Embodiments described herein relate generally to a paper feeding device and an image processing apparatus.
In the related art, there is known a paper feeding device including a paper feeding roller that conveys a sheet and a separation roller that applies a load to the conveyed sheet. The separation roller separates overlapped sheets.
The separation roller is slidably supported in a state of being pressed against the paper feeding roller. If the sliding resistance is large in a sliding portion, the pressing of the separation roller against the paper feeding roller becomes incomplete. The paper feeding device is required to reduce the sliding resistance of the sliding portion that supports the separation roller.
In general, according to one embodiment, a paper feeding device includes a paper feeding roller and a separation roller. The paper feeding roller and the separation roller are arranged in a parallel direction. The paper feeding roller and the separation roller interpose a sheet. The paper feeding device includes a paper feeding roller, a separation roller, a shaft, a holder, and a rotation stopping portion. The paper feeding roller is configured to convey the sheet in a conveyance direction orthogonal to the parallel direction. The separation roller is configured to be pressed against the paper feeding roller. The shaft is configured to rotatably support the separation roller via a torque limiter. The holder is configured to include a supporting portion. The supporting portion is provided with a first guide surface and a second guide surface facing each other and extending in the parallel direction. The rotation stopping portion is configured to be attached to the shaft. The rotation stopping portion is configured to be inserted between the first guide surface and the second guide surface. The rotation stopping portion is configured to include a first sliding surface and a second sliding surface. The first sliding surface faces the first guide surface on the paper feeding roller side of the parallel direction and a downstream side of the conveyance direction with respect to a rotation axis of the separation roller. The second sliding surface faces the second guide surface on an opposite side of the paper feeding roller of the parallel direction and an upstream side of the conveyance direction with respect to the rotation axis of the separation roller.
Hereinafter, embodiments for carrying out the invention are described below with reference to the drawings. In each figure, the same parts are denoted by the same reference numerals.
In the following, the description is made by using an orthogonal coordinate system of X, Y, and Z, if necessary. A predetermined direction in a horizontal plane is set as an X direction, a direction orthogonal to the X direction in the horizontal plane is set as a Y direction, a direction orthogonal to each of the X direction and the Y direction (that is, a vertical direction) is set as a Z direction. Among the X, Y, and Z directions, an arrow direction in the figure is set as a plus (+) direction, and a direction opposite to the arrow is set as a minus (−) direction. The +X direction is set as the front direction, the −X direction is set as the rear direction, the +Y direction is set as the right direction, the −Y direction is set as the left direction, the +Z direction is set as the upward direction, and the −Z direction is set as the downward direction.
The image processing apparatus 90 is described.
The image processing apparatus 90 of the present embodiment is a multifunction printer (MFP). For example, the image processing apparatus 90 forms an image on paper with a developer such as a toner. For example, the paper is paper or label paper. The paper may be any paper as long as an image can be formed on the surface thereof. In the example of
According to the present embodiment, as an image processing apparatus on which the paper feeding device 1 is mounted, a multifunction printer is exemplified. However, the paper feeding device 1 may be mounted on other image processing apparatuses. As the image processing apparatus on which the paper feeding device 1 is mounted, an automatic document feeder, a scanner, and a decoloring device are exemplified.
The paper feeding device 1 is described.
As illustrated in
As illustrated in
The separation roller 20 is a cylindrical shape with a second rotation axis J2 as the center. The second rotation axis J2 of the present embodiment is parallel to the horizontal direction (X axis). The first rotation axis J1 and the second rotation axis J2 are parallel to each other.
As illustrated in
As illustrated in
A sheet S is interposed between the paper feeding roller 10 and the separation roller 20. The sheet S comes into contact with the paper feeding roller 10 on the upper surface. The sheet S comes into contact with the separation roller 20 on the lower surface. The paper feeding roller 10 is driven and rotated to convey the sheet S. If two or more of the sheets S are overlapped and fed, the separation roller 20 applies a load to the sheet S on the lower side due to the action of the torque limiter 39 and separates the upper sheet S.
As illustrated in
As illustrated in
The shaft 30 extends in the horizontal direction with the second rotation axis J2 as the center. The shaft 30 has a cylindrical shape. The torque limiter 39 is fixed to the outer peripheral surface of the shaft 30. The shaft 30 rotatably supports the separation roller 20 via the torque limiter 39.
An upward force is applied from the pressure unit 80 to the end portions 32 on both sides of the shaft 30. As illustrated in
End portions 32 are provided with D-cut surfaces 31 on the both sides of the shaft 30. A cross section of the end portion 32 of the shaft 30 has a D shape. The rotation stopping portions 40 are attached to the end portions 32 on the both sides of the shaft 30. The torque limiter 39 and the separation roller 20 are disposed between the two rotation stopping portions 40 in the axial direction of the shaft 30.
The rotation stopping portion 40 has a flat plate shape along a plane (Y-Z plane) orthogonal to the second rotation axis J2. The rotation stopping portions 40 are provided with outer ribs 49 extending along the outer shape. The outer ribs 49 project on both sides of the rotation stopping portions 40 in the plate thickness direction. The outer ribs 49 reinforce the rotation stopping portions 40.
As illustrated in
Support holes 47 penetrate the main body portion 45 in the plate thickness direction. The support hole 47 has a D shape. The end portions 32 of the shaft 30 are inserted into the support holes 47. The relative rotation of the shaft 30 and the rotation stopping portions 40 is limited. Inner ribs 48 are provided on the inner edge of the support holes 47. The inner ribs 48 protrude in the plate thickness direction of the rotation stopping portions 40. The inner rib 48 enhances the rigidity of the rotation stopping portion 40 near the support hole 47. The inner rib 48 stabilizes the support of the shaft 30 by the rotation stopping portion 40.
A first end edge 55 and a second end edge 56 are provided on the outer peripheral edge of the rotation stopping portion 40. The first end edge 55 and the second end edge 56 each extend in substantially straight-line shapes in the parallel direction PD.
The first end edge 55 is positioned on the downstream side of the conveyance direction TD with respect to the second rotation axis J2. The first end edge 55 is an end edge of the main body portion 45. The second end edge 56 is positioned on the upstream side of the conveyance direction TD with respect to the second rotation axis J2. Meanwhile, the second end edge 56 is an end edge mounted over the main body portion 45 and the leg portion 46.
The first end edge 55 includes a first sliding surface 51 and a third sliding surface 53. Meanwhile, the second end edge 56 includes a second sliding surface 52 and a fourth sliding surface 54. That is, the rotation stopping portion 40 includes the first sliding surface 51, the second sliding surface 52, the third sliding surface 53, and the fourth sliding surface 54.
The first sliding surface 51 and the third sliding surface 53 face the downstream side of the conveyance direction TD. The first sliding surface 51 and the third sliding surface 53 are planes orthogonal to the conveyance direction TD. The first sliding surface 51 is disposed on the upper end side of the first end edge 55. Meanwhile, the third sliding surface 53 is disposed on the lower end side of the first end edge 55. The third sliding surface 53 is positioned on the opposite side of the paper feeding roller 10 in the parallel direction PD with respect to the first sliding surface 51. The third sliding surface 53 is disposed in the same planar shape as the first sliding surface 51. The first sliding surface 51 and the third sliding surface 53 are provided with recesses 59 containing grease.
A first cutout portion 57 is provided between the first sliding surface 51 and the third sliding surface 53. The first cutout portion 57 opens on the downstream side of the conveyance direction TD. The first cutout portion 57 depresses on the upstream side of the conveyance direction TD with respect to the first sliding surface 51 and the third sliding surface 53.
The second sliding surface 52 and the fourth sliding surface 54 face the downstream side of the conveyance direction TD. The second sliding surface 52 and the fourth sliding surface 54 are planes orthogonal to the conveyance direction TD. The second sliding surface 52 is disposed on the lower end side at the second end edge 56. The second sliding surface 52 is provided in the distal end portion of the leg portion 46. Meanwhile, the fourth sliding surface 54 is disposed on the upper end side at the second end edge 56. The main body portion 45 is provided with the fourth sliding surface 54. The fourth sliding surface 54 is positioned on the paper feeding roller 10 side of the parallel direction PD with respect to the second sliding surface 52. The fourth sliding surface 54 is disposed in the same planar shape as the second sliding surface 52. The second sliding surface 52 is provided with the recess 59 containing grease.
A second cutout portion 58 is provided between the second sliding surface 52 and the fourth sliding surface 54. The second cutout portion 58 opens on the upstream side of the conveyance direction TD. The second cutout portion 58 depresses on the downstream side of the conveyance direction TD with respect to the second sliding surface 52 and the fourth sliding surface 54.
The holder 60 supports the end portions 32 of the shaft 30 via the rotation stopping portions 40. The holder 60 is configured with a resin material. The holder 60 is disposed on the lower side of the separation roller 20.
The holder 60 includes two supporting portions 69 that each support the rotation stopping portions 40. As illustrated in
The first facing wall 61 and the second facing wall 62 face each other in the conveyance direction TD. The first facing wall 61 and the second facing wall 62 each extend in the parallel direction PD. The bottom wall portion connects the lower end portion of the first facing wall 61 and the lower end portion of the second facing wall 62.
The first facing wall 61 includes a first guide surface 66 that faces the upstream side of the conveyance direction TD. The second facing wall 62 includes a second guide surface 67 that faces the downstream side of the conveyance direction. The supporting portion 69 is provided with the first guide surface 66 and the second guide surface 67. The first guide surface 66 and the second guide surface 67 each include a flat surface extending in the parallel direction PD. The first guide surface 66 and the second guide surface 67 face each other in the conveyance direction TD.
The rotation stopping portion 40 is inserted between the first guide surface 66 and the second guide surface 67.
The first guide surface 66 faces the first sliding surface 51 and the third sliding surface 53 of the rotation stopping portion 40. The first sliding surface 51 and the third sliding surface 53 face the first guide surface 66 on the downstream side of the conveyance direction TD with respect to the second rotation axis J2. The first sliding surface 51 faces the first guide surface 66 on the paper feeding roller 10 side of the parallel direction PD with respect to the second rotation axis J2. The third sliding surface 53 faces the first guide surface 66 on the opposite side of the paper feeding roller 10 in the parallel direction PD with respect to the second rotation axis J2.
The second guide surface 67 faces the second sliding surface 52 and the fourth sliding surface 54 of the rotation stopping portion 40. The second sliding surface 52 and the fourth sliding surface 54 face the second guide surface 67 on the upstream side of the conveyance direction TD with respect to the second rotation axis J2. The second sliding surface 52 and the fourth sliding surface 54 face the second guide surface 67 on the opposite side of the paper feeding roller 10 in the parallel direction PD with respect to the second rotation axis J2.
The shaft 30 is pressed against the paper feeding roller 10 side by the pressure unit 80. If the sheet S is interposed between the paper feeding roller 10 and the separation roller 20, the interaxial distance between the first rotation axis J1 and the second rotation axis J2 changes. Here, the first sliding surface 51 and the third sliding surface 53 slide in the parallel direction PD with respect to the first guide surface 66. The second sliding surface 52 and the fourth sliding surface 54 slide in the parallel direction PD with respect to the second guide surface 67.
The width dimension of the rotation stopping portion 40 in the conveyance direction TD is slightly smaller than the distance between the first guide surface 66 and the second guide surface 67. The rotation stopping portion 40 can smoothly slide between the first guide surface 66 and the second guide surface 67.
The rotation stopping portion 40 faces the first guide surface 66 on the two sliding surfaces (the first sliding surface 51 and the third sliding surface 53) on the downstream side of the conveyance direction TD with respect to the second rotation axis J2. The rotation stopping portion 40 faces the second guide surface 67 on the two sliding surfaces (the second sliding surface 52 and the fourth sliding surface 54) on the upstream side of the conveyance direction TD with respect to the second rotation axis J2. According to the present embodiment, a large sliding area of the rotation stopping portion 40 in the parallel direction PD can be secured, and sliding efficiency can be improved. A plurality of sliding surfaces realize the rotation stop regardless of the direction of the rotation stopping portion 40 to which the moment is applied.
In the first end edge 55 of the rotation stopping portion 40, the first cutout portion 57 is provided between the first sliding surface 51 and the third sliding surface 53. The first sliding surface 51 and the third sliding surface 53 are partitioned by the first cutout portion 57. In the second end edge 56, the second cutout portion 58 is provided between the second sliding surface 52 and the fourth sliding surface 54. The second sliding surface 52 and the fourth sliding surface 54 are partitioned by the second cutout portion 58. The rotation stopping portion 40 comes into contact with the first guide surface 66 and the second guide surface 67 in a limited area. The dimension of the rotation stopping portion 40 is easily managed.
In the present embodiment, a portion between the first sliding surface 51 and the third sliding surface 53, and the first guide surface 66 is filled with grease that reduces the sliding resistance. A portion between the second sliding surface 52 and the fourth sliding surface 54, and the second guide surface 67 is filled with grease that reduces the sliding resistance.
The first sliding surface 51, the second sliding surface 52, and the third sliding surface 53 are provided with the recesses 59 containing grease. The recess 59 has a groove shape extending in the axial direction of the second rotation axis J2. The grease in the recess 59 is supplied to the first sliding surface 51, the second sliding surface 52, and the third sliding surface 53 and constantly reduces the sliding resistance.
According to the present embodiment, the fourth sliding surface 54 is not provided with the recess 59. However, all of the sliding surfaces (the first sliding surface 51, the second sliding surface 52, the third sliding surface 53, and the fourth sliding surface 54) may be provided with the recesses 59. If at least one sliding surface of all of the sliding surfaces is provided with the recess 59, a consistent effect can be obtained in view of the smoothness of sliding.
If the sheet S is conveyed to the downstream side of the conveyance direction TD, the moment is applied to the rotation stopping portion 40 as the reaction force of the torque limiter 39. The direction of the moment applied to the rotation stopping portion 40 is clockwise in
According to the present embodiment, the rotation stopping portion 40 includes the first sliding surface 51 and the second sliding surface 52. The first sliding surface 51 comes into contact with the first guide surface 66 on the downstream side of the conveyance direction TD and the separation roller 20 side of the parallel direction PD with respect to the second rotation axis J2. Meanwhile, the second sliding surface 52 comes into contact with the second guide surface 67 on the upstream side of the conveyance direction TD and the opposite side of the separation roller 20 in the parallel direction PD with respect to the second rotation axis J2. The moment applied to the separation roller 20 during the conveyance of the sheet S is effectively received on the first guide surface 66 and the second guide surface 67. The first sliding surface 51 and the second sliding surface 52 each are separated from the second rotation axis J2 in the parallel direction PD. The reaction force of the first guide surface 66 and the second guide surface 67 decreases. As a result, the sliding resistance applied between the first sliding surface 51 and the first guide surface 66 and between the second sliding surface 52 and the second guide surface 67 is reduced.
As illustrated in
Slight gaps are provided between the first sliding surface 51 and the first guide surface 66 and between the second sliding surface 52 and the second guide surface 67. If the clockwise moment (
Based on
The force that the separation roller 20 applies to the sheet S during the conveyance of the sheet S is set as separating force T. The separation roller 20 receives the force of the separating force T from the sheet S as the reaction force. A moment of a product of the separating force T and a radius Lt of the separation roller 20 (T×Lt) is applied to the rotation stopping portion 40.
Meanwhile, the rotation stopping portion 40 comes into contact with the first guide surface 66 in the first sliding surface 51 and receives first reaction force N1. The rotation stopping portion 40 comes into contact with the second guide surface 67 in the second sliding surface 52 and receives second reaction force N2. A moment of a sum of a product of the first reaction force N1 and the first distance L1 (N1×L1) and a product of the second reaction force N2 and the second distance L2 (N2×L2) is applied to the rotation stopping portion 40.
In view of the balance of the moment of the rotation stopping portion 40, Equation (1) is established.
T×Lt=(N1×L1)+(N2×L2) (1)
The balance of the force of the rotation stopping portion 40 during the conveyance of the sheet S is considered.
The separating force T and the second reaction force N2 as the reaction force toward the downstream side of the conveyance direction TD and the first reaction force N1 as the reaction force toward the upstream side of the conveyance direction TD are applied to the rotation stopping portion 40.
In view of the balance of the force of the rotation stopping portion 40, Equation (2) is established.
T+N2=N1 (2)
From Equation (2), the first reaction force N1 is always larger than the second reaction force N2. In order to smooth the sliding of the rotation stopping portion 40 in the supporting portion 69, it is important to reduce the first reaction force N1.
From Equations (1) and (2), Equations (3) and (4) are derived.
N1=T×(Lt+L2)/(L1+L2) (3)
N2=T×(Lt−L1)/(L1+L2) (4)
From Equations (3) and (4), the first reaction force N1 and the second reaction force N2 are reduced by causing the first distance L1 to be a value of larger than 0. According to the present embodiment, since the first distance L1 is a value of larger than 0, the first reaction force N1 is reduced, and the sliding of the rotation stopping portion 40 in the supporting portion 69 is smoothed.
The first distance L1 of the present embodiment is larger than a half of the radius Lt of the separation roller 20. The first reaction force N1 is effectively reduced by causing the first distance L1 to be larger than a half of the radius Lt of the separation roller 20.
The first distance L1 is preferably smaller than the radius Lt of the separation roller 20. If the first distance L1 is larger than the radius Lt of the separation roller 20, the first sliding surface 51 is disposed on the paper feeding roller 10 side with respect to the sheet S. Here, in order not to allow the rotation stopping portion 40 to prevent the conveyance of the sheet S, the first sliding surface 51 is disposed on the outside of the passage area of the sheet S. Here, there is a concern that the size of the paper feeding device 1 increases. According to the present embodiment, by causing the first distance L1 to be smaller than the radius Lt of the separation roller 20, the size of the paper feeding device 1 can be reduced.
From Equation (4), it is understood that the second reaction force N2 can be reduced by increasing the second distance L2. According to the present embodiment, since the second distance L2 is a sufficiently large value, the second reaction force N2 can be reduced, and the sliding of the rotation stopping portion 40 in the supporting portions 69 can be smoothed.
The second distance L2 of the present embodiment is larger than the radius Lt of the separation roller 20. The second reaction force N2 is effectively reduced by causing the second distance L2 to be larger than the radius Lt of the separation roller 20.
According to the present embodiment, the rotation stopping portions 40 are attached to the shaft 30 in the end portions 32 that interpose the separation roller 20. The holder 60 includes the two supporting portions 69 that each support the rotation stopping portions 40. The first reaction force N1 and the second reaction force N2 are received by the two rotation stopping portions 40 in a dispersed manner. The first reaction force N1 and the second reaction force N2 applied to each of the rotation stopping portions 40 can be reduced, and the sliding of the rotation stopping portions 40 can be smoothed. The rotation of the shaft 30 is restricted by the end portions 32 on both sides, and the skew of the shaft 30 is reduced.
As illustrated in
The second facing wall 62 of the supporting portion 69 includes a second rib (rib) 68. The second rib 68 extends in the parallel direction PD. The second rib 68 protrudes to the downstream side of the conveyance direction TD. The second rib 68 is provided with the second guide surface 67. The contact area between the supporting portion 69 and the second sliding surface 52 can be limited by providing the second guide surface 67 at the distal end of the second rib 68. Accordingly, the dimension of the second guide surface 67 is easily managed.
As illustrated in
According to the present embodiment, the leg portion 46 having the second sliding surface 52 is inserted into the through hole 64 of the holder 60. The second distance L2 can be secured to be large by providing the second sliding surface 52 in the leg portion 46. The dimension of the holder 60 in the parallel direction PD is reduced by inserting the leg portion 46 to the through hole 64. The size of the paper feeding device 1 can be reduced.
As illustrated in
According to the present embodiment, the sheet guide surface 72 is inclined to the conveyance direction TD. More specifically, the sheet guide surface 72 is inclined to the paper feeding roller 10 side toward downstream side of the conveyance direction TD when being viewed in the axial direction of the separation roller 20.
The sheet S is conveyed between the paper feeding roller 10 and the separation roller 20 in the conveyance direction TD. The sheet S is conveyed in a manner of being bent in contact with the sheet guide surface 72 on the downstream side of the paper feeding roller 10 and the separation roller 20.
The space of the separation roller 20 on the downstream side of the conveyance direction TD is secured to be large by causing the sheet guide surface 72 to be inclined to the paper feeding roller 10 side on the downstream side of the conveyance direction TD. The position of the first sliding surface 51 in the parallel direction PD can come closer to the paper feeding roller 10 side. The first distance L1 becomes large, and the sliding between the rotation stopping portion 40 and the supporting portion 69 becomes smooth.
As illustrated in
While certain embodiments have been described these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms: furthermore various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and there equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the invention.
This application is a Continuation of application Ser. No. 17/013,888 filed on Sep. 8, 2020, the entire contents of which are incorporated herein by reference.
Number | Name | Date | Kind |
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5738452 | Uchida | Apr 1998 | A |
6997453 | Matsuda et al. | Feb 2006 | B2 |
9033334 | Yano | May 2015 | B2 |
9796545 | Morizono et al. | Oct 2017 | B2 |
20060237895 | Nishikata et al. | Oct 2006 | A1 |
Entry |
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Non-Final Office Action for U.S. Appl. No. 17/013,888 dated Jun. 16, 2022. |
Number | Date | Country | |
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20230137449 A1 | May 2023 | US |
Number | Date | Country | |
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Parent | 17013888 | Sep 2020 | US |
Child | 18089625 | US |