JP2010036995A - Image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming system for forming an image efficiently at a high speed while avoiding cost increase owing to inclusion of a sheet inversion mechanism for a long sheet, in the image forming system for printing on both surfaces. <P>SOLUTION: In the image forming system, a first image forming device 1a and a second image forming device 1b are aligned in a conveyance direction of a sheet in series. The sheet on which an image is formed in the first image forming device 1a at an upstream side is inverted and an inversion device 94 for conveying the sheet to the second image forming device 1b at a downstream side after the inversion is arranged between the first image forming device 1a and the second image forming device 1b. The inversion device 94 includes a receiving part 95 for receiving the sheet after forming an image on a surface and a storing part 95 equipped with a discharge part, continuing from the receiving part 95, for rolling and storing the sheet being passed through the receiving part and discharging the sheet after inverting a sheet image surface. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an image forming apparatus for forming images on both sides of a long sheet.

  In image forming apparatuses, in recent years, the demand for using long paper as an advertising medium is increasing year by year. In addition, from the viewpoint of effective use of resources, image formation on both the front and back sides of the sheet is also required.

In order to perform such image formation on both sides of the sheet at high speed, two printing apparatuses are arranged in series, one side is printed by the upstream printing apparatus, and the other side is printed by the downstream printing apparatus. Is configured to perform the print processing.
In this configuration, a paper discharge device is installed between printing devices arranged in series, and in the case of single-sided printing, when the single-sided printing is performed, the sheet is discharged by the paper discharge device. The processing capacity is secured.
In this case, as a configuration for double-sided printing, two printing apparatuses are dedicated to the front side and the back side, respectively, or a sheet reversing mechanism is not required, or a normal double-sided printing machine having a built-in sheet reversing mechanism is juxtaposed. Then, the sheet reversing mechanism is used or not. (For example, Patent Document 1)

JP-A-2005-022243

However, when two printing apparatuses are arranged in series, if each of the printing apparatuses is a dedicated machine for the front and back surfaces as described above, even if no sheet reversing mechanism is required, the cost of the entire system increases. .
On the other hand, even if a general-purpose machine is used, since the sheet reversing mechanism is built in each printing apparatus, the sheet reversing mechanism becomes large in the case of a long document, which also increases the cost. End up.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a reversing device capable of suppressing a space for a sheet reversing mechanism even when a long document is printed on both sides. In addition, it is an object of the present invention to provide an image forming system with high speed and excellent cost performance by incorporating such a reversing device.

  In order to achieve the above object, the present invention provides a receiving unit that receives a sheet after single-sided image formation, and a sheet that is provided continuously from the receiving unit and that passes through the receiving unit and stores the sheet. A reversing device is provided that includes a storage unit that includes a discharge unit that reverses the surface and discharges the sheet.

  In addition, the present invention is characterized by having a preventing means for preventing the sheet from entering the receiving portion when the sheet is reversed.

  The present invention further includes a reversing path for leading the sheet in a direction different from the receiving section, and a first sheet discharging section for discharging the sheet that has passed through the reversing path, the reversing path, and the first It is possible to select a paper discharge path leading to one paper discharge unit.

  Further, according to the present invention, a first arcuate guide that can be attached to and detached from the first paper discharge unit is provided, and the paper discharge path can be selected so as to guide a sheet after single-sided image formation to the first arcuate guide. It is characterized by that.

  The present invention is also characterized in that a plurality of image forming apparatuses for forming and discharging an image on a sheet are provided, and the image forming apparatuses are connected in series with the reversing apparatus interposed therebetween.

  The present invention also includes a plurality of image forming apparatuses that form and discharge an image on a sheet, and the image forming apparatuses are connected in series with the reversing apparatus interposed therebetween, and a paper jam occurs in the downstream image forming apparatus. If it occurs, the sheet that is being image-formed by the image forming apparatus on the upstream side is discharged to the first paper discharge unit.

  According to the present invention, a second paper discharge unit is provided in the image forming apparatus on the downstream side, and a second arcuate guide that can be attached to and detached from the second paper discharge unit is provided. The second arc guide is guided to the second arcuate guide.

  According to the present invention, since a space for reversal can be suppressed even for a long sheet, an apparatus excellent in cost performance can be provided.

The best mode for carrying out the present invention will be exemplarily described in detail below with reference to the drawings.
FIG. 1 is a schematic diagram of an image forming apparatus used in the present embodiment, FIG. 2 is a schematic diagram of an image forming system using the first embodiment, and FIG. 3 is an inversion in the first embodiment. FIG. 4 is a diagram for explaining the operation state of the reversing device in the first embodiment, FIG. 5 is a schematic diagram of an image forming system using the second embodiment, and FIG. 7 is a schematic diagram of a reversing device in the second embodiment, FIG. 7 is an explanatory diagram of an operation state of the reversing device in the second embodiment, FIG. 8 is a schematic diagram of an image forming system in the third embodiment, and FIG. Is a schematic diagram of an image forming system according to the fourth embodiment, FIG. 10 is a schematic diagram of an image forming system according to the fifth embodiment, and FIG. 11 is a schematic diagram of an image forming system according to the sixth embodiment. FIG. FIG. 12 is a schematic diagram of a reversing device according to the seventh embodiment.

  As shown in FIG. 1, in the image forming apparatus according to the present embodiment, an image forming unit 1 is disposed substantially at the center of the image forming apparatus, and a paper feeding unit 2 is disposed immediately below the image forming unit 1. The paper feed unit 2 includes a tandem paper feed tray 21 and a paper feed cassette 22. Additional paper feeders 26 and 27 can be added as necessary. Above the image forming unit 1, a reading unit 3 for reading a document is disposed. A paper discharge unit 4 is appropriately disposed on the left side of the image forming unit 1, and a recording medium (hereinafter referred to as a sheet) on which an image is formed is discharged and stored.

  In the reading unit 3, in order to perform reading scanning of a document (not shown) placed on the contact glass, a reading traveling body including a document illumination light source and a mirror reciprocates. Image information scanned by the reading traveling body is read as an image signal into a CCD installed behind the lens. The read image signal is digitized and subjected to image processing. Based on the image-processed signal, an electrostatic latent image is formed on the surface of the photosensitive member 61 by light emission of a laser diode LD (not shown) in the exposure device 7. The optical signal from the LD reaches the photoreceptor 61 via a known polygon mirror or lens. An automatic document feeder for automatically feeding a document onto the contact glass is attached above the reading unit 3.

In the image forming unit 1, four image forming units 6 are disposed around a belt-like intermediate transfer belt 5 for forming a color image.
In each image forming unit 6, a charging device 62 that charges the surface of the photosensitive member 61 around the drum-shaped photosensitive member 61, and an exposure device 7 that irradiates the surface of the photosensitive member 61 with image information with laser light. Two developing devices 63 for visualizing the electrostatic latent image formed on the surface of the photoconductor 61 and a cleaning device 64 for removing and collecting the remaining toner on the photoconductor 61 are disposed.

  In the sheet feeding unit 2, unused sheets are stored in the tandem sheet feeding tray 21 or the sheet feeding cassette 22, and the bottom plate supporting the sheet rises up to a position where the pickup roller can contact the uppermost sheet. . The uppermost sheet is fed out from the tandem sheet feeding tray 21 or the sheet feeding cassette 22 by the rotation of the sheet feeding roller and conveyed to the registration roller 23. The registration roller 23 is controlled so as to start rotation at a timing so that the conveyance of the sheet is temporarily stopped and the positional relationship between the toner image on the surface of the photosensitive member 61 and the leading edge of the sheet becomes a predetermined position.

The toner image is first formed in the yellow (Y) image forming unit, and the yellow (Y) toner is developed and transferred to the intermediate transfer belt 5. Next, the toner is developed and transferred to the intermediate transfer belt 5 in the order of cyan (C), magenta (M), and finally black (BK) image forming sections.
The four color toner images transferred onto the intermediate transfer belt 5 in this way are transferred to a sheet by the transfer device 51, and the toner remaining on the surface of the intermediate transfer belt 5 after the transfer is transferred by the intermediate transfer cleaning device 52. Removed and recovered.
Further, a fixing device 8 for fixing the toner on the sheet onto which the toner image has been transferred is disposed downstream of the sheet conveyance path. The sheet that has passed through the fixing device 8 is discharged from the discharge port 40 to the discharge unit 4 by the discharge roller 41 and stored.

  At the time of duplex printing, the sheet on which an image is formed on one side is branched from the direction of the paper discharge unit 4 by the branching claw 92 and conveyed toward the reversing unit 93, reversed by the reversing unit 93, and then fed again. Then, the registration roller 23 corrects the skew of the sheet, and the next image forming operation on the back surface is reached.

  The color image forming apparatus of the present embodiment scans and reads a document as described above, digitizes it, and copies it onto a sheet. This is a multifunctional image forming apparatus having a so-called printer function for printing on a sheet of facsimile information that is exchanged with a remote place and image information handled by a computer. A sheet on which an image is formed by any function is discharged and stored in the paper discharge unit 4.

In the present invention, two image forming apparatuses configured as described above are combined in series to form an image forming system for duplex printing.
First, in the first embodiment, as shown in FIG. 2, the first image forming apparatus 1a is disposed on the upstream side and the second image forming apparatus 1b is disposed on the downstream side in the sheet conveyance direction. Place.
A reversing device 94 that reverses and conveys the sheet from the first image forming apparatus 1a to the second image forming apparatus 1b is disposed between the image forming apparatuses 1a and 1b.
The reversing device 94 combines the paper discharge port 40 from which the paper discharge unit 4 of the first image forming apparatus 1a has been removed with the paper supply port 28 of the second image forming apparatus 1b, whereby the first image forming apparatus 1a is connected. The sheet is disposed so as to be reversed and conveyed from the image forming apparatus 1a to the second image forming apparatus 1b.
In the description of the present invention, as described above, it is defined from upstream to downstream along the sheet conveyance direction.

In order to perform double-sided printing, it is necessary to reverse the sheet. However, in the reversing unit 93 built in the first image forming apparatus 1a, the reversible sheet length is limited, so the sheet is long. If it exists, it cannot be reversed.
For this reason, in the present invention, in the case of a long sheet, the reversal disposed between the first image forming apparatus 1a and the second image forming apparatus 1b, not the reversing unit 93 in the first image forming apparatus 1a. The apparatus 94 is configured to invert the sheet.
As shown in FIG. 3, the reversing device 94 is provided continuously with a receiving portion 95-1 for receiving a sheet after single-sided image formation, and the receiving portion 95-1 downstream from the receiving portion 95-1. In addition, the sheet passing through the sheet is rolled and accommodated, and an arcuate accommodation part 95-2 having a discharge part 87 for inverting the sheet image surface and discharging the sheet is provided.
Further, driving rollers 96a and 96b for conveying sheets in the receiving portion 95-1 and driving rollers 96c and 96d for conveying sheets in the accommodating portion 95-2 are provided. Of the four drive rollers a, b, c, and d, one drive roller 96a on the upstream side has a driven roller so that the paper is nipped and conveyed by the driven roller while rotating clockwise. However, the three downstream drive rollers 96b, c, and d do not have driven rollers, and are configured to be capable of reverse driving.
Further, on the sheet carry-in path in the reversing device 94, conveyance rollers 83 and 84 that carry the sheet from the sheet carry-in port 80 and convey it to the receiving unit 95-1 are arranged. A sheet detecting means 85 for detecting the leading end portion and the trailing end portion is provided between the conveying rollers 83 and 84.
Further, on the downstream sheet discharge path in the reversing device 94, a conveyance roller 82 for discharging the sheet from the discharge port 81 to the second image forming apparatus 1b, and a discharge roller 87 to the discharge roller 82 are provided. A paper guide 86 for guiding the sheet is disposed.

The accommodating portion 95-2 is generally formed in an arc shape so as to constitute an approximately cylindrical internal space having a diameter of 90 to 180 mm.
Further, as shown in FIG. 3, the accommodating portion 95-2 is configured to accommodate the sheet conveyed from the receiving portion 95-1 while being rolled counterclockwise in the internal space. Accordingly, the image forming surface is stored outside in the space.
Further, a step is formed between the upstream end of the storage portion 95-2 and the downstream end of the receiving portion 95-1, and the step serves as a sheet discharge portion 87.
The upstream end of the sheet guide 86 is disposed in the space in the discharge unit 87, and the leading end of the sheet conveyed to the discharge unit 87 is not allowed to enter the receiving unit 95-1. It is configured to guide in the direction of the carry-out roller 82.

When a document to be used for image formation is long and double-sided printing is required, the manual paper feed unit 27 provided with the first image forming apparatus 1a or the first image forming apparatus 1a is provided. A long sheet is selected from a roll paper cassette or the like (not shown) attached to the sheet, supplied to the image forming unit of the first image forming apparatus 1a, and image formation is performed on one side of the sheet as described above.
Next, the long sheet on which the image is formed on one side in this way is reversed from the paper discharge port 40 of the first image forming apparatus 1a without being sent to the reversing unit 93 built in the first image forming apparatus 1a. Derived to device 94.

As shown in FIGS. 3 and 4, the long sheet P <b> 1 led out to the reversing device 94 is transported in the direction of the receiving unit 95-1 by the transport rollers 83 and 84 through the transport path.
When the leading edge of the long sheet P1 is detected by the paper detection means 85, the drive rollers 96a, b, c, d are configured to start rotating at a constant speed in the clockwise direction. While receiving the driving force by the driving rollers 96a, 96b, 96d, the guide roller 95a guides the receiving space 95-1 to the cylindrical space in the housing portion 95-2.
At this time, the downstream driving rollers 96b, c, d are not provided with a driven roller, but the long sheet P1 has the driving rollers 96b, c, d due to the so-called waist of the sheet itself. As shown in FIG. 4 (1), it is guided to be rounded into the cylindrical space of the accommodating portion 95-2. At this time, the single-sided image-formed sheet is accommodated in the space with the image forming surface facing the driving roller.
As described above, when the paper is conveyed by the waist of the paper, the setting of the diameter of the cylindrical shape formed by the accommodating portion 95-2 is important. In the present embodiment, as described above, when the basis weight is 52.3 to 280 g / square meter and the diameter is set to 90 to 180 mm, appropriate conveyance can be performed.

The drive rollers 96b, c, d are configured to be driven to rotate in the counterclockwise direction when the long sheet P1 is curled and stored in the space and the rear end thereof exceeds the discharge portion 87. ing.
This reversal drive is performed after a lapse of time corresponding to the time when the trailing edge exceeds the discharge section 87 after the sheet detection means 85 detects the trailing edge of the long sheet P1, but separately includes a storage section 95- It is also possible to install a sheet detection means for detecting the trailing edge of the sheet in the vicinity of the downstream portion 2 and to perform the detection based on the detection signal. As described above, those skilled in the art can appropriately employ the configuration for controlling the sheet feeding of the driving rollers 96a, 96b, 96c, and 96d.

Thus, when the drive rollers 96b, c, d are driven in reverse, the rear end portion of the long sheet P1 becomes the front end portion and is once conveyed toward the upstream side. However, when the tip portion is conveyed to the space of the discharge portion 87, as shown in FIG. 4 (2), the paper guide 86 located in the space does not enter the receiving portion 95-1, and the unloading path. It is guided in the direction of the transport roller 82 (that is, downstream side). This sheet guide 86 constitutes a preventing means for preventing the sheet from entering the receiving portion 95-1 when the sheet is reversed. And by this switchback operation, the front and back of the long sheet P1 are reversed in the reversing device 94.
After the long sheet P1 is reversed in the reversing device 94 as described above, the long sheet P1 is conveyed from the sheet carry-out port 81 to the second image forming apparatus 1b via the carry-out path.

Since the long sheet P1 conveyed to the paper feed port 28 of the second image forming apparatus 1b has already been turned upside down, the image forming unit of the second image forming apparatus 1b can form an image as usual. By doing so, double-sided printing is completed.
The long sheet P1 for which double-sided printing has been completed in this manner is discharged to an appropriate discharge portion instructed by the operator of the discharge device 42, and the operation is completed.

  Usually, when a toner image is transferred to a sheet, and the toner image is fixed and dried, curling occurs on the image forming surface side. However, according to the reversing device 94 in the first embodiment, when the long sheet P1 accommodated in the accommodating portion 95-2 is discharged, the leading end portion and the trailing end portion in the conveyance direction of the sheet are not accommodated in the accommodating portion 95-2. Since the image forming surface is accommodated in the portion 95-2, the upward curl in FIG. 2 is given. Therefore, the long sheet P1 provided with the upward curl in this way is provided with the curl in the same direction as the curvature direction of the intermediate transfer belt 5 in the transfer portion of the second image forming apparatus 1b on the downstream side. Therefore, the adhesion with the intermediate transfer belt 5 on the downstream side can be improved.

  In the case of coated paper, there is a possibility of curling downward depending on conditions such as humidity. Therefore, a curl correction unit that curls the sheet upward may be provided in the carry-out path downstream of the discharge unit 87.

  On the other hand, according to the first embodiment, the sheet accommodated in the accommodating portion 95-2 is in contact with the guide surface of the accommodating portion 95-2 and the driving roller 96 on the image forming surface side. If the curvature of 95-2 is set to be large, the image surface may be rubbed by them. For this reason, it is preferable that the curvature of the accommodating portion 95-2 is a curvature that does not affect the image.

  According to the first embodiment, a reversing device that can perform a reversing operation even for a long sheet, can reduce a space required for sheet reversal, and improves transfer efficiency in the downstream image forming apparatus 1b. Can be provided. Furthermore, since a general-purpose machine can be used as the image forming apparatus, an image forming system with excellent cost performance can be provided.

  In the first embodiment described above, rubbing or the like may occur on the image forming surface of the sheet. Therefore, in the second embodiment, in order to prevent such rubbing or the like of the image forming surface. Composed.

In the second embodiment, as shown in FIG. 5, a reversing device 94 ′ is arranged in place of the reversing device 94 in the first embodiment.
As shown in FIG. 6, in the reversing device 94 ′, conveying rollers 83 ′ and 84 ′ are arranged in a carry-in path continuing to the sheet carry-in port 80 ′, and a sheet is placed in a lower storage portion 95′-2 downstream thereof. A receiving portion 95′-1 for guiding is arranged.
And, at the downstream end of the receiving part 95′-1, a synthetic resin elastic sheet M extends in a direction transverse to the sheet and is installed at an angle inclined in the downstream direction. When the leading end of the sheet is conveyed in the downstream direction and abuts against the elastic sheet M, the elastic sheet M receives the pressing force and is easily bent so that the abutting portion is parallel to the sheet conveyance direction. Yes. On the other hand, when the leading end of the sheet tries to enter the receiving portion 95′-1 from the downstream side, the elastic sheet M is set at an inclination angle that does not bend even if it receives a pressing force that comes into contact. It is configured to prevent the entry. As described above, the elastic sheet M constitutes a preventing means for preventing the leading end of the sheet from entering the receiving portion 95′-1 when the sheet is reversed.
Reference numeral 85 ′ denotes a sheet detecting unit similar to that in the first embodiment.

Further, a driving roller 97 having a driven roller is disposed below the carry-in path, and further, driving rollers 96e, f, g, h without a driven roller are arranged in an arcuate housing portion 95 ′. -Arranged in order clockwise along 2. These drive rollers 97, 96e, f, g, and h are all configured to be capable of reverse driving.
As shown in FIG. 6, the accommodating portion 95′-2 is formed in an arc shape so that a cylindrical space portion is formed inside the arc, and the drive rollers 96e, f, g, h are It arrange | positions so that a part of roller may be exposed in this space part.
Above the storage portion 95′-2, a discharge portion 87 ′ that discharges the sheet downstream is provided, and a carry-out path that continues from the discharge portion to the sheet discharge port 81 ′ is provided. A transport roller 82 'is disposed along the carry-out path.

In the second embodiment, the long sheet is reversed as follows.
As shown in FIGS. 6 and 7, the long sheet P2 having an image formed on one side is carried into the reversing device 94 ′ from the paper carry-in port 80 ′ with the image forming surface facing up.
When the long sheet P2 is carried into the reversing device 94 ′, the long sheet P2 is conveyed downward by the conveying rollers 83 ′ and 84 ′ and the receiving unit 95′-1, and the leading end of the sheet is formed on the elastic sheet M described above. It is conveyed in the direction of the driving roller 97 without being obstructed by the path.
Subsequently, the long sheet P2 is driven by the drive rollers 96e, f, g, and h that rotate counterclockwise in the cylindrical space formed in the arcuate accommodating portion 95′-2. While being conveyed, as shown in FIG. 7 (1), it is wound clockwise. Therefore, the image forming surface of the long sheet P2 does not come into contact with the inner wall of the accommodating portion 95′-2 and the driving rollers 96e, f, g, h.
The drive rollers 97 and 96e, f, g, and h are temporarily stopped and then rotated in the clockwise direction at a timing when the rear end portion of the long sheet P2 passes through the elastic sheet M. As a result, the rear end portion of the long sheet P <b> 2 becomes a front end portion and is once transported upward (upstream side) and comes into contact with the elastic sheet M. At this time, as shown in FIG. 7 (2), since the elastic sheet M prevents the sheet from entering the receiving portion 95′-1, the leading end of the long sheet P2 is discharged by the elastic sheet M. Guided in the direction of the downstream delivery path via the portion 87 '. Therefore, the long sheet P2 is reversed in the reversing device 94 ′.
After the long sheet P2 is reversed in the reversing device 94 ′ as described above, the long sheet P2 is conveyed from the sheet carry-out port 81 ′ to the second image forming device 1b through the carry-out path while the image forming surface is the lower surface.
In the second embodiment, contrary to the first embodiment, a downward curl is generated in the sheet discharged from the accommodating portion 95′-2. Therefore, a curl correction unit that imparts an upward curl to the inverted sheet may be provided in the carry-out path from the discharge unit to the sheet carry-out port 81 ′.

 In the second embodiment, the image forming surface of the long sheet P2 does not come into contact with the accommodating portion 95′-2 and the drive rollers 96e, f, g, h inside the reversing device 94 ′. Therefore, there is no possibility that a guide trace by the paper guide 95 ′ or a roller trace by the drive rollers 96e, f, g, h will occur.

In the above-described embodiment, when an image is formed on only one side of a sheet, the sheet is discharged downstream of the second image forming apparatus 1b. The second image forming apparatus 1b This is merely an operation of passing the sheet, and is not efficient as an image forming system.
In the third embodiment, in order to improve such inefficiency, as shown in FIG. 8, the first paper discharge unit 43 is provided on the upper part of the reversing device 94 ′ similar to that in the second embodiment. And a branching section 98 for discharging the single-side printed sheet to the first paper discharge section 43.
The branching portion 98 is provided downstream of the conveying roller 84 or 84 ′, and guides a sheet on which an image has been formed toward the upper first paper discharge portion 43 in the case of single-sided printing, and in the case of double-sided printing. Is configured so that a selective operation can be performed so as to guide the sheet printed on one side toward the reversing means below.
The second image forming apparatus 1b downstream is configured to perform another image formation while performing single-sided printing.

  According to the third embodiment, when performing single-sided printing, image formation is performed only by the first image forming apparatus 1a on the upstream side, and the image-formed sheet is transferred to the second image forming apparatus 1b. The sheet is immediately discharged without being sent, and while the first image forming apparatus 1a is forming an image, the second image forming apparatus 1b can separately form an image. It can be a system.

In the third embodiment, the first paper discharge unit 43 provided on the upper portion of the reversing device 94 ′ does not have a sufficient space for discharging the long one-side printed material. When the scale-like printed matter is discharged, the sheet may be deformed.
In the fourth embodiment, in order to prevent such deformation of the long sheet accompanying the discharge, a long sheet discharge unit 45 is detachably attached to the upper portion of the first discharge unit 43. Is provided.
As shown in FIG. 9, the long sheet discharge section 45 has a storage cassette (first arcuate guide) 44 at the top, and the first arcuate guide 44 is a long sheet. It has a cylindrical internal space in which the sheet can be rolled up and stored. The first arcuate guide 44 is open on the side so that the sheet can be taken out from the side.
Further, a second branch part 99 is provided downstream of the branch part 98 described above, and it is determined whether the sheet is conveyed to the first sheet discharge part 43 or the sheet discharge part 45 for long sheets. It is configured so that it can be selected.

When the sheet that is printed on one side and discharged is a long sheet, the long sheet is conveyed upward from the branching section 98 as shown in FIG. 9, and is further elongated by the second branching section 99. The sheet is conveyed in the direction of the sheet discharge unit 45. The long sheet conveyed in this way is finally rolled into a cylindrical shape in the first arcuate guide 44 and discharged, so that it does not fold or deform.
The long sheet discharged in this way can be taken out from the open surface of the side portion of the first arcuate guide 44.
When a long sheet is not used, a sheet discharge table 44 ′ having a normal straight tray is placed in place of the long sheet discharge unit 45, which is the same as that in the case of single-sided printing. It can be used as a second paper discharge unit.

In the above embodiment, when a paper jam occurs in the second image forming apparatus 1b on the downstream side and image formation cannot be performed, the entire system is stopped.
However, since it is possible to operate the first image forming apparatus 1a on the upstream side, if the entire system is stopped in this way, the system becomes inefficient.
The fifth embodiment has been made to improve such inefficiency.

In the fifth embodiment, as shown in FIG. 10, even when a paper jam or the like occurs in the second image forming apparatus 1b on the downstream side and the operation of the second image forming apparatus 1b is interrupted. The first image forming apparatus 1a on the upstream side does not interrupt the image formation, and the sheet that is being image-formed by the first image forming apparatus 1a has the branching section 98 and the first one after the subsequent image formation is completed. The two-branching unit 99 is activated, and the sheet is discharged to either the first sheet discharge unit 43 or the long sheet discharge unit 45, that is, the first arcuate guide 44 (or the sheet discharge table 44 '). It is configured to be.
Then, the first image forming apparatus 1a is continuously operated so that another job is performed.
Similarly, even when the operation of the first image forming apparatus 1a is interrupted, it is possible to continue the job separately without interrupting the operation of the normally operating second image forming apparatus 1b. You can also.

  As described above, in the fifth embodiment, even when one of the image forming apparatuses is interrupted due to a paper jam or the like, the other system can be operated efficiently by operating the other image forming apparatus. Can do.

In the sixth embodiment, as shown in FIG. 11, the second paper discharge unit 42 of the second image forming apparatus 1b on the downstream side is used for discharging a long sheet printed on both sides. Is provided with a second long sheet discharge unit 47 configured in the same manner as the long sheet discharge unit 45 described above. A second arcuate guide 46 configured in the same manner as the first arcuate guide 44 is detachably mounted on the second long sheet discharge unit 47.
And in the case of a long sheet, the 3rd branch part 100 which switches a conveyance path to the 2nd long sheet discharge part 47 side is provided.
Accordingly, when a long sheet printed on both sides is conveyed, the conveyance path is switched to the second long sheet discharge unit 47 side by the third branching unit 100, and the long sheet is the second sheet. The circular arc guide 46 is rolled and stored and discharged.

  With this configuration, the long sheet printed on both sides is rolled into a cylindrical shape in the second arcuate guide 46 and discharged, so that it is possible to prevent deformation such as folds and wrinkles during paper discharge. it can.

Next, in the seventh embodiment, as shown in FIG. 12, an accommodating portion 95 ′ similar to that in the second embodiment is placed in the reversing device 94 ″ with the carry-in route interposed therebetween. And the curling direction of the sheet discharged from the accommodating portion 95 ′ is reversed, and the upper and lower accommodating portions 95 ′ can be selected.
For this reason, a branching claw 101 is provided for distributing the sheet introduced into the reversing device 94 '' to each storage unit 95 ', and the arcuate direction of the upper and lower storage units 95' is determined by the curl direction of the sheet. Arrange them so that they are opposite to each other.

In this embodiment, the upper and lower storage units are configured so that the curl directions are reversed. Therefore, in the case shown in FIG. 12, for example, when the image surface is rubbed, an operation unit (not shown) is used. By setting the mode, the branching claw 101 is operated so as to store the sheet in the lower storage portion. Conversely, when priority is given to improving the adhesion of the sheet to the intermediate transfer belt, the branching claw 101 is operated so as to be accommodated in the upper accommodating portion.
Thus, in the seventh embodiment, it is possible to make a selection according to the priority of the user regarding the curl direction of the sheet.
Note that the sheets discharged from the storage units merge and are sent to the downstream image forming apparatus, but a curl correction unit that curls the sheet upward may be provided in the middle of the carry-out path.
In consideration of the rubbing of the image surface, the curvature of the upper accommodating portion may be made smaller than the curvature of the lower side.
Further, in the example shown in FIG. 12, the configuration of the accommodating portion 95 ′ and the means for preventing the entry of the seat is the same as that of the accommodating portion in the second embodiment described above, but is not limited thereto. Alternatively, the accommodation portion 95 and the means for preventing the entry of the sheet in the first embodiment may be used as long as the curling directions on the lower side and the upper side are reversed.

In the third to sixth embodiments, the configuration using the inverting device 95 ′ in the second embodiment is shown. However, the present invention is not limited to this, and the first embodiment is not limited thereto. The reversing device 95 according to the embodiment and the reversing device 95 ″ according to the seventh embodiment may be used as appropriate.
Similarly, regarding the reversing device, as means for preventing sheet entry in each embodiment, means for preventing sheet entry in the first and second embodiments may be employed.

  The present invention is provided continuously from the receiving portion for receiving a sheet after single-sided image formation, and stores the sheet that has passed through the receiving portion by curling and reversing the sheet image surface and discharging the sheet. Since the reversing device is provided with a storage unit including a discharge unit, even a long sheet does not cause physical damage such as folds and wrinkles, and the space for reversal can be suppressed. A reversing device with excellent performance can be provided. Further, it is possible to prevent rubbing or the like on the image forming surface, or to improve transfer efficiency in subsequent image formation.

  Further, the reversing device of the present invention has a preventing means for preventing the sheet from entering the receiving portion when the sheet is reversed, thereby preventing the reverse feeding of the sheet in the reversing device and ensuring the reversal of the sheet. be able to.

  Further, the reversing device of the present invention includes a reversing path that leads out a sheet in a direction different from the receiving section, and a first paper discharge section that discharges the sheet that has passed through the reversing path, and the reversing path. In addition, by making it possible to select the paper discharge path led out to the first paper discharge unit, it is possible to provide a reversing device that can handle both paper that requires reversal and paper that does not require reversal.

  In the reversing device of the present invention, a first arcuate guide that can be attached to and detached from the first paper ejection unit is provided, and the paper ejected so as to guide the sheet after single-sided image formation to the first arcuate guide. By making the path selectable, it is possible to provide a reversing device that can handle both long papers that require reversal and long papers that do not require reversal. In either case, the long sheet can be prevented from being physically damaged, such as folds or wrinkles, and the space for storage or reversal can be suppressed, so that a reversing device with excellent cost performance can be provided. it can.

  The image forming system according to the present invention includes a plurality of image forming apparatuses that form and discharge an image on a sheet, and the image forming apparatuses are connected in series with the reversing apparatus interposed therebetween, so that the image forming apparatus can be used as a general-purpose image forming apparatus. Therefore, an image forming system with excellent cost performance can be provided.

  The image forming system according to the present invention includes a plurality of image forming apparatuses that form and discharge an image on a sheet, and the image forming apparatuses are connected in series with the reversing apparatus interposed therebetween, and the downstream side image forming apparatus is formed. When a paper jam occurs in the apparatus, a sheet that is being image-formed by the upstream image forming apparatus is discharged to the first paper discharge unit, so that one of the image forming apparatuses operates due to a paper jam or the like. Even when the operation is interrupted, the entire system can be efficiently operated by operating the other image forming apparatus.

  Furthermore, the image forming system of the present invention is provided with a second paper discharge unit in the downstream image forming apparatus and a second arcuate guide that can be attached to and detached from the second paper discharge unit. By guiding the formed sheet to the second arcuate guide, the long sheet printed on both sides is rolled into a cylindrical shape and discharged into the second arcuate guide. Space, and deformation such as folds and wrinkles during paper discharge can be prevented.

Schematic diagram of an image forming apparatus used in the present embodiment Schematic diagram of an image forming system using the first embodiment Schematic of the reversing device in the first embodiment Explanatory drawing of the operating state of the reversing device in the first embodiment Schematic diagram of an image forming system using the second embodiment Schematic of the reversing device in the second embodiment Explanatory drawing of the operating state of the reversing device in the second embodiment Schematic diagram of an image forming system according to the third embodiment Schematic diagram of an image forming system according to the fourth embodiment Schematic diagram of an image forming system in the fifth embodiment Schematic of an image forming system in the sixth embodiment Schematic of the reversing device in the seventh embodiment

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 a 1st image forming apparatus 1 b 2nd image forming apparatus 1 Image forming part 2 Paper feed part 3 Document reading part 4 Paper discharge part 5 Intermediate transfer belt 6 Image forming part 7 Exposure apparatus 8 Fixing apparatus 28 Paper feed port 40 Paper discharge port 42 Second paper discharge section 43 First paper discharge section 44 First arcuate guide 44 'Paper discharge tray 45 Long sheet discharge part 46 Second arcuate guide 47 Long sheet discharge unit 51 Transfer device 61 Photoconductor 63 Developing device
80 sheet carry-in port 81 sheet discharge port 82, 83, 84 conveying roller 85 sheet detection means 86 paper guide 87, 87 ′ discharge unit 92 branch claw 93 reversing unit 94, 94 ′ 94 ″ reversing device 95-1, 95 ′- 1 Receiving part 95-2, 95'-2 receiving part
96a, b, c, d, e, f, g, h Driving roller 97 Driving roller 98 Branching part 99 Second branching part 100 Third branching part 101 Branching claw M Elastic sheet

Claims (7)

  A receiving portion that receives a sheet after single-sided image formation, and a discharge portion that is provided continuously from the receiving portion, stores the sheet that has passed through the receiving portion in a rounded manner, and reverses the sheet image surface to discharge the sheet. A reversing device.   The reversing device according to claim 1, further comprising a preventing unit that prevents a sheet from entering the receiving portion when the sheet is reversed.   A reversing path for deriving a sheet in a direction different from the receiving section; and a first sheet discharging section for discharging the sheet that has passed through the reversing path, the reversing path, and the first sheet discharging section. The reversing device according to claim 1, wherein a paper discharge path to be led out is selectable.   A detachable first arcuate guide is provided in the first sheet discharge unit, and the sheet discharge path can be selected so as to guide a sheet after single-sided image formation to the first arcuate guide. The reversing device according to claim 3.   5. The image according to claim 1, comprising a plurality of image forming apparatuses that form and discharge an image on a sheet, and the image forming apparatuses are connected in series with the reversing apparatus interposed therebetween. Forming system.   A plurality of image forming apparatuses that form and discharge an image on a sheet, the image forming apparatuses are connected in series with the reversing apparatus interposed therebetween, and a paper jam occurs in the downstream image forming apparatus; 5. The image forming system according to claim 3, wherein a sheet being image-formed by the image forming apparatus on the side is discharged to the first paper discharge unit.   The image forming apparatus on the downstream side is provided with a second paper discharge unit, and a second arcuate guide that can be attached to and detached from the second paper discharge unit is provided so that the sheet after double-sided image formation is formed on the second circle. The image forming system according to claim 5, wherein the image forming system is led to an arc guide.

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