Patent Application
20240208758
This application claims priority from Japanese Patent Application No. 2022-207844 filed on Dec. 26, 2022. The entire content of the priority application is incorporated herein by reference.
There has been conventionally known a sheet discharging device includes a first rotation shaft, a second rotation shaft, a first discharging roller body, a second discharging roller body, and a sheet stacking portion.
The first rotation shaft and the second rotation shaft extend in a width direction orthogonal to a direction in which a sheet is conveyed toward the sheet stacking portion. The first rotation shaft is positioned upward relative to the second rotation shaft. The first discharging roller body is configured to rotate together with the first rotation shaft. The second discharging roller body is configured to rotate together with the second rotation shaft. The first discharging roller body is positioned offset from the second discharging roller body in the width direction. The lower end of the outer circumferential surface of the first discharging roller body is positioned downward relative to the upper end of the outer circumferential surface of the second discharging roller body.
The first discharging roller body and the second discharging roller body are configured to convey the sheet in a discharging direction. The sheet stacking portion is configured to support the sheet discharged thereon. At this time, the first discharging roller body and the second discharging roller body enhances the rigidity of the sheet by deforming the sheet into a wavy shape when viewed in the discharging direction, stabilizing the posture of the sheet being discharged.
Also, the conventional sheet discharging device further includes a contacting flag member, which is a part of a discharge detection sensor. The contacting flag member extends in the discharging direction from a position upper than the first rotation shaft while sloping downward. The contacting flag member also has a function to drop the rear end of the sheet onto the sheet stacking portion after the sheet has passed between the first discharging roller body and the second discharging roller body.
With this configuration, the conventional sheet discharging device attempts to improve the stacking performance of the sheets discharged on the sheet stacking portion.
However, it is difficult to make the conventional sheet discharging device compact in the up-down direction since the first rotation shaft and the first discharging roller body are positioned further upward than the second rotation shaft in the conventional sheet discharging device. In addition, the above-described configuration that the contacting flag member extends in the discharging direction from a position upper than the first rotation shaft while sloping downward is also a factor that makes it challenging to make the conventional sheet discharging device compact in the up-down direction.
In view of the foregoing, it is an object of the present disclosure to provide a sheet discharging device which can be made compact in the up-down direction while enhancing the stacking performance of the sheets discharged onto the discharge tray with a simple structure.
In order to attain the above and other objects, according to one aspect, the present disclosure provides a sheet discharging device including a lower sheet guide, a discharging roller, a plurality of elastic pieces, and a discharge tray. The lower sheet guide has an upper surface configured to guide a sheet. The discharging roller includes a shaft and a roller body. The shaft is positioned downward relative to the upper surface. The shaft extends in a width direction orthogonal to a conveying direction of the sheet being guided by the upper surface. The roller body is configured to rotate together with the shaft. The roller body is configured to convey the sheet being guided by the upper surface in a discharging direction. Each of the plurality of elastic pieces protrudes in the discharging direction. Each elastic piece is arranged upward relative to the shaft and offset from the roller body in the width direction. The discharge tray is configured to support the sheet discharged by the discharging roller. Each elastic piece has a surface facing downward. The surface of each elastic piece has a portion directly above the shaft. The portion is positioned downward relative to an upper end of an outer circumferential surface of the roller body in a state where the portion is not in contact with the sheet being guided by the upper surface. The plurality of elastic pieces includes a first elastic piece and a plurality of second elastic pieces. The first elastic piece includes a bending portion bent toward the discharge tray. The bending portion is positioned downstream in the discharging direction relative to the shaft. Each of the plurality of second elastic pieces is shorter than the first elastic piece. Each second elastic piece does not include a bending portion bent toward the discharge tray. The first elastic piece and the plurality of second elastic pieces are alternately arranged in the width direction.
According to another aspect, the present disclosure provides a sheet discharging device including a lower sheet guide, a discharging roller, a pressing member, and a discharge tray. The lower sheet guide has an upper surface configured to guide a sheet. The discharging roller includes a shaft and a roller body. The shaft is positioned downward relative to the upper surface. The shaft extends in a width direction orthogonal to a conveying direction of the sheet being guided by the upper surface. The roller body is configured to rotate together with the shaft. The roller body is configured to convey the sheet being guided by the upper surface in a discharging direction. The pressing member is configured to press the sheet being discharged by the discharging roller. The pressure member includes a plurality of elastic pieces protruding in the discharging direction. Each elastic piece is arranged upward relative to the shaft and offset from the roller body in the width direction. The discharge tray is configured to support the sheet discharged by the discharging roller. Each elastic piece has a surface facing downward. The surface of each elastic piece has a portion directly above the shaft. The portion is positioned downward relative to an upper end of an outer circumferential surface of the roller body in a state where the portion is not in contact with the sheet being guided by the upper surface. The plurality of elastic pieces includes a first elastic piece and a plurality of second elastic pieces. The first elastic piece includes a bending portion bent toward the discharge tray. The bending portion is positioned downstream in the discharging direction relative to the shaft. Each of the plurality of second elastic pieces is shorter than the first elastic piece. Each second elastic piece does not include a bending portion bent toward the discharge tray. The first elastic piece and the plurality of second elastic pieces are alternately arranged in the width direction.
Hereinafter, first through fourth embodiments of the present disclosure will be described while referring to the accompanying drawings.
<First Embodiment>
As illustrated in
As illustrated in
<Overall Structure>
As illustrated in
As illustrated in
The main body 8 includes two platen glasses, which constitute the upper surface of the main body 8. One platen glass of the two platen glasses has a large area. The upper surface of the one platen glass constitutes the original document supporting surface 3A. The other platen glass of the two platen glasses is slender and elongated in the front-rear direction and is positioned leftward of the original document supporting surface 3A. The upper surface of the other platen glass constitutes the reading surface 3B.
The original document supporting surface 3A supports an original document to be subjected to image-reading. Examples of the original document to be subjected to image-reading include a sheet such as a sheet of paper and a transparent plastic film (overhead projector sheets), and a book. The reading surface 3B is used when a conveying unit 4 described later operates.
The reading sensor 3S is a well-known image-reading sensor, such as a contact image sensor (CIS), a charge coupled device (CCD), or other types of sensors. The reading sensor 3S is slender and elongated in the front-rear direction. The reading sensor 3S is positioned downward relative to both the original document supporting surface 3A and reading surface 3B.
In a case where the image-reading unit 3 reads an image formed on the original document supported by the original document supporting surface 3A, the reading sensor 3S reads the image of the original document by the operation of the scanning mechanism (not illustrated). More specifically, the reading sensor 3S is configured to read the image of the original document line by line, which extends in the front-rear direction (i.e., in a main scanning direction), while moving rightward (i.e., in a sub scanning direction) from a position below the left end edge of the original document supporting surface 3A. When the reading sensor 3S has moved to a position below the right end edge of the original document supporting surface 3A, the reading sensor 3S finishes the reading of the image and returned to a standby position by the operation of the scanning mechanism (not illustrated).
Note that, when the conveying unit 4 described later operates, the reading sensor 3S moves to a static reading position below the reading surface 3B by the operation of the scanning mechanism (not illustrated) and rests at the static reading position.
As illustrated in
As illustrated in
The bottom surface of the cover 9 is of a size that can cover the entire upper surface of the main body 8. The cover 9 uses the lower surface of the base member 39 to cover the original document placed on the original document supporting surface 3A.
Although not illustrated, when a user pivotally moves the cover 9 upward and rearward about the pivot axis X9, the cover 9 exposes the original document supporting surface 3A. In a state where the original document supporting surface 3A is exposed, a user can place the original document on the original document supporting surface 3A and take the original document out of the image-reading device 1.
As illustrated in
The discharge tray 96 is constituted by the upper surface of the right portion of the base member 39. The feeding tray 91 is positioned above the discharge tray 96. The feeding tray 91 supports the sheets SH to be subjected to image-reading in a stacked state.
Note that, in the present embodiment, an object to be subjected to image-reading using the original document supporting surface 3A will be referred to as the “original document”. An object to be subjected to image-reading while being conveyed by the conveying unit 4 will be referred to as the “sheet SH”. The original document and the sheet SH may be substantially the same as each other.
The feeding tray 91 includes a side guide 92A and a side guide 92B. The side guides 92A and 92B are configured to slide both toward and away from each other in the front-rear direction. With this configuration, the side guides 92A and 92B can position the sheets SH of various sizes supported on the feeding tray 91 in the front-rear direction. In the present embodiment, examples of the sheets SH to be subjected to image-reading include a postcard, an A4-size paper, and an A5-size paper.
As illustrated in
The conveying unit 4 includes a feeding roller 41, a separating roller 42, a separating pad 42A, a pair of first conveying rollers 43, a pressure member 44, a pair of second conveying rollers 45, a discharging roller 47, and plurality of elastic pieces 100. The pair of second conveying rollers 45 is an example of the “pair of conveying rollers” of the present disclosure.
The feeding roller 41 faces the left end portion of the feeding tray 91 from above. The separating roller 42 and the separating pad 42A are positioned leftward relative to the feeding roller 41. The pair of first conveying rollers 43 is positioned near the left side wall of the cover 9 and near the upper surface of the main body 8. The pressure member 44 is positioned directly above the reading surface 3B.
The first conveying guide 35 and the second conveying guide 36 are configured of some of chute members provided inside the cover 9 and libs protruding downward from the lower surface of the upper wall of the cover 9.
The first conveying guide 35 is configured to guide the sheet SH from the left end portion of the feeding tray 91 to the pair of first conveying rollers 43.
The second conveying guide 36 is configured to guide the sheet SH from the pair of the first conveying rollers 43 to the reading surface 3B in a direction sloped downward (i.e., in a diagonal direction sloping downward and rightward) so that the sheet SH passes between the pressure member 44 and the reading surface 3B (i.e., so that the sheet SH passes through an area above the reading sensor 3S positioned at the static reading position).
The lower sheet guide 31 is provided at the left portion of the base member 39. The lower sheet guide 31 has an upper surface 31G. The upper surface 31G is a sloped surface facing upward. The upper surface 31G extends from a position rightward of the reading surface 3B in a diagonal direction sloping upward and rightward. The upper surface 31G also extends in the front-rear direction.
The upper sheet guide 32 is positioned upward relative to the lower sheet guide 31. The upper sheet guide 32 has a lower surface 32G. The lower surface 32G faces the upper surface 31G of the lower sheet guide 31 from above. The lower surface 32G is a sloped surface facing downward. The lower surface 32G extends from a position rightward of the reading surface 3B in a diagonal direction sloping upward and rightward. The lower surface 32G also extends in the front-rear direction.
The upper surface 31G of the lower sheet guide 31 and the lower surface 32G of the upper sheet guide 32 define a discharge path P1 therebetween. In other words, the discharge path P1 is defined between the upper surface 31G and the lower surface 32G. The upper surface 31G and the lower surface 32G are configured to guide the sheet SH along the discharge path P1 in a conveying direction D1 after the sheet SH has passed between the pressure member 44 and the reading surface 3B.
The conveying direction D1 of the sheet SH being guided by the upper surface 31G and the lower surface 32G (i.e., a direction in which the sheet SH is conveyed while guided by the upper surface 31G and the lower surface 32G) is a diagonal direction sloping upward and rightward. A width direction, which is orthogonal to the conveying direction D1, is the front-rear direction. In the present embodiment, the width direction encompasses two opposite directions: one direction is the frontward direction, and the other direction is the rearward direction.
As illustrated in
After the sheet SH has been guided by the upper surface 31G of the lower sheet guide 31 and the lower surface 32G of the upper sheet guide 32 in the conveying direction D1, the sheet SH is guided in a discharging direction D2 at the right end portion of the upper surface 31G. The discharging direction D2 is the rightward direction in the approximately horizontal direction.
The base member 39 has a regulating surface 97 positioned between the lower sheet guide 31 and the discharge tray 96. The discharge tray 96 has an upstream end 96E in the discharging direction D2. The regulating surface 97 is a flat surface facing in the discharging direction D2 and connected to the upstream end 96E of the discharge tray 96. The regulating surface 97 extends upward in the vertical direction and also extends in the width direction.
The regulating surface 97 has an upper end connected to the right end of the upper surface 31G. The regulating surface 97 is configured to regulate the position of the upstream end of the sheet SH in the discharging direction D2 that has been guided along the discharge path P1 and discharged onto the discharge tray 96.
An elastic piece holding portion 32H is fixed to the upper surface of the right end portion of the upper sheet guide 32. The elastic piece holding portion 32H is elongated from one end to the other end of the upper sheet guide 32 in the front-rear direction, and slightly extends in the left-right direction.
The pair of second conveying rollers 45 is positioned downstream relative to the center portion of the discharge path P1 and upstream relative to the discharging roller 47 in the discharging direction D2. The pair of second conveying rollers 45 includes a driving shaft 45S, two driving rollers 45A and two follow rollers 45B. The driving rollers 45A are each an example of the “driving roller body” in the present disclosure. The two follow rollers 45B are each an example of the “follow roller body” in the present disclosure.
The driving shaft 45S is positioned upward relative to the lower surface 32G of the upper sheet guide 32 and extends in the width direction. As illustrated in
A first gear 21 is fixed to one end portion of the driving shaft 45S in the width direction. The first gear 21 is positioned further in the one direction in the width direction than both the upper surface 31G of the lower sheet guide 31 and the lower surface 32G of the upper sheet guide 32. That is, the first gear 21 is positioned further in the one direction in the width direction than the discharge path P1. In the present embodiment, the first gear 21 is positioned frontward relative to both the upper surface 31G and the lower surface 32G. In other words, the first gear 21 is positioned frontward relative to the discharge path P1.
The driving shaft 45S is configured to rotate by receiving a driving force transmitted from a motor M1 via a drive train (not illustrated). The motor M1 is positioned further in the other direction in the width direction than the discharge path P1. With this configuration, the two driving rollers 45A and the first gear 21 rotate together with the driving shaft 45S.
As illustrated in
The pair of second conveying rollers 45 is configured to convey the sheet SH being guided by the upper surface 31G of the lower sheet guide 31 and the lower surface 32G of the upper sheet guide 32 toward the discharging roller 47.
As illustrated in
As illustrated in
Each end portion of the outer circumferential surface 48A of each roller 48 in the width direction has a paddle 48P. The paddle 48P includes a plurality of protrusions arranged apart from one another in the circumferential direction of the outer circumferential surface 48A. At the time of the roller 48 finishing conveyance of the sheet SH, the protrusions of the paddles 48P can push out the sheet SH by contacting the left end of the sheet SH (i.e., the upstream end of the sheet SH in the conveying direction D2).
A second gear 22 is fixed to one end portion of the shaft 49 in the width direction. The second gear 22 is positioned further in the one direction in the width direction than the discharge path P1. The second gear 22 is meshingly engaged with the first gear 21.
The second gear 22 is configured to receive a driving force transmitted from the driving shaft 45S via the first gear 21, whereby the second gear 22 and the two rollers 48 rotate together with the shaft 49.
The two rollers 48 are configured to convey the sheet SH being guided by the upper surface 31G of the lower sheet guide 31 and the lower surface 32G of the upper sheet guide 32 in the discharging direction D2 and to discharge the sheet SH onto the discharge tray 96. The positions of the two rollers 48 in the up-down direction are higher than those of the two follow rollers 45B, and accordingly, the maximum number of the sheets SH that can be stacked on the discharge tray 96 is increased by the height difference.
As illustrated in
In the present embodiment, the elastic pieces 100 are film-like members and are manufactured by being cutting out from PET (polyethylene terephthalate) films, for example. Each elastic piece 100 has a thickness that can provide such rigidity that the elastic piece 100 does not bend when the elastic piece 100 comes into contact with the sheet SH. In the present embodiment, each elastic piece 100 is configured of a PET film having a thickness of 25 μm.
As illustrated in
As illustrated in
Each first elastic piece 110 protrudes in the discharging direction D2 from the upstream end portion 110E while slightly sloping downward. Each first elastic piece 110 extends across the discharge path P1 in a state where the first elastic piece 110 is not in contact with the sheet SH being guided by the upper surface 31G of the lower sheet guide 31.
Each first elastic piece 110 has a lower surface facing downward. The lower surface of each first elastic piece 110 includes a portion 110S that is positioned directly above the shaft 49. Each portion 110S is positioned downward relative to an upper end 48A1 of the outer circumferential surface 48A of each roller 48 in a state where the portion 110S is not in contact with the sheet SH being guided by the upper surface 31G of the lower sheet guide 31.
Each first elastic piece 110 includes a bending portion 112 and a portion 110A. The bending portion 112 is positioned downstream relative to the shaft 49 in the discharging direction D2 and is bent toward the discharge tray 96. The portion 110A is a portion positioned downstream relative to the bending portion 112 in the discharging direction D2. The portion 110A has a flat-plate shape extending toward the discharge tray 96. The portion 110A slopes downward in the discharging direction D2. More specifically, the bending portion 112 is positioned downstream relative to the regulating surface 97 in the discharging direction D2.
The outer circumferential surface 48A of each roller 48 has a downstream end 48A2 in the discharging direction D2. The downstream end 48A2 and the bending portion 112 of the first elastic piece 110 are spaced apart from each other by a distance L1 in the discharging direction D2. The outer circumferential surface 48A has a diameter L2. The distance L1 is smaller than the diameter L2.
As illustrated in
Similarly to the first elastic pieces 110, each second elastic piece 120 also protrudes in the discharging direction D2 from the upstream end portion 120E while slightly sloping downward. Each second elastic piece 120 extends across the discharge path P1 in a state where the second elastic piece 120 is not in contact with the sheet SH being guided by the upper surface 31G of the lower sheet guide 31.
Each second elastic piece 120 has a lower surface facing downward. The lower surface of each second elastic piece 120 includes a portion 120S that is positioned directly above the shaft 49. Similarly to the above-described portions 110S of the first elastic pieces 110, each portion 120S is positioned downward relative to the upper end 48A1 of the outer circumferential surface 48A of each roller 48 in a state where the portion 120S is not in contact with the sheet SH being guided by the upper surface 31G of the lower sheet guide 31.
Each second elastic piece 120 does not include a bending portion bent toward the discharge tray 96 on the downstream side of the shaft 49 in the discharging direction D2. Also, the downward inclination angle of the portion of the first elastic piece 110 which extends from the upstream end portion 110E to the bending portion 112 is the same as the downward inclination angle of the portion of the second elastic piece 120 which extends from the upstream end portion 120E to the downstream end portion 120F.
The downstream end portion 120F of each second elastic piece 120 is positioned within a range A1 in the discharging direction D2 from the regulating surface 97 to the bending portion 112 of the first elastic piece 110. In other words, with respect to the discharging direction D2, the downstream end portion 120F of each second elastic piece 120 is positioned within the range A1 from the regulating surface 97 to the bending portion 112 of the first elastic piece 110. In the present embodiment, the position in the discharging direction D2 of the downstream end portion 120F of the second elastic piece 120 is the same as the position in the discharging direction D2 of the bending portion 112 of the first elastic piece 110. That is, the second elastic piece 120 is shorter than the first elastic piece 110.
As illustrated in
As described above, the elastic pieces 100 include the two second elastic pieces 120. In the width direction, one of the two second elastic pieces 120 is positioned further in the one direction than the one of the rollers 48, which is positioned further in the one direction in the width direction than the other of the two rollers 48. In the width direction, the other of the two second elastic pieces 120 is positioned further in the other direction than the other of the two rollers 48, which is positioned further in the other direction in the width direction than the one of the two rollers 48. In other words, the two rollers 48 are positioned between the two second elastic pieces 120 in the width direction.
The two second elastic pieces 120 are spaced apart from each other by a distance in the width direction. The distance in the width direction between the two second elastic pieces 120 is smaller than both the length in the width direction of a postcard and the length in the width direction of an A5-size paper. Hence, when the conveying unit 4 conveys the sheets SH such as the postcard, the A4-size paper, and the A5-size paper, the two second elastic pieces 120 contact all of such types of the sheets SH.
As described above, the elastic pieces 100 include the two first elastic pieces 110 besides the first elastic piece 110 that is positioned between the two rollers 48. One of the two first elastic pieces 110 is positioned further in the one direction in the width direction than the one of the two second elastic pieces 120, which is positioned further in the one direction in the width direction than the other of the two second elastic pieces 120. The other of the two first elastic pieces 110 is positioned further in the other direction in the width direction than the other of the two second elastic pieces 120, which is positioned further in the other direction in the width direction than the one of the two second elastic pieces 120. In other words, the two second elastic pieces 120 are positioned between the two first elastic pieces 120 in the width direction.
That is, the first elastic pieces 110 and the second elastic pieces 120 are alternately arranged in the width direction.
As illustrated in
As illustrated in
The image-reading device 1 further includes a contacting portion 98. Specifically, a part of the back surface of the feeding tray 91 is configured of a member having a surface facing downward which serves as the contacting portion 98. That is, the contacting portion 98 is the surface of the member which faces downward. As illustrated in
According to the image-reading device 1 of the first embodiment, in a case where the image-reading unit 3 reads an image formed on the sheet SH supported by the feeding tray 91, the feeding roller 41, the separating roller 42 and the separating pad 42A of the conveying unit 4 convey the sheets SH supported by the feeding tray 91 one by one.
Next, the pair of first conveying rollers 43 conveys the sheet SH being guided by both the first conveying guide 35 and the second conveying guide 36 to cause the sheet SH to pass above the reading sensor 3S positioned at the static reading position. With this configuration, the reading sensor 3S reads the image formed on the surface of the sheet SH.
Thereafter, the pair of second conveying rollers 45 conveys toward the discharging roller 47 the sheet SH being guided by both the upper surface 31G of the lower sheet guide 31 and the lower surface 32G of the upper sheet guide 32. The rollers 48 of the discharging roller 47, the first elastic pieces 110, and the second elastic pieces 120 convey the sheet SH in the discharging portion D2 to discharge the sheet SH onto the discharge tray 96.
At this time, as illustrated in
With this configuration, in comparison with a configuration that includes neither the discharging roller 47, nor the first elastic pieces 110 nor the second elastic pieces 120, the maximum number of the sheets SH that can be stacked on the discharge tray 96 can be increased, thereby enhancing the certainty of discharge of the sheets SH and stabilizing the postures of the sheets SH being discharged.
As illustrated in
As illustrated in
As a result, the image-reading device 1 can suppress the stacking order of the sheets SH discharged on the discharge tray 96 from being changed and can also suppress the sheets SH from being jammed.
In the image-reading device 1 of the present embodiment, components corresponding to a first shaft, a first discharging roller, and a contacting flag member which are provided in a conventional sheet discharging device do not exist at positions upward relative to the rollers 48.
Accordingly, with a simple structure, the image-reading device 1 of the first embodiment can be made compact in the up-down direction and the stacking performance of the sheets SH discharged on the discharge tray 96 can be enhanced.
As illustrated in
Further, in the image-reading device 1, as illustrated in
According to the image-reading device 1, the distance L1 in the discharging direction D2 between the bending portion 112 of the first elastic piece and the downstream end 48A2 of the outer circumferential surface 48A of the roller 48 in the discharging direction D2 is smaller than the diameter L2 of the outer circumferential surface 48A. With this configuration, a sufficient maximum height of the pile of the discharged sheets SH that can stacked on the discharge tray 96 can be ensured and change in the stacking order of the sheets SH discharged on the discharge tray 96 can be suppressed by the portions 110A of the first elastic pieces 110, which are positioned downstream relative to the bending portions 112 in the discharging direction D2.
Further, according to the image-reading device 1, with respect to the discharging direction D2, the downstream end portions 120F of the second elastic pieces 120 in the discharging direction D2 are positioned within the range A1 from the regulating surface 97 to the bending portions 112 of the first elastic pieces 110 as illustrated in
According to the image-reading device 1, as illustrated in
Furthermore, according to the image-reading device 1, the elastic pieces 100 include the two second elastic pieces 120 as described above. One of the two second elastic pieces 120 is positioned further in the one direction in the width direction than the one of the two rollers 48, which is positioned further in the one direction in the width direction than the other of the two rollers 48. The other of the two second elastic pieces 120 is positioned further in the other direction in the width direction than the other of the two rollers 48, which is positioned further in the other direction in the width direction than the one of the two rollers 48. This configuration can achieve with a high level of certainty that the two second elastic pieces 120 press the sheet SH against the outer circumferential surfaces 48A of the two rollers 48, regardless of the size of the sheet SH being discharged.
According to the image-reading device 1, the elastic piece 100 further includes the remaining two first elastic pieces 110 as described above. One of the remaining two first elastic pieces 110 is positioned further in the one direction in the width direction than the one of the two second elastic pieces 120, which is positioned further in the one direction in the width direction than the other of the two second elastic pieces 120. The other of the remaining two first elastic pieces 110 is positioned further in the other direction in the width direction than the other of the two second elastic pieces 120, which is positioned further in the other direction in the width direction than the one of the two second elastic pieces 120. This configuration can achieve with a high level of certainty that, when the sheet SH having a large size is discharged, the two first elastic pieces 110 positioned outward of the two second elastic pieces 120 in the width direction drop the sheet SH onto the discharge tray 96 while suppressing the sheet SH from being curled by pressing the sheet SH toward the discharge tray 96.
In addition, according to the image-reading device 1, the length WL1A in the width direction of the first elastic piece 110 positioned between the two rollers 48 is greater than the length WL1B in the width direction of the remaining two first elastic pieces 110. This configuration can achieve with a high level of certainty that, when the sheet SH having a small size and a high stiffness, such as a postcard, is discharged, the first elastic piece 110 positioned between the two rollers 48 drops the sheet SH onto the discharge tray 96 while suppressing the sheet SH from being curled by pressing the sheet SH toward the discharge tray 96.
According to the image-reading device 1, the first elastic pieces 110 and the second elastic pieces 120 have a film-like shape. Hence, the first elastic pieces 110 and the second elastic pieces 120 can be easily manufactured at a low cost.
Moreover, as illustrated in
As illustrated in
As illustrated in
Also, in the second embodiment, the downstream end portions 120F of the two second elastic pieces 120 in the discharging direction D2 are positioned upstream in the discharging direction D2 relative to the bending portions 112 of the first elastic pieces 110 within the range A1, unlike the downstream end portions 120F of the two second elastic pieces 120 in the first embodiment.
Further, in the second embodiment, ribs 32H1 are provided on the upper surface of the elastic piece holding portion 32H to fix the first elastic pieces 110 and the second elastic pieces 120 in position. Each rib 32H1 has an approximately C-shape in a plan view and surrounds the upstream end portion 110E of the corresponding first elastic piece 110 and the upstream end portion 120E of the corresponding second elastic piece 120 from the left side and from the outside in the width direction, as illustrated in
Since the other parts and components in the second embodiment are identical to those in the first embodiment, like parts and components are designated with the same reference numerals and duplicate descriptions are omitted.
Similarly to the image-reading device 1 of the first embodiment, with a simple structure, the image-reading device of the second embodiment can be made compact in the up-down direction and the stacking performance of the sheets SH discharged on the discharge tray 96 can be enhanced.
As illustrated in
In the third embodiment, columnar portions 32H2 are provided on the upper surface of the elastic piece holding portion 32H to fix the first elastic pieces 110 and second elastic pieces 120 in position. The columnar portions 32H2 are linearly arranged in the width direction and spaced apart from one another in the width direction.
The first elastic piece 110 positioned between the two rollers 48 is formed with a round hole 115A and an elongated hole 115B, which are spaced apart from each other in the width direction. By inserting the columnar portions 32H2 into the round hole 115A and the elongated hole 115B, the accuracy of positioning the first elastic piece 110 when attaching the first elastic piece 110 to the upper surface of the elastic piece holding portion 32H can be enhanced.
Each of the two pairs of the first elastic piece 110 and the second elastic piece 120 positioned outward relative to the two rollers 48 in the width direction also has a round hole the same as the round hole 115A and an elongated hole the same as the elongated hole 115B.
Since the other parts and components in the third embodiment are identical to those in the first embodiment, like parts and components are designated with the same reference numerals and duplicate descriptions are omitted.
Similarly to the image-reading device 1 of the first embodiment and the image-reading device of the second embodiment, with a simple structure, the image-reading device of the third embodiment can be made compact in the up-down direction and the stacking performance of the sheets SH discharged on the discharge tray 96 can be enhanced.
As illustrated in
Since the other parts and components in the fourth embodiment are identical to those in the first embodiment, like parts and components are designated with the same reference numerals and duplicate descriptions are omitted.
Similarly to the image-reading device 1 of the first embodiment and the image-reading devices of the second and third embodiments, with a simple structure, the image-reading device of the fourth embodiment can be made compact in the up-down direction and the stacking performance of the sheets SH discharged on the discharge tray 96 can be enhanced.
In the image-reading device according to the fourth embodiment, the portions 110A of the first elastic pieces 110 which are positioned downstream in the discharging direction D2 relative to the bending portions 112 are reinforced by the reinforcement plates 119. This configuration can achieve with a high level of certainty that the first elastic pieces 110 drop the sheet SH being discharged onto the discharge tray 96 while suppressing the sheet SH from being curled by pressing the sheet SH toward the discharge tray 96.
While the invention has been described in conjunction with various example structures outlined above and illustrated in the figures, various alternatives, modifications, variations, improvements, and/or substantial equivalents, whether known or that may be presently unforeseen, may become apparent to those having at least ordinary skill in the art.
Accordingly, the example embodiments of the disclosure, as set forth above, are intended to be illustrative of the invention, and not limiting the invention. Various changes may be made without departing from the spirit and scope of the disclosure. Therefore, the disclosure is intended to embrace all known or later developed alternatives, modifications, variations, improvements, and/or substantial equivalents. Some specific examples of potential alternatives, modifications, or variations in the described invention are provided below:
In the first through fourth embodiments, the upstream end portions 110E of the first elastic pieces 110 and the upstream end portions 120E of the second elastic pieces 120 are held by the upper sheet guide 32 via the elastic piece holding portion 32H. However, the present disclosure is not limited to this configuration. For example, the upstream end portions 110E of the first elastic pieces 110 and the upstream end portions 120E of the second elastic pieces 120 may be held directly by the upper sheet guide 32.
In the fourth embodiment, each reinforcement plate 119 reinforces the entire portion 110A of the corresponding first elastic piece 110, which is positioned downstream in the discharging direction D2 relative to the bending portion 112. However, the present disclosure is not limited to the configuration. For example, the reinforcement plate 119 may reinforce a part of the portion 110A of the corresponding first elastic piece 110, which is positioned downstream in the discharging direction D2 relative to the bending portion 112.
The present disclosure can be applied to other sheet discharging devices, such as an image-forming device, image-reading device, a multifunction peripheral having an image forming function and an image reading function.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2022-207844 | Dec 2022 | JP | national |
