of the preceding sheet bundle upstream of the folded portion of the succeeding sheet bundle before the succeeding sheet bundle is discharged onto the preceding sheet bundle on the sheet stack portion. Thus, the sheet processing apparatus according to the present invention can stack the sheet bundles in such a way that the folded portion of the succeeding sheet bundle is placed on the open side portion of the preceding sheet bundle in an overlapping manner thereby making it possible to prevent the folded portion of the succeeding sheet bundle from entering the open portion of the preceding sheet bundle and to minimize improper stacking.
Since the image forming apparatus according to the present invention is equipped with a sheet processing apparatus in which frequency of improper stacking of the sheet bundle is low, it possible to improve image forming efficiency.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
In the following, a finisher equipped with a saddle-stitching bookbinding section 800 that constitutes a sheet processing apparatus according to an embodiment of the present invention and an image forming apparatus provided with the finisher will be described with reference to the drawings.
A copying machine 1000 as an image forming apparatus has an original feeding portion 100, an image reader section 200, a printer section 300, a folding process section 400, a finisher section 500, an inserter section 900 and so on. The folding process section 400 and the inserter section 900 may be provided as optional equipment.
As shown in
The scanner unit 104 reads the image on the original that passes above the scanner unit 104, from left to right. This type of original reading method is called “flow reading”. While the original travels on the platen glass 102, it is illuminated by a lamp 103 of the scanner unit 104. Light reflected by the original is guided to an image sensor 109 via mirrors 105, 106, 107 and a lens 108.
The image reader section 200 may alternatively perform such an original reading process in which the original is stopped and temporarily kept stationary on the platen glass 102 by the original feeding portion 100 and the scanner unit 104 is moved from left to right in that state to read the original. This reading method is called “stationary reading”. When reading of an original is to be performed without using the original feeding portion 100, a user should set the original on the platen glass 102 by lifting up and then lowering the original feeding portion 100, and thereafter the scanner unit 104 performs the stationary reading.
A signal or signals image data of the original obtained by reading by the image sensor 109 is/are subjected to a predetermined image processing and sent to an exposure control portion 110. The exposure control portion 110 emits a laser beam in accordance with the signal or signals of image data. The laser beam is directed onto a photosensitive drum 111 in a scanning manner by a polygon mirror 110a. An electrostatic latent image corresponding to the scanning laser beam is formed on the photosensitive drum 111.
The electrostatic latent image formed on the photosensitive drum 111 is developed by the developing device 113 and visualized as a toner image. Meanwhile, a sheet (recording paper) P is conveyed to a transfer portion 116 from either one of a cassette 114, 115, a manual sheet feeding portion 125 and a double side conveyance path 124. Then, the visualized toner image is transferred onto the sheet in the transfer portion 116. The sheet on which the toner image has been transferred enters a fixing portion 177, where the toner image is fixed on the sheet. The photosensitive drum 111, the developing device 113 and other parts constitute an image forming portion.
The sheet having passed through the fixing portion 177 is once guided by a flapper 121 to a path 122. As the trailing edge of the sheet moves from of the flapper 121, it is conveyed in a switch-back manner and guided to the discharge rollers 118 by the flapper 121. The sheet is discharged from the printer section 300 by the discharge rollers 118. Thus, the sheet is discharged from the printer section 300 in the face-down state in which the side on which the toner image has been formed is facing downward. The above-described operation is referred to as “reverse discharge”.
In the case where sheets are discharged out of the machine in the face-down state, the image forming process may be performed sequentially from the first page. For example, when the image forming process is performed using the original feeding portion 100 or when image forming process is performed based on image data from a computer, the order of the pages can be arranged in a correct sequence.
In the case where images are formed on both sides of a sheet, the printer section 300 guides the sheet directly from the fixing portion 177 to the discharge rollers 118, and just after the trailing edge of the sheet gets out of the flapper 121, the sheet is conveyed in a switch-back manner and guided to the double side conveyance path 124 using the flapper 121.
The copying machine 1000 according to the present invention is equipped with a saddle-stitching bookbinding section 800 in which the frequency of improper stacking of sheet bundle is low, and therefore, the efficiency of image formation can be improved.
Next, the structure of the folding process section 400 and the finisher 500 will be described with reference to
In
When the folding process is to be applied on the sheet, the switching flapper 135 is switched to the folding path 136 side to guide the sheet to the folding path 136. The sheet guided to the folding path 136 is conveyed to folding rollers 140, 141 and folded into a Z shape (hereinafter referred to as “Z-folded”).
In the case where the folding process is not to be performed, the switching flipper 135 is switched to the position for guiding the sheet toward the finisher 500. The sheet discharged from the printer section 300 is directly transferred to the finisher 500 through the conveyance path 131 and the switching flapper 135.
The sheet conveyed into the folding path 136 abuts a stopper 137 by its leading edge to form a loop, and then the sheet is folded by folding rollers 140, 141. This folded portion is caused to abut an upper stopper 143 to form a loop, and the loop is further folded by the folding rollers 141, 142. Thus, the sheet is Z-folded. The Z-folded sheet is guided through conveyance paths 145, 131 and discharged to the finisher 500 by a pair of discharge rollers 133. The folding process performed by the folding process section 400 is applied selectively.
The finisher 500 is adapted to perform various processes on sheets such as a bundling process of arranging multiple sheets conveyed from the printer section 300 through the folding process section 400 into a sheet bundle, a stapling process (or binding process) of stapling the sheet bundle at its trailing edge side, a sorting process and non-sorting process.
As shown in
Between the conveying rollers 502 and the conveying rollers 503 is provided a punch unit 530. The punch unit 530 is adapted to perforate (or perform punching process on) the trailing edge portion of the conveyed sheet, when needed.
A flapper 513 provided at the end of the conveyance path 520 is adapted to switch the upper discharge path 521 and the lower discharge path 622 in the downstream direction thereof. The upper discharge path 521 is adapted to guide the sheet to a sample tray 701 by means of upper discharge rollers 509. On the other hand, in the lower discharge path 622, there is provided conveying roller pairs 510, 511 and 512. These roller pairs 510, 511 and 512 are adapted to convey the sheet and discharge it onto a processing tray 550.
The sheets discharged onto the processing tray 550 are arranged successively and stacked into a bundle, and a sorting process and a stapling process are performed thereon in accordance with setting established through an operating portion 1 (
The above-mentioned stapling process is performed by a stapler 560. The stapler 560 is adapted to move along the width direction of the sheet (i.e. the direction transverse to the sheet conveyance direction) to staple the sheet bundle at a desired position. The stack tray 700 and the sample tray 701 are adapted to move up and down along the body 500A of the finisher 500. The upper sample tray 701 is adapted to receive sheets from the upper discharge path 521 and the processing tray 550. The lower stack tray 700 is adapted to receive sheets from the processing tray 550. In this way, a large amount of sheets can be stacked on the stack tray 700 and the sample tray 701. The trailing edges of the stacked sheets are received by a trailing edge guide 710 extending in the vertical direction so as to be aligned.
Next, the structure of the saddle-stitching bookbinding section 800 will be described.
In the following description, a process of folding a sheet bundle using a pair of folding rollers 810 and pushing member 830 will be referred to as the folding process. A process of creasing a sheet bundle on which a folding process has been applied using a pair of press rollers 861 to make a fold line or crease will be referred to as fold line processing. The folding process and fold line processing constitute in combination what is referred to in the following as sheet processing.
Although the saddle-stitching bookbinding section 800 in this embodiment is provided with the press roller pair 861, it is not essential.
A switching flapper 514 provided halfway in the lower discharge path 622 is adapted to switch the path of the sheet to the right side to guide it into a saddle discharge path 523 and then to the saddle-stitching bookbinding section 800. In the saddle-stitching bookbinding section 800, there is provided a saddle inlet roller pair 801, a flapper 802 driven by a solenoid in accordance with the sheet size, a storage guide 803 for storing sheets, a slide roller 804 and a sheet positioning member 805 arranged in the mentioned order from the entrance of the saddle-stitching bookbinding section 800.
The saddle inlet roller pair 801 and the slide roller 804 are adapted to be rotated by a motor M1. A stapler 820 is provided halfway in the storage guide 803 in an opposed manner with the storage guide 803 therebetween. The stapler 820 has a driver 820a that drives a wire staple and an anvil 820b for bending the wire staple driven onto it.
The sheet positioning member 805 is adapted to receive the leading edge (i.e. the lower edge) of the sheet when the sheet are convey to it, and its position can be adjusted in the up-and-down directions so that the center of the sheet with respect to the conveyance direction is aligned with the binding position of the stapler 820. The sheet positioning member 805 is moved up and down by a motor M2 and stopped at a suitable position associated with the sheet size.
In the downstream of the stapler 820 are a pair of folding rollers 810a, 810b. A thrust member 830 is provided at a position opposed to the folding roller pair 810a, 810b. The folding roller pair 810a, 810b and the thrust member 830 constitute the folding portion.
The thrust member 830 has a home position away from the storage guide 803 and is adapted to be driven by a motor M3 to project toward a bundle of sheets stored in the storage guide 803 thereby thrusting the sheet bundle into the nip of the folding roller pair 810a, 810b. After that, the thrust member 830 is returned to the home position. A pressure F1 sufficient for folding process for folding the sheet bundle is created between the two folding rollers 810 by means of a spring (not shown).
The sheet bundle having been folded by the folding roller pair 810 is discharged onto a folded bundle tray 890 via a first folding, conveying roller pair 811a, 811b and a second folding, conveying roller pair 812a, 812b.
A force F2, F3 enough to convey and stop the folded sheet bundle is also created between the rollers of each of the first folding, conveying roller pair 811 and the second folding, conveying roller pair 812.
A conveyance guide 813 is adapted to guide the sheet bundle between the folding roller pair 810 and the first folding, conveying roller pair 811. A conveyance guide 814 is adapted to guide the sheet bundle between the first folding, conveying roller pair 811 and the second folding, conveying roller pair 812. The folding roller pair 810, the first folding conveying roller pair 811 and the second folding, conveying roller pair 812 are driven by the same motor M4 (not shown) to rotate at a constant speed while holding the sheet bundle folded at a portion centered between both sides.
Folding of the sheet bundle that has been bound by the stapler 820 is performed after the sheet bundle is moved down by the sheet positioning member 805 from the position for sheet stapling process by a predetermined distance so that the stapled position on the sheet bundle is aligned with the position of the nip of the folding roller pair 810. Thus, the sheet bundle is folded at the stapled (or bound) portion.
A pair of alignment plates 815 have surfaces extending toward the storage guide 803 and are adapted to align the sheets stored in the storage guide 803 with respect to the width direction while the sheets rotate around the outer circumference of the folding roller pair 810a, 810b. The pair of alignment plates 815 are driven by a motor M5 to move the sheets in the holding direction to perform positioning of the sheets with respect to the width direction.
Downstream of the second folding, conveying roller 812 is a fold line press unit 860 serving as a folded portion processing unit. The fold line press unit 860 has a press holder 862 that supports a pair of press rollers 861 and is adapted to enhance the fold line by moving the press holder 862 while nipping the folded portion with the pair of press rollers 861, namely it is adapted to make the fold line definitely. Directly below the fold line press unit 860 is provided a first conveyor belt 894.
Next, the structure of the fold line press unit 860 will be described.
The fold line press unit 860 has a metal base plate 863 on which principal parts are assembled and two slide shafts 864, 865 and is fixedly mounted on the front and rear side panels of the body 500A of the finisher. The two slide shafts 864, 865 are provided side by side and extending in the front-rear direction of the finisher 500 (
A timing belt 868 is looped around pulleys 866, 867 (
The home position of the press holder 862 is in the rear side portion of the finisher 500. This position is detected by a home sensor S1 (
In the following discussion, the press holder 862 will be described. It should be noted that illustration of a sheet guide 871 (
The press holder 862 has a frame 840. Slide bearings 874 and 875 are attached on the frame 840 by screws. The pair of press rollers 861a and 861b are fixedly mounted on the roller shaft 872a and 872b, respectively, and rotatably supported on press arms 873a and 873b (
A tension spring 875a, 875b is attached between one end of each of the press arms 873a, 873b and the frame 840. The pair of press rollers 861a, 861b are pulled toward each other by the tension springs 875a, 875b to form a nip. When a sheet bundle is introduced between the pair of press rollers 861a, 861b, the press arms 873a, 873b swing about the respective swing shafts 874a, 874b as the pivots so that a clearance is created between the pair of press rollers 861a, 861b.
One end of each roller shaft 872a, 872b projects beyond the frame 840 to the exterior. Gears 876, 877 are mounted on the projecting portions the roller shafts 872a, 872b. Gears 880, 879, 878 meshing with one another are rotatably mounted on the frame 840. The gear 878 meshes with the gear 876, the gear 879 meshes with the gear 877, and the gear 880 meshes with a gear 881. This gear 881 is fixedly mounted on a gear shaft 882.
The gear shaft 882 is supported on the frame 840 via a bearing. On the other end of the gear shaft 882 (
Rotation of the motor M6 causes the timing belt 868 to rotate, so that the press holder 862 is moved while being supported by the slide shafts 864, 865. With this movement, the gear 883 of the press holder 862 rotates and moves while meshing with the rack gear 841. With rotation of the gear 883, the pair of press rollers 861a, 861b also rotate. The gear ratios of the gears are designed in such a way that the velocity of movement of the press holder 862 and the circumferential velocity of the pair of the press rollers 861a, 861b become equal to each other.
The center-folded sheet bundle (hereinafter referred to as “folded sheet bundle”) that has been folded at its center is subjected to fold line processing in which the fold line of the sheets is made definite by the press roller pair 861 shown in
Specifically, the nip pressure F3 of the second folding, conveying roller pair 812 is applied on the leading edge portion of the folded sheet bundle, the nip pressure F2 of the first folding, conveying roller pair 811 is applied on the trailing edge thereof, and nip pressure F1 of the folding roller pair 810 is sometimes applied on it simultaneously depending on the sheet size (i.e. the length in the conveyance direction) of the folded sheet bundle. Consequently, even when a torque is applied on the folded sheet bundle as it is nipped by the press roller pair 861, the above-mentioned roller pairs can hold the folded sheet bundle to prevent it from moving in spite of the torque.
The position of the leading edge of the folded sheet bundle is detected by a sensor 884 provided on the conveyance guide 814 in order to keep constant the positional relationship between the position of the leading edge (the position of leading edge during it is pressed) of the folded sheet bundle at the time when it is stopped upon fold line processing for making the folded portion at the leading edge of the folded sheet bundle definite and the press roller pair 861, irrespective of the sheet size.
On the other hand, as to the position of the trailing edge (the position of trailing edge during it is pressed) during fold line processing, the positions of the various components are arranged in such a way that the trailing edge of the folded sheet bundle does not obstruct storage of the succeeding sheets conveyed into the storage guide 803, namely in such a way that the trailing edge of the folded sheet bundle does not project into or is not left in the storage guide 803. Specifically, the direct or shortest distance Ls of the guide path 885 from a discharge portion 803a, at which the sheet bundle stored in the storage guide 803 is thrust by the thrust member 830 so as to be discharged, to a position of the downstream direction surface 861c of the press roller pair 861 in the nip is arranged to be shorter than the length L1 (along the conveyance direction) of the folded sheet bundle of the maximum size that is subjected to the fold line processing(Ls<L1). The guide path 885 starts at the discharge portion 803a of the storage guide 803 and ends at the downstream direction surface 861c of the press roller pair 861.
The guide path 885 composed of the conveyance guide 813, 814 is curved gently so as not to create a permanent curl of the folded sheet bundle. The length Lm of the guide path 885 extending from the discharge portion 803a of the storage guide 803 to the downstream direction surface 861c of the press roller pair 861 through the pair of folding rollers 810 and the conveyance guides 813, 814 is arranged to be longer than the length L1 (along the conveyance direction) of the folded sheet bundle of the maximum size that is subjected to the fold line processing (Lm>L1).
In some cases, the press roller pair 861 performs the fold line processing on the sheet bundle in the state in which the leading edge Pa of the folded portion of the sheet bundle is positioned near the downstream direction surface 861c of the press roller pair 861 in the nip (
As per the above, by the above-described feature “Ls<L1” of the guide path 885 and gentle curvature of the conveyance guides 813, 814, the conveyance guides 813, 814 together with the press holder 862 can be accommodated in the space between the storage guide 803 (
By the above-described feature “Ls<L1”, it is possible to arrange the saddle-stitching bookbinding section 800 above the folded bundle tray 890 in a overlapping manner utilizing the vertically extending space in which the folded bundle tray 890 and the fold line press unit 860 are placed. Thus, it is possible to shorten the horizontal length of the apparatus.
In the saddle-stitching bookbinding section 800, by the above-described feature “Lm>L1”, the open side trailing edge portion Pc (
In addition, in the saddle-stitching bookbinding section 800, by the above-described feature “Lm>L1”, the trailing edge portion Pc of the folded sheet bundle is not left in the storage guide 803, and therefore succeeding sheets can be sequentially stored in the storage guide while the fold line processing is applied on the folded sheet bundle. Consequently, the trailing edge portion Pc of the center-folded sheet bundle does not open or spread, and therefore it is possible to enhance the appearance of the sheet bundle. In addition, it is possible to improve efficiency of sheet bundle processing by the saddle-stitching bookbinding section 800 by shortening the time interval of the fold line processing on sheet bundles or shortening the distance between the preceding sheet bundle and the succeeding sheet bundle.
The nip angle of the second folding, conveying roller pair 812 that discharges the sheet bundle onto the folded bundle tray 890 at the most downstream position in the guide path 885 is designed in such way that the folded sheet bundle is discharged in a downwardly inclined state. This design is adopted in order that the second folding, conveying roller pair 812 can discharge the folded sheet bundle below the stack tray 700 without fail even when a large amount of sheets are stacked on the stack tray 700 and the stack tray 700 has been lowered to the vicinity of the folded bundle tray 890.
Next, the structure of the folded bundle tray 890 will be described with reference to
The first stack surface 891 is arranged beneath the fold line press unit 860 in a spatially overlapping manner and inclined downwardly toward the downstream with respect to the conveyance direction of the sheet bundle. The angle of this inclination is arranged to be substantially equal to the discharge angle of the second folding, conveying roller pair 812. The top of the inclined surface of the first stack surface 891 is arranged as high as possible while being prevented from interfering with the operation of the fold line press unit 860. Thus, the drop distance from the second folding, conveying roller pair 812 to the first stack surface 891 is set as short as possible. The second stack surface 892 is inclined relative to the inclined surface of the first stack surface 891, where the second stack surface 892 is inclined in the direction opposite to the inclination of the first stack surface 891 (i.e. inclined upwardly toward the downstream direction with respect to the sheet conveyance direction). The third stack surface 893 is arranged parallel with the second stack surface 892 with a step therebetween. It is preferred that the angle of inclination of the first stack surface 891 be approximately 20 to 25 degrees downward from the horizontal plane, and the angle of inclination of the second stack surface 892 be approximately 10 to 15 degrees upward from the horizontal plane.
The first stack surface 891 and the second stack surface 892 are provided with the first and second conveyor belts 894 and 895 that serve as sheet bundle moving members for conveying folded sheet bundles stacked thereon. Both the first and the second conveyor belts 894, 895 are wound at one end thereof on a drive pulley 896 provided near the angled portion. The other end of the first conveyor belt 894 is wound on an idler pulley 897. The other end of the second conveyor belt 895 is wound on an idler pulley 898.
The first and the second conveyor belts 894, 895 are driven by a conveyor motor M7 connected to the shaft of the drive pulley 896 to rotate in the same forward or backward direction.
On the first stack surface 891 is provided a sheet bundle detection sensor 899 that can detect a center folded sheet bundle that is placed directly below the operation region of the fold line press unit 860. The sheet bundle detection sensor 899 is adapted to detect the stack position of the folded sheet bundle discharged.
The member providing the third stack surface 893 is accommodated beneath the second stack surface 892 in an extendable manner. When the member providing the third stack surface 893 is accommodated in the position illustrated by the broken line, a storage box 852 having a height equal to the height from the floor to the idler pulley 898 may be placed on the floor. Thus, it is possible to increase the number of the folded sheet bundles that can be stacked.
Next, an inserter 900 provided in the upper portion of the finisher 500 will be described with reference to
The inserter 900 is adapted to feed a sheet set by a user on an insert tray 901, 902 to one of the sample tray 701, the stack tray 700 and the folded bundle tray 890 without passing it through the printer section 300. The inserter 900 separates sheets stacked on the insert trays 901, 902 page by page and supplies a separated sheet into the finisher path 520 at a desired timing.
A RAM 152 is used as a memory space for temporarily storing control data and a workspace for computation required for a control process. The external I/F 203 is interface of the copying machine 1000 and an external computer 204. The external I/F 203 is adapted to develop print data from the computer 204 into bitmap image and output it as image data to the image signal control part 202. An image of an original read by the image sensor (not shown) is output from the image reader control part 201 to the image signal control part 202. The printer control part 301 is adapted to output image data from the image signal control part 202 to an exposure control part (not shown).
Next, the saddle-stitching bookbinding operation of the saddle-stitching bookbinding section 800 will be described.
When the saddle-stitching bookbinding mode is set by the user, sheets P on which images have been formed are sequentially discharged from the discharge rollers 118 (
Subsequently, the sheets are held between and aligned by the pair of alignment plates 815 that have been kept at a standby position at which the alignment plates do not interfere with the sheets conveyed into the storage guide 803. Thus, both side edges of the sheets are aligned. As a result, the sheets are aligned at its lower edge and both side edges.
The above-described sheet storage and alignment operations are performed every time the sheet P is conveyed into the storage guide 803. After completion of alignment of the last sheet, the central portion, with respect to the conveyance direction, of the sheet bundle stored in the storage guide 803 is stapled with wire by the stapler 820. As shown in
Thereafter, the thrust member 830 that has been at a standby position starts to move toward the nip of the folding roller pair 810 (in the direction indicated by arrow E) and thrusts the central portion of the sheet bundle P into the nip of the folding roller pair 810 while forcibly widening the gap of the folding roller pair 810. The folding roller pair 810 rotate to convey and fold the sheet bundle P in two while holding it in the nip (
As shown in
As shown in
Thereafter, the press roller pair 861 abuts a side edge portion Pb, which runs along the sheet conveyance direction, of the folded sheet bundle P that is held stationary. Since both of the two press rollers 861a, 861b are rotating, they receive the side edge portion Pb of the folded sheet bundle P and ride on the side edge portion smoothly to hold the folded portion therebetween (
The pairs of rollers 812, 811, 810 may be replaced by pairs of belts.
After the press roller pair 862 have reciprocated a predetermined number of times, the fold line press unit 860 is moved to the home position to open the path of the folded sheet bundle P1 in the conveyance direction. Thereafter, as shown in
As shown in
Since the bundle sensor 899 is disposed directly below the operation region of the fold line press unit 860, the entire folded sheet bundle P1 having been stopped including the trailing edge portion PC is positioned (at a first stack position) outside the operation region of the fold line press unit 860.
While the preceding folded sheet bundle P1 is discharged onto the folded bundle tray 890 in the above-described manner, the next (or succeeding) folded sheet bundle P2 undergoes discharge and alignment operations. In addition, the succeeding folded sheet bundle P2 is also subjected to the fold line enhancing process by the fold line press unit 860. Since the preceding folded sheet bundle P1 is placed at the first stack position, it does not interfere with the press unit 860 or obstruct the fold line enhancing process performed by the press unit 860. Furthermore, when the preceding folded sheet bundle P1 is conveyed to the first stack position, it is kept away from a wall provided below the second folding, conveying roller pair 812 for sure, and therefore the trailing edge Pc thereof does not lean against the wall to be curled.
As shown in
After that, the motor M4 starts to rotate again as shown in
The fold line of the preceding folded sheet bundle P1 has been sufficiently enhanced by the fold line press unit 860, and its trailing edge portion Pc does not become open. As described above, the saddle-stitching bookbinding section 800 is adapted to discharge the succeeding folded sheet bundle P2 onto the preceding folded sheet bundle P1 after moving the preceding folded sheet bundle P1 to the second stack position. Therefore, the leading edge Pa of the succeeding folded sheet bundle P2 does not get into the open trailing edge portion Pc of the preceding folded sheet bundle P1. Even in the case where the succeeding folded sheet bundle is a sheet bundle that is made of thin sheets with a low stiffness and likely to droop down, the succeeding folded sheet bundle does not get into the open trailing edge portion Pc of the preceding folded sheet bundle P1. Consequently, the succeeding folded sheet bundle P2 is stably stacked in such a displaced manner that the leading edge Pa of the succeeding folded sheet bundle P2 presses the trailing edge portion Pc of the preceding folded sheet bundle P1 from above without causing any failure such as getting stuck with the preceding folded sheet bundle P1.
Therefore, the frequency of jamming of the folded sheet bundle, improper stacking and bending of the sheet in the saddle-stitching bookbinding section 800 is low.
While the succeeding folded sheet bundle P2 is discharged, the first and the second conveyor belts 894, 895 rotate in such a direction as to convey the sheet bundle in the downstream direction. Consequently, the preceding and the succeeding folded sheet bundles p1, p2 are stacked in a displaced state in which the leading edge portion Pa of the succeeding folded sheet bundle P2 presses the trailing edge portion Pc of the preceding folded sheet bundle P1 against the folded bundle tray 890.
As shown in
As the number of the stacked bundle increases, the first folded sheet bundle P1 climbs up the inclined second stack surface 892 in the downstream direction with respect to the discharge direction. Since the folded sheet bundles P are conveyed with their folded portion being the leading edge, the open side trailing edge portion Pc thereof does not open or spread. Therefore, the folded sheet bundles moves on the second stack surface 892 in a stable state.
In addition, since the folded sheet bundles are guided upwardly by the second stack surface 892 that is inclined upwardly toward its downstream end, they cay be easily picked up by the user.
Furthermore, by putting the member providing the third stack surface 893 to accommodate it under the second stack surface 892 and placing a storage box 852 (
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2005-252901, filed Aug. 31, 2005, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2005-252901 | Aug 2005 | JP | national |
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