A sheet folding device folds a sheet-like medium (hereinafter, referred to as “sheet”) into various forms. The sheet folding device may be employed in a finisher of sheets discharged from a copying machine, a printer, or the like, or may be a stand-alone device.
The sheet folding device may fold a sheet once or more than twice using a pair of folding rollers forming a folding nip. The sheet folding device feeds a sheet that has passed through the folding nip again to an entrance of the folding nip to fold the sheet more than once. A structure for feeding the sheet that has passed through the folding nip to the entrance of the folding nip for the next folding may vary. Sheet feeding accuracy between the entrance of the folding nip and an exit of the folding nip may affect precise sheet folding.
Hereinafter, examples of a sheet folding device and an image forming device using the same will be described with reference to the accompanying drawings. The same reference numerals refer to the same elements throughout. In the drawings, the sizes of constituent elements may be exaggerated for clarity.
The printer 100 may print an image on a sheet P using any one of various printing methods, such as an electrophotographic method, an inkjet method, a thermal transfer method, and a thermal sublimation method. For example, the image forming device of the present example prints a color image on the sheet P using the electrophotographic method.
The image forming device may further include a scanner 300 for reading an image recorded on a document. The scanner 300 may have various structures such as a flatbed structure in which a document is located at a fixed position and a reading member moves to read an image, a document feed structure in which the reading member is located at a fixed position and the document is fed, or a combination structure thereof.
The finisher 400 may include a sheet folding device 700 that folds the sheet P discharged from the printer 100 once or more. The finisher 400 may further include an aligner 500 for aligning the sheet P discharged from the printer 100. The aligner 500 may have a structure capable of stapling or punching a staple at an end of the sheet P. The finisher 400 may further include a middle stapler 600 for stapling a staple at a central portion of the sheet P.
Hereinafter, examples of the sheet folding device 700 will be described in detail.
Referring to
The pair of folding rollers is located in the folding path 710. The pair of folding rollers may include the first and second folding rollers 721 and 722 which are engaged with each other as the first folding roller is to engage with the second folding roller to form a folding nip N. The first folding roller 721 is located on the downstream side and the second folding roller 722 is located on the upstream side with respect to the folding path 710. A second motor 723 rotates the first and second folding rollers 721 and 722. A controller 800 controls the sheet folding device 700. The controller 800 may rotate the first and second folding rollers 721 and 722 by driving the second motor 723.
The folding blade 750 is located on an entrance side of the folding nip N. The folding blade 750 may be moved to an insertion position (dashed lines in
The positioning member 740 supports the leading edge PF of the sheet P fed along the folding path 710 and aligns the sheet P at an initial folding position. The positioning member 740 is moved to the alignment position (solid lines in
With the above-described configuration, it is possible to fold the sheet P once. For example, a single sheet or a plurality of sheets P discharged from the printer 100 are fed along the folding path 710 so that the leading edge PF thereof is supported by the positioning member 740 which is located at an alignment position as shown in
The sheet folding device 700 of the present example is capable of folding twice or more by using a single pair of the first and second folding rollers 721 and 722. The sheet P having passed through the folding nip N is guided back to the folding path 710 through the guide path 761 and returned to an entrance of the folding nip N. The guide path 761 may be provided around at least one of the first folding roller 721 and the second folding roller 722. In the present example, the guide path 761 is provided around the first folding roller 721. However, in other examples, the guide path can be provided around the second folding roller or around the first and the second folding rollers.
The guide member 730 is located around the first folding roller 721. The guide member 730 is movable to a first position (of
The conveying roller 762 is arranged on the guide path 761. The conveying roller 762 engages with any one of the pair of folding rollers, for example, the first folding roller 721 to form a conveying nip N2. The conveying roller 762 is driven to be rotate by the first folding roller 721 to feed the sheet P along the guide path 761. The conveying roller 762 of the present example may be rotated around the first folding roller 721. In an example, the conveying roller 762 may be rotatably located on the guide member 730. With this configuration, the conveying roller 762 may be rotated around the first folding roller 721 by the fourth motor 739. The conveying roller 762 may be moved by the fourth motor 739 to a position (of
The guide member 730 may include a first guide portion 731 for selectively guiding the sheet P to the guide path 761 at the first position and the second position, and a second guide portion 732 for guiding the sheet P to the folding path 710. The first guide portion 731 is located at the exit side of the folding nip N and the second guide portion 732 is located at the entrance side of the folding nip N with respect to the conveying roller 762. The first guide portion 731 and the second guide portion 732 may be connected to each other by a third guide portion 733. As shown in
The sheet folding device 700 may have at least one position sensor 737 for detecting a position of the guide member 730. The position sensor 737 may be implemented by, for example, an optical sensor, a microswitch, or the like. For example, any one of the first, second, and third positions of the guide member 730, e.g., the first position, may be a reference position. The position sensor 737 may detect the guide member 730 located at the reference position. The drive motor for driving the guide member 730, that is, the fourth motor 739 may be, for example, a pulse motor. When the reference position is detected by the position sensor 737, the guide member 730 is located at the first position. The controller 800 may control a rotational direction of the fourth motor 739 and the number of drive pulses to move the guide member 730 to the second position or the third position.
When a member for selectively guiding the sheet P that has passed through the folding nip N to the guide path 761 and a member for guiding the sheet P fed along the guide path 761 to the folding path 710 are separately provided, the structure of the sheet folding device 700 becomes complicated and the assembly cost may be increased. In addition, two drive motors are used for driving these two members, respectively, so that the component cost may be increased. According to the present example, a function of selectively guiding the sheet P that has passed through the folding nip N to the guide path 761 and a function of guiding the sheet P fed along the guide path 761 to the folding path 710 may be implemented by one guide member 730 and the fourth motor 739. Therefore, the number of components and the number of assembling processes may be reduced, and the manufacturing cost of the sheet folding device 700 may be reduced. Further, since the conveying roller 762 is provided on the guide member 730, the conveying roller 762 may be moved by the fourth motor 739. Therefore, the manufacturing cost of the sheet folding device 700 may be further reduced.
Although not shown in the drawings, a guide member that is spaced apart from an outer periphery of the first folding roller 721 and forms the guide path 761 is employed in the sheet folding device 700 and the conveying roller 762 may be located at a fixed position. In this configuration, since a moving path of the sheet P is not uniform between the exit and the entrance of the folding nip N, a length of moving path of the sheet P between the exit and the entrance of the folding nip N may vary. For accurate subsequent folding of the sheet P, moving distances of the sheet P between the exit and the entrance of the folding nip N need to be constant. It is difficult to align folding positions of the sheet P with the folding blade 750 unless the moving distances of the sheet P between the exit and the entrance of the folding nip N is constant. A method of arranging a plurality of conveying rollers 762 in a fixed position along the guide path 761 may be considered, but in this case, the component cost may be increased. Furthermore, a skew of the sheet P may be generated as the sheet P is bent when the sheet P enters a plurality of conveying nips formed by the plurality of conveying rollers 762 and the first folding roller 721. Further, since the guide member extends from the exit of the folding nip N to the entrance of the folding nip N around the first folding roller 721, it is not easy to remove a jam when the jam occurs in the guide path 761. In order to remove the jam, the guide member needs to be partially or wholly separated to expose the guide path 761.
According to the present example, the conveying roller 762 may be rotated around the first folding roller 721 and moved to the position (of
Also, since the conveying roller 762 is rotated around the first folding roller 721 and moved toward the exit of the folding nip N while the sheet P is engaged with the conveying nip N2 formed by the conveying roller 762 and the first folding roller 721, the possibility of occurrence of a skew may be reduced.
Further, since the guide member 730 itself may move between the entrance and the exit of the folding nip N, the guide path 761 is always partially exposed. Therefore, when a jam occurs, the jam treatment is easy.
Furthermore, when the conveying roller 762 has a fixed position, a minimum folding length is limited by the distance from the exit of the folding nip N to the folding nip N. The minimum folding length may be shortened by bringing the conveying roller 762 close to the exit of the folding nip N, but the variability of a length of the moving path of the sheet P between the exit and entrance of the folding nip N may become larger. Thus, it is necessary to arrange the plurality of conveying rollers 762 around the first folding rollers 721. When the conveying roller 762 is moved away from the exit of the folding nip N, the minimum folding length may not be shortened. According to the present example, it is possible to change a position of the conveying roller 762 in a state in which the conveying nip N2 is formed, so that even when the minimum number of conveying rollers 762, for example, one conveying roller 762 is employed, the minimum folding length may be relatively shorter.
Not shown in
Referring to
In
When the guide member 730 reaches the third position as shown in
The guide member 730 may be moved to the first position before the folding blade 750 is moved to an insertion position for the second folding. Then, as shown in
As shown in
As described above, Z-folding is possible. Further, simple four-folding may also be performed by folding the central portion of the folded sheet P one more time.
C-folding or Z-folding, which is 3-folding, may be possible by folding twice using the guide path 761 or the guide path 761a. In addition, double gate-folding, roll-folding, W-folding, or the like is possible by folding three times while passing the sheet P sequentially through the guide path 761 and the guide path 761a.
The guide member 730b may include a first guide portion 731b which is located on the exit side of the folding nip N with respect to the first conveying roller 762-1 and selectively guides the sheet P to the guide path 761 at the first position (the position shown by solid lines in
According to such a configuration, the function of selectively guiding the sheet P that has passed through the folding nip N to the guide path 761 and the function of guiding the sheet P fed along the guide path 761 to the folding path 710 may be implemented by one guide member 730b and the fourth motor 739 for driving the guide member 730b. Therefore, the number of components and the number of assembling processes may be reduced, and the manufacturing cost of the sheet folding device 700 may be reduced. Further, since the first and second conveying rollers 762-1 and 762-2 are provided on the guide member 730b, the first and second conveying rollers 762-1 and 762-2 may be moved by the fourth motor 739. Therefore, the manufacturing cost of the sheet folding device 700 may be further reduced. According to the present example, since the first and second conveying rollers 762-1 and 762-2 may be rotated to some extent around the first folding roller 721, the distance between the first and second conveying rollers 762-1 and 762-2 may be made close to each other, which may help prevent the sheet P from skewing, and the minimum folding length may be made relatively short.
Referring to
For example, the first guide member 730-1 may be rotated around the first folding roller 721 and moved to the first and second positions. The first elastic member 734-1 may be implemented by a tension coil spring, for example, as shown in
A position of the conveying roller 762 may be indirectly detected by detecting the position of the first guide member 730-1. The position sensor 737 (of
When the reference position is detected by the position sensor 737, the first guide member 730-1 is located at the first position. The controller 800 drives the fourth motor 739, for example, in a forward direction, to rotate the rotation bracket 763, for example, in a clockwise direction. When the rotation bracket 763 pushes the first guide member 730-1 and the first guide member 730-1 is moved to the second position beyond the first position, the position of the conveying roller 762 may be indirectly detected by the position sensor 737. By setting the number of drive pulses between the first position and the second position in advance, the rotation bracket 763 may be rotated to move the first guide member 730-1 from the first position to the second position.
The sheet P that has passed through the folding nip N may be guided to the guide path 761 by the first guide member 730-1 located in the second position. In this state, the controller 800 may drive the fourth motor 739, for example, in a reverse direction, to rotate the rotation bracket 763, for example, in a counterclockwise direction. Then, the first guide member 730-1 may be returned to the first position by the elastic force of the first elastic member 734-1.
When the leading edge of the sheet P guided to the guide path 761 is engaged with the conveying nip N2 formed by the conveying roller 762 and the first folding roller 721, the controller 800 further drives the fourth motor 739, for example, in the reverse direction, in accordance with rotational linear velocity of the first folding roller 721. The conveying roller 762 may then be rotated around the first folding roller 721 and moved toward the entrance of the folding nip N. According to this configuration, since the sheet P is fed in close contact with the first folding roller 721 between the entrance and the exit of the folding nip N, the feeding of the sheet P between the entrance and the exit of the folding nip N is almost constant. Therefore, accurate subsequent folding of the sheet P is possible. The sheet P may be stably guided to the folding path 710 by the second guide member 730-2 located at the third position.
The second guide member 730-2 may be moved from the third position to the fourth position close to the entrance of the folding nip N as shown in
In a state in which the leading edge of the sheet P is engaged with the conveying nip N2, the controller 800 drives the fourth motor 739 in the reverse direction in accordance with the rotational linear velocity of the first folding roller 721. The rotation bracket 763 is rotated in the counterclockwise direction and is brought into contact with the second guide member 730-2 located at the third position. When the fourth motor 739 is further driven in the reverse direction in this state, the second guide member 730-2 may be pushed by the rotation bracket 763 and further moved toward the entrance of the folding nip N. According to such a configuration, as shown in
When the fourth motor 739 is again driven in the forward direction, the conveying roller 762 may be rotated in the clockwise direction and the second guide member 730-2 may be returned to the third position by the elastic force of the second elastic member 734-2.
The above-described examples are merely illustrative, and various modifications and equivalent other examples may be made by one of skill in the art. Therefore, the scope of the present disclosure is defined not by the detailed description of the present disclosure but by the appended claims.
Number | Date | Country | Kind |
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10-2018-0108420 | Sep 2018 | KR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/US2019/050625 | 9/11/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/056010 | 3/19/2020 | WO | A |
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