Patent Grant
9958820
This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No.
2015-027422, filed Feb. 16, 2015, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to an image forming apparatus and a winding-deviation prevention method.
2. Description of the Related Art
Conventionally, there is an electrophotographic image forming apparatus. In this image forming apparatus, generally, the photosensitive drums of a development device are equally electrified and initialized, and latent images are formed on the photosensitive drums by optical writing and developed to toner images. Then, the toner images are directly or indirectly transferred onto a print target medium and fixed by a fuser.
In this image forming apparatus, when being rolled up after printing, paper (roll paper) ejected by a face-down method is reversed by a front/back reversing unit installed on the lower side of the paper ejection flow of the printer and then ejected face up. Subsequently, a tip end of the ejected paper is placed on the winding shaft of a rewinder, and then a rolling-up operation is started.
However, when the roll paper is to be rolled up, it is difficult to roll up the roll paper with both edges aligned without looseness, and therefore methods for rolling up roll paper with both edges aligned have been proposed. For example, Japanese Patent Application Laid-Open (Kokai) Publication No. 2008-074051 proposes a technique of rolling up by repeating a procedure in which a step roller (tension roller) is used to form slack of paper by self weight of the roller before rolling up, the rolling-up operation is stopped before the slack disappears, and then slack is formed again.
This technique can be relatively easily achieved, but there is a problem in that a space for providing a sensor and the step roller for continuously forming slack is required. In addition, there is a problem in that operations of keeping the rolling-up accuracy (with both edges aligned) high and achieving rolling up without looseness are easily affected by the positional accuracy of each section.
In another conventional known technique, for example, flanges (guides) conforming to the width of paper are arranged on a winding shaft, and the paper is accommodated between the guides by the guides being rotated along with the rotation of the winding shaft. However, in this conventional technique, there is a problem in that the positions of the flanges are required to be moved for a different paper width, which makes the structure complicated. In addition, there is a problem in that, when the paper is not accurately conveyed to the winding shaft, the edges of the paper are damaged by being forcibly accommodated between the guides.
In still another conventional technique, for example, fixed guides conforming to the width of paper are provided in an area on the upper side of a rolling-up flow, and the paper is positioned by being inserted therebetween and wrapped around a roll-up shaft. However, in this conventional technique, there is a problem in that unevenness occurs when an operator adjusts the guides to correspond to the paper width. In addition, a problem occurs depending on the positional accuracy of the paper. That is, when the paper is sent at a tilt with respect to the roll-up shaft, its position cannot be kept by the guides, and the rolling-up operation cannot be performed stably.
In yet another conventional technique, for example, an actuator is arranged on a roll-up shaft, an end of paper is detected by a position sensor or the like before the paper is rolled up, and the roll-up shaft is controlled such that the end of the paper is aligned, whereby the rolling-up operation is performed stably. However, in this conventional technique, there is a problem in that, since the roll diameter changes in the course of rolling up the paper into a roll shape, the sensor arrangement, the sensor type, and the structure become complicated to conform thereto, which extremely increases the cost.
In accordance with one aspect of the present invention, there is provided an image forming apparatus comprising: a roller which conveys a print target medium ejected from an apparatus main body; and a support section which rotatably supports the roller in accordance with tension applied to the roller via the print target medium from a direction of a winding shaft arranged in a lower flow in a conveyance direction.
In accordance with another aspect of the present invention, there is provided a winding-deviation prevention method comprising: a step of preventing winding-deviation of a print target medium ejected from an image forming apparatus with respect to a winding shaft arranged on a lower flow side of a conveyance route, by rotating a support section for supporting a roller which changes a conveyance direction of the print target medium to a direction of the winding shaft in accordance with tension applied via the print target medium from a direction of the winding shaft.
The above and further objects and novel features of the present invention will more fully appear from the following detailed description when the same is read in conjunction with the accompanying drawings. It is to be expressly understood, however, that the drawings are for the purpose of illustration only and are not intended as a definition of the limits of the invention.
The present invention can be more deeply understood by the detailed description below being considered together with the following drawings.
Embodiments of the present invention will hereinafter be described with reference to the drawings.
Paper feed rollers 22 in
The printer body 30, which is an electrophotographic, intermediate transfer, and tandem type color image forming device, is constituted by a drum/development device 31, a transfer belt device 32, toner cartridges 33, electric equipment sections 34, a paper feeding section 35, a fixing device 36, etc.
The toner cartridges 33 are arranged above the transfer belt device 32, and the drum/development device 31 (hereinafter referred to as “development device 31”) is arranged substantially directly under the transfer belt device 32. The transfer belt device 32 includes an intermediate transfer belt 37, driving rollers 38, and a follower roller 39. The development device 31 is structured such that four development devices 31k, 31c, 31m, and 31y are arranged side-by-side in multiple stages from right to left in the drawing and come in contact with the lower driving surface of the intermediate transfer belt 37 of the transfer belt device 32.
The toner of black (K), cyan (C), magenta (M), and yellow (Y) shown in the drawing as K, C, M, and Y are supplied to these development devices 31k, 31c, 31m, and 31y, respectively, from the four toner cartridges 33.
The four toner cartridges 33 are arranged above the upper running surface of the intermediate transfer belt 37, in which the toner of black (K), cyan (C), magenta (M), and yellow (Y) to be supplied are accommodated, respectively. In areas between the toner cartridges 33 and the development device 31, toner vertical conveyance paths 40 are arranged, respectively, and a fixed amount of toner is conveyed into the development device 31 from each toner cartridge 33.
Among these development devices 31k, 31c, 31m, and 31y, three development devices 31c, 31m, and 31y on the upper flow side (the left-hand side in the drawing) form color images on the intermediate transfer belt 37 by using the color toner of cyan (C), magenta (M), and yellow (Y) which are the three primary colors of subtractive color mixing. The development device 31k forms a monochrome image on the intermediate transfer belt 37 by using the color toner of black (K) which is mainly used for characters, dark portions of images, etc.
The transfer belt device 32 includes the endless intermediate transfer belt 37 positioned in a substantially center area in the printer body 30 and having a flat loop shape extending in the horizontal direction of the drawing, and the driving rollers 38 and the follower roller 39 around which the intermediate transfer belt 37 is wrapped and circularly moved in the counterclockwise direction in the drawing.
The transfer belt device 32 also includes a secondary transfer backup roller 41 which is positioned above the driving rollers 38 and around which the intermediate transfer belt 37 is wrapped. This secondary transfer backup roller 41 comes in pressure contact with a secondary transfer roller 42 via the intermediate transfer belt 37.
The print target medium 21a, which is conveyed to the printer body 30, comes in pressure contact with the intermediate transfer belt 37 when it is conveyed between the secondary transfer backup roller 41 and the secondary transfer roller 42. As a result, monocolor images formed on the intermediate transfer belt 37 by use of the color toner of cyan (C), magenta (M), and yellow (Y), and a monochrome image formed thereon by use of the toner of black (K) are sequentially transferred onto the print target medium 21a that is roll paper, and supplied to the fixing device 36.
Also, the paper feeding section 35 includes a paper feed cassette having flat paper placed therein. The flat paper (including paper having a bag-like shape such as an envelope) in the paper feed cassette is conveyed to the secondary transfer backup roller 41 and the secondary transfer roller 42 through conveyance rollers 44, as in the case of roll paper. Then, monocolor images formed on the intermediate transfer belt 37 by use of the color toner of cyan (C), magenta (M), and yellow (Y), and a monochrome image formed thereon by use of the toner of black (K) are sequentially transferred onto the print target medium 21a that is flat paper, and supplied to the fixing device 36.
The fixing device 36 fuses a toner image transferred onto the print target medium 21a that is roll paper or flat paper. Roll paper conveyed from the fixing device 36 is wrapped around a winding shaft 51 installed in the roll paper rolling section 50 via a pair of conveyer rolls not shown and a front/back reversing unit 45 (winding-deviation prevention unit). On the other hand, flat paper conveyed from the fixing device 36 is ejected face down via the conveyer rolls not shown to a paper output tray 46 arranged on the upper surface of the printer body 30.
Prior to a printing operation, roll paper that serves as the print target medium 21a is set on the winding shaft 51. The print target medium 21a, which is roll paper, is pulled from the paper feed roll 21 of the roll paper feeding section 20, supplied to the printer body 30, conveyed through a conveyance path depicted in
The operator manually fixes a tip end portion of the print target medium 21a ejected from the front/back reversing unit 45 to the winding shaft 51 on the lower flow side. The print target medium 21a is normally set to the winding shaft 51 by the tip end portion of the print target medium 21a sent from the printer body 30 being attached to the winding shaft 51 with a tape or the like. However, in some cases, the print target medium 21a is attached during an operation. Also, there is a case where a rolling-up operation is started after paper conveyance is once stopped and the tip end portion of the print target medium 21a is attached.
The roll paper rolling section 50 has a drive section which rotates the winding shaft 51, and the print target medium 21a is wrapped around the winding shaft 51 with appropriate tension. That is, a clutch mechanism is provided in the drive section of the roll paper rolling section 50 so that setting where the print target medium 21a ejected from the printer body 30 is forcibly pulled up is not made, whereby the roll paper rolling section 50 always rolls up the print target medium 21a with appropriate tension.
Here, since the operation of attaching the tip end portion of the print target medium 21a to the winding shaft 51 is manually performed by the operator, attachment accuracy may be degraded. For example, the print target medium 21a may not be attached straight. In this case, the tension applied to the print target medium 21a to be wrapped around the winding shaft 51 becomes nonuniform (unbalanced) in the lateral direction (paper width direction), whereby the print target medium 21a is rolled up obliquely.
In the present embodiment, means capable of always ensuring a stable rolling-up state is provided. Specifically, the attachment of the front/back reversing unit 45 to the printer body 30 is not fixed, and the front/back reversing unit 45 is structured to be rotatable around the position of attachment to the printer body 30 in accordance with the tension of the print target medium 21a to be wrapped around the winding shaft 51. By the front/back reversing unit 45 being structured to be rotatable as described above, the tension occurring simultaneously with the start of the rotation of the winding shaft 51 is prevented from becoming nonuniform (unbalanced) in the lateral direction (paper width direction) of the print target medium 21a. Also, when the tension applied in the lateral direction (paper width direction) of the print target medium 21a becomes balanced, the front/back reversing unit 45 (including a roller 61 described below which is opposed to the winding shaft 51) is automatically returned to a substantially parallel position with respect to the winding shaft 51. As a result, the roller 61 (described below) of the front/back reversing unit 45 and the winding shaft 51 are automatically adjusted such that they constantly keep parallelism even if the tension applied in the lateral direction (paper width direction) of the print target medium 21a becomes nonuniform (unbalanced).
The roller 60 reverses the print target medium 21a ejected from the printer body 30, and the roller 61 changes the conveyance direction thereof such that the reversed print target medium 21a is ejected to the roll paper rolling section 50 side. The base metal sheet 63 of the front/back reversing unit 45 has the side plates 63-1 and 63-2 fixed thereon which support the rollers 60 and 61. This base metal sheet 63 is engaged with a rotation spindle 64 fixed to the fitting 62 such that it is rotatable in a horizontal direction. The fitting 62 is fixed to the printer body 30. This fitting 62 and the base metal sheet 63 are engaged with each other at the rotation spindle 64 such that they are spaced by about 0.5 mm via a spacer. That is, the front/back reversing unit 45 includes a support section where the side plates 63-1 and 63-2 which support the rollers 60 and 61 are fixed to the base metal sheet 63, which is rotatably engaged with the rotation spindle 64.
As described above, by the base metal sheet 63 being fixed to the fitting 62 via the rotation spindle 64 such that it is rotatable in a horizontal direction, the front/back reversing unit 45 can rotate in a direction following a direction where winding tension occurs. Also, the fitting 62 and the base metal sheet 63 are engaged with each other by the elastic member 65. The elastic member 65 is a member having restoring force, such as a spring or rubber, and applies force to return the base metal sheet 63 rotated around the rotation spindle 64 to its original position. The original position herein is a position allowing the front/back reversing unit 45 rotated in the horizontal direction to be returned such that the roller 61 and the winding shaft 51 are parallel to each other.
Therefore, skew of the print target medium 21a to be wrapped around the winding shaft 51 is eliminated. When winding tension disappears, the base metal sheet 63 is returned to a substantially original position. These motions occur when tension occurs at the start of a rolling-up operation, and the tension at the time of a rolling-up operation is required to be more than force for rotating the front/back reversing unit 45. That is, a relation of F<F′ is required, in which F represents force required for the rotation of the front/back reversing unit 45 and F′ represents the force of the winding shaft 51 in a rolling-up direction.
The operator manually fixes a tip end portion of the print target medium 21a ejected from the front/back reversing unit 45 to the winding shaft 51 on the lower flow side with a tape or the like. Here, since this fixation is performed manually by the operator, if the print target medium 21a is obliquely attached to the winding shaft 51, the print target medium 21a is rolled up obliquely. For example, when the upper winding tension of the print target medium 21a is increased, the front/back reversing unit 45 including the rollers 60 and 61 rotates in the clockwise direction via the rotation spindle 64, as depicted in
By the front/back reversing unit 45 rotating in the clockwise direction, the winding tension applied to the print target medium 21a is balanced (equalized). Then, by the winding tension applied to the print target medium 21a being balanced, the front/back reversing unit 45 is returned to the original position by the elastic member 65. That is, the roller 61 of the front/back reversing unit 45 and the winding shaft 51 become substantially parallel to each other, and the print target medium 21a is wrapped around the winding shaft 51 thereafter without being skewed.
On the other hand, when the lower winding tension of the print target medium 21a is increased as depicted in
In the above-described embodiment, in the image forming apparatus 10 having the front/back reversing unit 45 which changes face-down ejection to face-up ejection, the front/back reversing unit 45 is rotatably engaged with the printer body 30. Therefore, even if the winding tension to the print target medium 21a that is wrapped around the winding shaft 51 becomes unbalanced at the start of the rolling up of the print target medium 21a, the front/back reversing unit 45 rotates in accordance with the winding tension so as to make the winding tension balanced, and the accuracy of a rolling-up operation around the winding shaft 51 can be improved. Also, since guides which regulate the width of paper are not required, even in the case of label paper provided with an edge adhesion layer or the like, troubles due to the adhesion of an adhesive agent occurring from a constant contact with guides can be solved.
Also, in the above-described embodiment, when the winding tension is balanced, the front/back reversing unit 45 is returned to the original position by the elastic member 65 such that the roller 61 of the front/back reversing unit 45 and the winding shaft 51 are parallel to each other. Therefore, the print target medium 21a can be stably wrapped around the winding shaft 51 with the end portions of the print target medium 21a in the paper width direction being aligned, irrespective of the positional accuracy.
Moreover, in the above-described embodiment, the relation of F<F′ is satisfied in which F represents force required for the rotation of the front/back reversing unit 45 and F′ represents the force of the winding shaft 51 in the rolling-up direction. Therefore, paper can be rolled up without looseness can be achieved.
In the above-described embodiment, the front/back reversing unit 45 is rotatably engaged with the fitting 62 fixed to the printer body 30. However, a structure may be adopted in which the front/back reversing unit 45 is directly engaged with the printer body 30 without the fitting 62.
While the present invention has been described with reference to the preferred embodiments, it is intended that the invention be not limited by any of the details of the description therein but includes all the embodiments which fall within the scope of the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2015-027422 | Feb 2015 | JP | national |
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| Entry |
|---|
| Japanese Office Action dated Nov. 24, 2016 for Japanese Patent Application No. 2015-027422 and English translation of the same. (6 pages). |
| Number | Date | Country | |
|---|---|---|---|
| 20160236891 A1 | Aug 2016 | US |
