The present application claims priority to and incorporates by reference the entire contents of Japanese Patent Application No. 2010-127180 filed in Japan on Jun. 2, 2010.
1. Field of the Invention
The present invention relates to a creasing device that preliminary produces a fold mark or a crease in a sheet member (hereinafter, “sheet”) delivered from a preceding stage before the sheet is folded and to an image forming system that includes the creasing device and an image forming apparatus.
2. Description of the Related Art
What is called saddle-stitch or center-folded booklet production has been conventionally performed by saddle stitching a sheet batch, which is a stack of a plurality of sheets delivered from an image forming apparatus, and folding the thus-saddle-stitched sheet batch in the middle of the sheet batch. Folding such a sheet batch containing a plurality of sheets causes outside sheets of the sheet batch to be stretched at a fold line by a greater amount than inside sheets. An image portion formed at the fold line on outside sheets can thus be stretched, resulting in damage, such as come off of toner, to the image portion in some cases. A similar phenomenon can occur when other fold, such as z-fold or tri-fold, is performed. A sheet batch can be folded insufficiently depending on the thickness of the sheet batch.
A creasing device called a creaser that produces a fold mark (a crease) in a sheet batch prior to a folding process where the sheet batch undergoes half fold or the like to make outside sheets easy to fold, thereby preventing come off of toner have already been known. Some types of such creasing devices produce a crease in a sheet in a direction perpendicular to a sheet conveying direction by moving a roller on the sheet, burning the sheet with a laser beam, pressing a creasing blade against the sheet, or a like method.
However, producing the crease in a sheet with the roller involves moving the roller across a full length of the sheet in a direction, along which a fold extends, and therefore is time consuming. This can be resolved by rotating the sheet conveying direction by 90 degrees and producing a crease parallel to the sheet conveying direction; however, this scheme involves an effect on footprint and therefore is disadvantageous in view of space-saving. Creasing by using a laser beam is environmentally less favorable because smoke and odor are given off during creasing.
Creasing a sheet by pressing a creasing blade against the sheet can be performed in a relatively short period of time and allows easy production of a crease perpendicular to a sheet conveying direction; however, pressing a longitudinal face of the creasing blade against the sheet entirely at once causes a high load. To reduce the load, a scheme of bringing the creasing blade face into contact with a sheet in multiple batches can be used. However, this scheme is disadvantageous in that unevenness can develop between a portion that contacts the blade multiple times and a portion that contacts the blade only once and also in that producing a crease by making contact in multiple batches can decrease productivity.
To solve the inconveniences discussed above, it is possible to reduce a load placed on a creasing moving unit by bringing a creasing blade gradually into contact with a sheet from an edge of the sheet and causing a creasing unit to contact the sheet only once; however, this causes a pressure applied onto a center portion of the sheet to be weakened, making it difficult to produce an even crease.
To that end, creasing a sheet gradually from an edge of the sheet to reduce a load during creasing and bringing the creasing unit into contact with the sheet only once for production of an even crease is conceivable. To perform this, it is necessary to retain a sheet to prevent displacement of the sheet during creasing; however, if this sheet retaining operation is performed concurrently with the creasing operation, the sheet is retained only at a portion, which gradually shifts from an edge of the sheet. This can disadvantageously cause displacement of the sheet to occur during creasing.
To that end, a technique of moving a creasing member by using a plurality of individually-advancing-and-retracting mechanisms, which are activated at different times, so as to enable formation of a crease while reducing a pressing force for a creasing member is disclosed in, for instance, Japanese Patent Application Laid-open No. 2009-166928.
A technique of aligning edges of sheets by, when the sheets are cut, pressing a top surface of a batch of the sheets by a first pressing unit, which is capable of ascending and descending to press the batch placed on a sheet stacking unit at a portion near a fold of the batch, by, after a lapse of a predetermined period of time, pressing the batch at a portion near an edge of the batch by a second pressing unit, which is capable of ascending and descending to press the batch, and by, thereafter, trimming the edges of the sheets by a cutting unit, which is capable of ascending and descending is disclosed in Japanese Patent Application Laid-open No. 2000-198613. In this technique, consideration is given to prevention of displacement of the sheet batch.
However, the technique disclosed in Japanese Patent Application Laid-open No. 2009-166928 can disadvantageously cause a crease to have unevenness between a portion of a sheet that comes into contact with a creasing blade multiple times and a portion of the sheet that comes into contact with the creasing blade only once. This technique is also disadvantageous in that it is necessary to retain the sheets at different times by using a plurality of individually-advancing-and-retracting mechanisms to prevent displacement of the sheets during creasing, which also disadvantageously makes the structure complicated.
The technique disclosed in Japanese Patent Application Laid-open No. 2000-198613 prevents displacement of sheets by using the first and the second pressing units to pressing the sheet at different times during sheet cutting; however, the structure according to this technique is complicated as is the structure of the technique disclosed in Japanese Patent Application Laid-open No. 2009-166928. Furthermore, the technique disclosed in Japanese Patent Application Laid-open No. 2000-198613 is for a mechanism that imposes a force of a relatively large magnitude for edge trimming, and not appropriate for a mechanism that performs creasing by placing a relatively light load.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an aspect of the present invention, there is provided a creasing device that creases sheets on a per-sheet basis. The creasing device includes: a first member extending in a direction perpendicular to a sheet conveying direction and including a convex blade, the convex blade having a convex cross section; a second member extending in a direction perpendicular to the sheet conveying direction and including a concave blade, the concave blade allowing the convex blade to be fitted thereinto with a sheet interposed between the concave blade and the convex blade; a drive unit that brings the first member and the second member into and out of contact with each other to cause a sheet stopped at a predetermined position to be pinched between the first and the second members and creased; a sheet retainer driven by the drive unit and brought into contact with a top surface of the second member with the sheet interposed between the sheet retainer and the second member to retain the sheet across a full width of the sheet; and a holding unit that holds the sheet retainer in a retaining state during creasing where the convex blade and the concave blade come into contact with each other with the sheet interposed therebetween, the contact starting at one point and developing in one direction.
According to another aspect of the present invention, there is provided an image forming system including: the abovementioned creasing device; and an image forming apparatus that forms an image on the sheets.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
In embodiments discussed below, a reference symbol A corresponds to a creasing device; a creasing blade 11a corresponds to a convex blade; a creasing member 11 corresponds to a first member; a creasing channel 12a corresponds to a concave blade, a receiving member 12 corresponds to a second member; a drive mechanism 30M corresponds to a driving unit; a sheet retaining member 42 corresponds to a sheet retainer; a set of a third cam 41a and a fourth cam 41b, a first positioning member 43a and a second positioning member 43b, and a support 45 corresponds to a holding unit; a set of a first spring fixing unit 50a and a second fixing unit 50b correspond to a pressure changing unit; a reference symbol E corresponds to an image forming apparatus. A traveling speed of the sheet retainer depends on a rotation speed of a drive motor 30 and a relationship between the third and the fourth cams 41a and 41b and third and force positioning members 43a and 43b.
The present invention is intended to, during creasing, to move a creasing blade entirely, but to bring the creasing blade into contact with a sheet gradually from an edge of the sheet to thereby reduce a load placed on a creasing moving unit, and to bring a creasing unit into contact with the sheet only once to thereby produce an even crease, wherein it is intended that a sheet retaining mechanism, for use in retaining a position of the sheet during creasing, is configured to be driven by a same drive source as that for a creasing mechanism and to retain the sheet across a full width of the sheet along a direction perpendicular to a sheet conveying direction from a front end to a rear end of the sheet all together so that displacement of the sheet during creasing can be lessened.
Exemplary embodiments of the present invention are described below with reference to the accompanying drawings.
The image forming apparatus E forms a visible image pertaining to image data fed from a scanner, a personal computer (PC), or the like on a sheet of paper. The image forming apparatus E uses a known print engine of electrophotography, droplet ejection printing, or the like.
The creasing device A includes a conveying mechanism and a creasing unit C. The creasing unit C includes the creasing member 11 and the receiving member 12 and performs creasing by pinching a sheet of paper (hereinafter, “sheet”) between the creasing member 11 and the receiving member 12 to produce a linear crease. As illustrated in
The creasing member 11 is constantly resiliently urged by a resilient member 14, e.g., a compression spring, toward the receiving member 12 and moved up and down by a cam 13. Meanwhile, an upper end of the resilient member 14 in
In this example, the conveying mechanism includes a first pair of conveying rollers 1, a second pair of conveying rollers 2, and a third pair of conveying rollers 3 and conveys a sheet delivered from the image forming apparatus E to a subsequent stage. An entrance sensor SN1 is provided immediately upstream of the first conveying rollers 1, which are located most upstream among the conveying rollers. The entrance sensor SN1 detects a leading edge and a trailing edge of a sheet delivered into the creasing device A. A stopper plate 10, on which a leading edge of a sheet is to abut, is provided immediately downstream of the second conveying rollers 2 provided in the creasing unit C. The stopper plate 10 is capable of ascending and descending relative to a conveyance path.
The folding device B includes a center-folding device D that performs folding. The sheet creased by the creasing device A is conveyed into the folding device B, in which a fourth pair of conveying rollers 4, a fifth pair of conveying rollers 5, and a sixth pair of conveying rollers 6 deliver the sheet to the center-folding device D.
The center-folding device D includes a center-folding tray 22, a trailing-edge fence 23 provided at a lower end (most upstream in the conveying direction) of the center-folding tray 22, a folding plate 20 and a pair of folding rollers 21 configured to fold a sheet along a crease, and a stacking tray 24. The trailing-edge fence 23 evens up sheet edges in the sheet conveying direction by causing a return roller (not shown) to forcibly press trailing edges of sheets discharged'onto the center-folding tray 22 against the railing-edge fence 23. A jogger fence (not shown) also evens up sheet edges in the direction perpendicular to the conveying direction.
The folding plate 20 presses its distal-end edge against the evened-up sheet batch along the crease, thereby pushing it into a nip between the folding rollers 21. The sheet batch pushed into the nip between the folding rollers 21 is folded in the nip. When saddle-stitching is to be performed, the sheet batch is stitched by a stitching device (not shown) at a portion to be folded, and thereafter subjected to this folding process, what is called half fold. The half-folded sheet batch is discharged onto and stacked on the stacking tray 24.
For the sheet P1 stopped at this position, the cam 41a and the cam 41b (see
The operations mentioned above with reference to
The series of operations from sheet creasing (scoring) to folding is performed in this manner. Although not shown, the creasing device A is capable of adapting to other fold mode, such as tri-fold, Z-fold, or closed-gate fold, by producing creases (creases) whose number corresponds to the number of times folding is to be performed.
The configuration of the creasing unit C that performs the creasing mentioned above is illustrated in detail in
The creasing member 11 has, in addition to the creasing blade 11a provided at the lower end of the creasing member 11, a first elongated hole R at a rear and a second elongated hole and S at a front, into which a first support shaft 33 and a second support shaft 32, which will be described later, are loosely fit, respectively, and includes a first positioning member 31a and a second positioning member 31b at a rear end portion and a front end portion, respectively. The first and the second elongated holes R and S are elongated in a direction perpendicular to the sheet conveying direction and configured to allow the first and the second support shafts 33 and 32 to pivot in a plane perpendicular to the sheet conveying direction but not to allow movement in the sheet conveying direction, relative to the first and the second elongated holes R and S. The first and the second positioning members 31a and 31b extend substantially vertically downward from the front end portion and the rear end portion of the body of the creasing member 11. The first and the second positioning members 31a and 31b are disciform cam followers that are rotatably supported at their centers and brought into contact with a first cam 13a and a second cam 13b to be rotated. Meanwhile, a front side of the device is depicted on the left-hand side in
The receiving member 12 is coupled to the spring fixing member 15 located above the creasing member 11 via the first and the second support shafts 33 and 32 and moved integrally with the spring fixing member 15. A first shaft member 11m at a rear and a second shaft member 11n at a front are provided on the spring fixing member 15 at two longitudinal end portions of the creasing member 11. A first resilient member 14a and a second resilient member 14b (which are collectively referred to as “the resilient member 14”) are mounted on an outer periphery of the shaft member 11m and an outer periphery of the shaft member 11n, respectively, thereby constantly resiliently urging the spring fixing member 10 upward, and accordingly the receiving member 12 upward. The first support shaft 33 is formed to have a semicircular cross-sectional profile taken along short sides in a rectangular cross section and loosely fit in the first elongated hole R. A third elongated hole T that is vertically elongated is defined in the first support shaft 33 at a portion lower than a middle portion of the first support shaft 33. A rotating shaft Q is vertically inserted into the third elongated hole T from a side-surface of the creasing member 11 (in a direction perpendicular to the plane of
The drive mechanism 30M is a mechanism that rotates the first and the second cams 13a and 13b, which are in contact with the positioning members 31a and 31b, to press the creasing member 11 against the receiving member 12 and move the creasing member 11 away from receiving member 12. The drive mechanism 30M includes a camshaft 34, to which the first cam 13a and the second cam 13b are coaxially coupled at a rear portion and a front portion, respectively, a drive gear train 35 that drives the camshaft 34 at an end (in the present embodiment, a rear end portion) of the camshaft 34, and the drive motor 30 that drives the drive gear train 35. The first and the second cams 13a and 13b are located at positions where the first cam 13a and the second cam 13b are opposed to the first positioning member 31a and the second positioning member 31b and are to abut thereon, respectively. The first and the second cams 13a and 13b bring the creasing member 11 toward and away from the receiving member 12 according to distances between a center of the camshaft 34 and rotation centers of the positioning members 31a and 31b on straight lines passing through the center of the camshaft 34 and the rotation centers of the positioning members 31a and 31b. At this time, a position of the creasing member 11 is confined by the first and the second support shafts 33 and 32 and the first and the second elongated holes R and S. The creasing member 11 reciprocates under this confined state. A configuration that causes the creasing blade 11a of the creasing member 11 to come into contact with the receiving member 12 in a state where the creasing blade 11a is inclined relative to the receiving member 12 rather than parallel with the receiving member 12 so as to crease a sheet at an oblique angle according to shapes of the first and the second cams 13a and 13b is employed.
More specifically, when the drive motor 30 starts rotating from the state (where a sheet has been conveyed to and stopped at the creasing position), which corresponds to an initial position, illustrated in
When the creasing blade 11a abuts on the creasing channel 12a of the receiving member 12 as illustrated in
When the drive motor 30 further rotates from the state illustrated in
After the crease has been formed, the drive motor 30 further rotates, causing the camshaft 34 and the first and the second cams 13a and 13b to rotate. Then, as illustrated in
The bottom end of the portion of the creasing blade 11a near the first positioning member 31a is temporarily stopped at the position separated from the receiving member 12. When a top surface of the creasing member 11 is oriented horizontally as illustrated in
In this process, as illustrated in
When, in
S1=L1
S2=H1
H1=L1
In this state, the creasing blade 11a and the creasing channel 12a are in the positional relationship illustrated in
H2=L2
That is, the front portion and the rear portion of the creasing blade 11a move (descend) by the same distance concurrently.
In a state where the first and the second cams 13a and 13b are further rotated after the portion A has come into contact with the receiving member 12, as illustrated in
S1>L2′
S2=H2′
In this process, the creasing member 11 rotates about the rotating shaft Q.
S1>L3
S2>H3
The distances L and H are smaller than the distance S at both front and rear portion of the creasing blade 11a. Hence, the resilient members 14a and 14b press the creasing member 11 to cause the creasing blade 11a to be fitted into the creasing channel 12a of the receiving member 12 with a sheet therebetween, thereby producing a crease in the sheet.
S1=L4
S2>H4
Thereafter, the positional relationships shift to positional relationships that can be expressed by the following equations.
S1=L4′
S2=H4′
Meanwhile, the distance S1 at the rear portion is kept constant until the distance S2 at the front portion reaches the distance at the rear side. After a relationship expressed by S1=S2 has been established as illustrated in
The shapes of the first and the second cams 13a and 13b are configured such that a speed, at which the creasing blade 11a moves away from the receiving member 12, increases after the creasing blade 11a has started moving away from a state illustrated
By performing the operations mentioned above, sheets P are creased on a sheet-by-sheet basis and then conveyed into the folding device B.
As mentioned above, retaining sheets during sheet edge trimming is a known technique.
In the creasing member 11 configured in this manner, the sheet retaining member 42 is gradually brought into contact with a sheet from a sheet edge because the sheet retaining member 42 operates in the same manner as the creasing member 11. Accordingly, a portion of a sheet where the sheet retaining member 42 retains the sheet gradually changes during the creasing process. This can cause displacement of the sheet during the creasing process to occur. Hence, it will be difficult to prevent displacement even when such a mechanism as discussed above is introduced.
The sheet retaining member 42 is longer than the width of the sheet in view of the conveying direction so that the sheet retaining member 42 can reliably retain the sheet across the full width of the sheet. An elastic material, such as rubber, that causes less damage to a sheet and is less likely to skid on the sheet, is attached to a distal end portion 42b of the retaining member 42 because the retaining member 42 comes into contact with a sheet at the distal end portion 42b. The retaining member 42 is attached to a support 45, which is independent from the creasing member 11. The support 45 is located between the creasing member 11 and the spring fixing member 15 and urged toward the sheet conveyance path by a spring 44a and a spring 44b fixed to a bottom surface of the spring fixing member 15. A first guide hole 45a and a second guide hole 45b, into which the first support shaft 33 and the second support shaft 32 are to be loosely fit, respectively, are defined in the support 45. The first and the second guide holes 45a and 45b allow the sheet retaining member 42 to travel and serve as a guide for the same.
As illustrated in
Accordingly, running the drive motor 30, which is the drive source of the creasing member 11, causes the third and the fourth cams 41a and 41b to rotate, which in turn moves the sheet retaining member 42 in a direction substantially perpendicular to the sheet conveying direction concurrently with the creasing process to retain a sheet. Put another way, the sheet retaining member 42 and the creasing member 11 ascend and descend in a synchronized manner in a positional relationship that depends on a relationship between the cams and the positioning members.
It is desirable that the sheet retaining member 42 is located near the creasing member 11 in the conveying direction. In this time, a similar effect can be yielded regardless of whether the retaining member 42 is located upstream or downstream of the creasing member 11 in the conveying direction. The sheet retaining member 42 is located at a position upstream of the creasing member 11 in the conveying direction in the present embodiment. Accordingly, in a case where sheet jam in the conveying path occurs, a user removing a jammed sheet is prevented from accessing a portion under the creasing member 11, and therefore his/her hand is protected from touching the creasing blade 11a. Meanwhile, when the sheet retaining member 42 is provided downstream of the creasing member 11, a one-way clutch is desirably mounted on the second conveying rollers 2 so as to allow a sheet to be moved in the conveying direction. This allows a sheet to be moved so that the sheet can be creased.
More specifically, to prevent damage to the sheet and displacement of the sheet that may otherwise be caused by contact between of the distal end portion 42b of the sheet retaining member 42 and the sheet, a traveling speed, at which the sheet retaining member 42 descends, for a period (period F2) immediately before the contact is set low, while a traveling speed for a sheet-retaining period F3 is set such that the sheet retaining member 42 retains the sheet without fail for a duration that depends on the creasing speed, at which the creasing member 11 performs creasing. For a period (period Fl) prior to the period immediately before the contact and a period (period F4), over which the sheet retaining member 42 moves away from the sheet, the conveying speed of the sheet is set high to maintain productivity.
In a situation where the rotation speed of the drive motor 30 is constant, a vertical traveling speed of the sheet retaining member 42 depends on an amount of a change in a length in a radial direction of the third and the fourth cams 41a and 41b per a change in a rotation angle of the same. As illustrated in
Alternatively, the first and the second spring fixing units 50a and 50b can be configured as rotating members each having a male thread to be screwed into female threads provided by cutting threads in the spring fixing member 15.
This allows the pressure to be exerted by the sheet retaining member 42 on a sheet to be adjusted by rotating the first and the second spring fixing units 50a and 50b to vertically move positions of the first and the second spring fixing units 50a and 50b. Meanwhile, a scale 50m is desirably marked on each of top surfaces of the first and the second spring fixing units 50a and 50b as illustrated in
The higher the pressure exerted by the sheet retaining member 42, the more effectively displacement of the sheet during creasing is prevented. However, in some type of paper, the sheet retaining member 42 can leave an impression on a print surface of a sheet when a high pressure is exerted thereon. Accordingly, it is desirable to adjust the pressure exerted by the sheet retaining member 42 by changing vertical positions of the first and the second spring fixing units 50a and 50b depending on a sheet condition. In the example illustrated in
The thicker the thickness of a sheet, the more likely an impression is left by the sheet retaining member 42. In a situation where the sheet P is special paper, such as coated paper, or a situation where a print area in a portion where the sheet retaining member 42 contacts the sheet P is large, an impression is more conspicuous. To that end, a pressure to be exerted by the sheet retaining member 42 is desirably selected from P1, P2, and P3 depending on S1, which is a predetermined sheet thickness, C1, which is a print area in a contact portion between the sheet retaining member 42 and the sheet, and whether the sheet is special paper. Here, the pressures satisfies P1<P2<P3.
The creasing device A illustrated in
If the thickness of the sheet is equal to or greater than S1 (YES at Step S101), the sheet is special paper (YES at Step S102), and the percentage of the print area in the retained portion is equal to or greater than C1, which has been determined in advance, (YES at Step S103), the pressure is set to P1 (Step S104).
If the sheet is not special paper at Step S102, if the percentage of the print area in the retained portion is smaller than C1 at Step S103, if the thickness of the sheet is smaller than S1 (NO at Step S101) and the sheet is special-paper (YES at Step S105), or if the sheet is not special paper at Step S105 and the percentage of the print area in the retained portion is greater than C1, the pressure is set to P2 (Step S107).
If the percentage of the print area in the retained portion is smaller than C1 at Step S106, the pressure is set to P3 (Step S108).
In a configuration where the first and the second spring fixing units 50a and 50b are rotated by using a motor, it is possible to automatically adjust the pressure to be exerted onto a sheet by driving the motor according to the set value P1, P2, or P3.
The set values P1, P2, and P3 can be displayed on a display unit of the control panel E1 of the image forming apparatus E. This allows a user to perform adjustment by using a tool while referring to the scale 50m illustrated in
The operations in the flowchart can be executed by the CPU in the image forming apparatus E. For the configuration where the set values P1, P2, and P3 are displayed, this can be performed only by the image forming apparatus E.
As discussed above, according to the present embodiment, effects including the following effects are yielded.
It should be understood that the present invention is not limited to the embodiments, and it is intended to cover all various modifications as may be included within the spirit and scope as set forth in the appended claims.
According to an aspect of the present invention, when creasing is performed by bringing a convex blade and a concave blade into contact with a sheet interposed therebetween such that the contact starts from a point contact and develops in one direction, a sheet retainer, which is driven by a drive force of a driving unit that performs creasing, retains the sheet across a full width of the sheet in a retained state during creasing. Accordingly, creasing and prevention against sheet displacement can be achieved easily by using the single drive source.
Although the invention has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
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