This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2020-145005 filed Aug. 28, 2020.
The present disclosure relates to a sheet feeder and an image forming apparatus.
Japanese Unexamined Patent Application Publication No. 2016-000653 discloses a sheet feeder that includes a housing, a feed tray including a mount plate that receives sheets and that is slidably attached to the inside and outside of the housing, a transport device that transports sheets stacked on the mount plate in a direction orthogonal to both a sliding direction of the feed tray and a sheet-stack direction, and an elongation option removably attached to the upstream side of the mount plate in the transportation direction and including an extension plate serving as an extension of the mount plate to receive a long-size sheet. The sheet feeder includes a first locking device that is capable of holding the feed tray in a first locking position where the feed tray is not slidable in response to attachment of the elongation option thereto, and that is capable of holding the feed tray in a first unlocking position where the feed tray is slidable in response to detachment of the elongation option therefrom.
For example, a sheet feeding module having an openable/closeable upper surface may allow a manual tray to be mounted thereon. When the sheet feeding module has an open-close portion at such a position as to avoid the manual tray, the open-close portion is opened and closed within a limited range, and hinders removal or insertion of recording media.
Aspects of non-limiting embodiments of the present disclosure relate to a sheet feeder having an openable/closeable upper surface and including a housing that includes a manual insertion portion. The sheet feeder includes an open-close portion that is opened and closed within a larger range than an open-close portion disposed at such a position as to avoid the manual tray.
Aspects of certain non-limiting embodiments of the present disclosure address the features discussed above and/or other features not described above. However, aspects of the non-limiting embodiments are not required to address the above features, and aspects of the non-limiting embodiments of the present disclosure may not address features described above.
According to an aspect of the present disclosure, there is provided a sheet feeder including a housing including a mount portion that receives recording media, an open-close portion that is disposed on an upper surface of the housing to close the mount portion and rotates about a first hinge to open or close a mount space over the mount portion, and a manual insertion portion at least part of which is disposed on the open-close portion to receive manually inserted recording media, the manual insertion portion being rotatable about the first hinge or a second hinge disposed parallel to the first hinge to rotate upward from a position where the manual insertion portion overlaps the open-close portion.
Exemplary embodiments of the present disclosure will be described in detail based on the following figures, wherein:
Embodiments of the technology of the present disclosure will be described below. In the following description, in the drawings illustrated as appropriate, the direction indicated with arrow X is defined as an apparatus width direction and the direction indicated with arrow Y is defined as an apparatus height direction. The direction (direction of arrow Z) orthogonal to the apparatus width direction and the apparatus height direction is defined as an apparatus depth direction.
Structure of Image Forming Apparatus
As illustrated in
Structure of Sheet Feeder
Entire Structure
As illustrated in
The sheet feeder 10 also includes a drawable tray 26 at a lower portion of the body 12 on the front side in the depth direction (that is, Z direction). The drawable tray 26 accommodates a recording medium (not illustrated) different from recording media P. The drawable tray 26 is drawn out from the body 12 to accommodate the recording medium (not illustrated) different from the recording media P.
Structure of Body 12
As illustrated in
The body 12 also includes an upper wall 12D, disposed above the front wall 12A, the rear wall 12B, the side wall 12C, and another side wall (not illustrated in
The front wall 12A and the rear wall 12B hold the mount space S over the mount portion 16 therebetween from both sides in the direction crossing the transportation direction of the recording media P, that is, in the apparatus depth direction indicated with arrow Z. The front wall 12A includes a cut portion 32 at a portion opposite to a portion near the upper wall 12D and having a lower height than a portion connected to the upper wall 12D. In other words, the cut portion 32 lowers the height of the portion on the upstream side in the transportation direction (that is, in the direction of arrow A illustrated in
Structure of Container Device 14
The container device 14 has a function of accommodating multiple recording media P. As illustrated in
Inside the container device 14, the mount portion 16 that receives the multiple recording media P are disposed (refer to
In the sheet feeder 10, a sheet feeding device (not illustrated) disposed inside the body 12 near the upper wall 12D transports the recording media P stacked on the mount portion 16 one by one in the direction of arrow A. The mount portion 16 protrudes upstream in the transportation direction of the recording media P (that is, in direction of arrow A) from a position between the front wall 12A and the rear wall 12B. Specifically, in the sheet feeder 10, an upper portion of the side wall 12C between the front wall 12A and the rear wall 12B is open toward the upstream side in the transportation direction of the recording media P, and the mount portion 16 is disposed across the open portion.
The open-close covering 30 is rotated in the apparatus depth direction (refer to
Structure of Open-Close Member 20
The open-close member 20 has a function of opening the mount space S over the mount portion 16 while sharing the covering area with the open-close covering 30, to allow the multiple recording media P to be placed on the mount portion 16. As illustrated in
As illustrated in
While closing the mount space S, the open-close member 20 covers an area from the upper wall 12D up to the ends of the front wall 12A and the rear wall 12B on the upstream side in the transportation direction of the recording media P (that is, the direction of arrow A in
The open-close member 20 is rotated upward to open the mount space S about the first hinge 40 from the closed position along the upper wall 12D. When the open-close member 20 opens the mount space S, in association with opening of the sheet feeder 10, the rotation member 22 overlapping the open-close member 20 rotates in such a direction as to stand erect. The sheet feeder 10 allows, while the open-close member 20 opens the mount space S, recording media P to be inserted across the front wall 12A and placed on the mount portion 16 (refer to
As illustrated in
A handle 60 is disposed at a leading end portion 20A of the open-close member 20 opposite to an end portion closer to the first hinge 40. The handle 60 unlocks the open-close member 20 from the body 12 while the open-close member 20 opens the mount space S (refer to
Structure of Rotation Member 22
The rotation member 22 has a function of allowing manually inserted recording media (not illustrated) different from the recording media P to be placed. As illustrated in
The second hinge 42 is disposed at a higher position in the vertical direction of the sheet feeder 10 than (that is, upward in the vertical direction from) the first hinge 40. While the rotation member 22 is closed, at least part of the rotation member 22 overlaps the open-close member 20 that closes the mount space S. In this state, the leading end portion 22A of the rotation member 22 is in contact with the contact portion 48 of the open-close member 20.
The rotation member 22 is rotatable alone about the second hinge 42. The rotation member 22 shifts from the position overlapping the open-close member 20 to the erect position with an operation of the open-close member 20 opening the mount space S. Specifically, the rotation member 22 rotates in such a direction as to stand erect while sliding over the contact portion 48 of the open-close member 20 with the operation of the open-close member 20 opening the mount space S. In the sheet feeder 10, when the open-close member 20 is in the closing position, the rotation member 22 is allowed to rotate alone in such a direction as to stand erect, as described above. However, using the sheet feeder 10 while only the rotation member 22 stands erect has no practical meaning. Thus, usually, the open-close member 20 and the rotation member 22 are switched together into either the open position or the closing position.
In the sheet feeder 10, as illustrated in
In other words, when the open-close member 20 is in the maximum open state, the center of gravity G1 of the open-close member 20 is located between the first hinge 40 and the second hinge 42. When the rotation member 22 is in the open position (that is, in the erect state), the center of gravity G2 of the rotation member 22 is located between the first hinge 40 and the second hinge 42, so that the rotation member 22 is easily rotatable in the closing direction indicated with arrow C. In the sheet feeder 10, when the rotation member 22 is to rotate from the open position in the closing direction indicated with arrow C, the open-close member 20 is hindered from rotating in the closing direction due to the position of the center of gravity G of the open-close member 20.
As illustrated in
The slide portion 52 is formed from, for example, a resin member softer than a resin member forming the contact portion 48 of the open-close member 20. Examples of the resin member forming the slide portion 52 include polyamide resin such as nylon and acrylonitrile butadiene styrene (ABS) resin (copolymerized synthetic resin including acrylonitrile, butadiene, and styrene). The body of the rotation member 22 is formed from, for example, a polycarbonate/acrylonitrile butadiene styrene (PC/ABS) resin (a blend of polycarbonate and a copolymerized synthetic resin including acrylonitrile, butadiene, and styrene). Examples of a resin member forming the contact portion 48 of the open-close member 20 include a PC/ABS resin. Instead of or in addition to the softness, the material forming the slide portion 52 may have further smoothness than a resin member forming other portion of the rotation member 22.
The rotation member 22 has a recess 54 at an upper portion and at a center portion in the apparatus depth direction (that is, Z direction). The recess 54 is set back downward in the vertical direction with respect to the frame portion 50 (refer to
As shown in
Structure of Damper 36
As described above, the damper 36 has a function of assisting the operation of the open-close member 20 opening the mount space S. As illustrated in
The present exemplary embodiment includes a single damper 36. Specifically, the damper 36 is disposed on a far side of the sheet feeder 10 in the depth direction (that is, Z direction). No damper is disposed on the near side, closer to the front wall 12A of the sheet feeder 10 in the depth direction (that is, Z direction).
In the damper 36, the rod 36B is pushed in the direction to move forward with respect to the damper body 36A. Specifically, the damper 36 exerts a maximum reaction force when having the shortest length in the longitudinal direction. In the present exemplary embodiment, when the open-close member 20 is raised midway in such a direction as to open the mount space S, the open-close member 20 is raised with the function of the damper 36.
As illustrated in
In the present exemplary embodiment, when the open-close member 20 is closed, the center of gravity G3 is exerted on the attachment 70. In the present exemplary embodiment, the angle θ is set at 3°, and the reaction force (upward component F1 in
Operations and Functions
Operations and functions of the present exemplary embodiment will be described.
In a normal state of the sheet feeder 10, the open-close member 20 is in the closing position to close the mount portion 16 on the upper surface of the body 12, and the open-close member 20 closes the mount space S over the mount portion 16 (refer to
In the sheet feeder 10, to place the recording media P on the mount portion 16, the open-close member 20 is rotated about the first hinge 40 to open the mount space S over the mount portion 16 (refer to
Then, the open-close covering 30 of the container device 14 is rotated from the near side toward the far side in the apparatus depth direction to open the mount space S over the mount portion 16 (refer to
Thereafter, the open-close member 20 is rotated to close the mount space S over the mount portion 16, and the rotation member 22 is rotated to the position overlapping the open-close member 20. In addition, the open-close covering 30 of the container device 14 is rotated to close the mount space S over the mount portion 16. In this state, the sheet feeder 10 is operated to transport the recording media P to the image forming apparatus body 202. The image forming apparatus body 202 forms images on the recording media P transported thereto.
In the sheet feeder 10, the open-close member 20 is opened and closed within a wider range than an open-close portion disposed to avoid a rotation member in a sheet feeder having an openable/closable upper surface and including a housing that includes a manual insertion portion which is served by the rotation member.
In the sheet feeder 10, the second hinge 42 is disposed closer to a first end of the body 12 in a first direction than the first hinge 40. For example, in the sheet feeder 10, when the open-close member 20 is in the maximum open position and the rotation member 22 is in the erect position, a height H1 from the upper surface of the rear wall 12B of the body 12 to the leading end surface of the leading end portion 20A of the open-close member 20 is, for example, approximately 358 mm. Thus, in the sheet feeder 10, when the open-close member 20 opens the mount space S, the height of the entire apparatus including the open-close member 20 and the rotation member 22 is prevented from being higher than the height of a structure including the first hinge located closer to the first end in the first direction of the housing than the second hinge.
In the sheet feeder 10, the rotation member 22 is shifted from the position where part of the rotation member 22 overlaps the open-close member 20 to the erect position with the operation of the open-close member 20 opening the mount space S. Thus, in the sheet feeder 10, the open-close member 20 performs the opening operation with less time and effort compared to the structure where the manual insertion portion does not stand erect with the operation of the open-close portion opening the mount space.
In the sheet feeder 10, the first hinge 40 extends in the direction crossing the transportation direction of the recording media P (that is, the direction of arrow A illustrated in
To the body 12 of the sheet feeder 10, the container device 14 including the mount portion S that receives a recording medium P longer than an A3-size recording medium is removably attached. Thus, the sheet feeder 10 has a smaller size compared to a structure where a mount portion that receives long recording media is installed in advance in the housing.
In the sheet feeder 10, when the open-close member 20 is in the maximum open state, the center of gravity G1 of the open-close member 20 is located closer to the second hinge 42 than to the first hinge 40. Thus, when the rotation member 22 is to rotate from the open position in the closing direction indicated with arrow C, the open-close member 20 is hindered from rotating in the closing direction with the moment at the rotation center of the first hinge 40 of the open-close member 20 due to the center of gravity G1 of the open-close member 20. Specifically, even when the open-close member 20 is pushed by the rotation member 22, the open-close member 20 is less easily rotated in the closing direction opposite to the direction of the rotation with the center of gravity G1. Thus, in the sheet feeder 10, when the open-close portion is in the maximum open state, the open-close member 20 prevents the rotation member 22 from rotating in the falling direction compared to the structure where the center of gravity of the open-close portion is located closer to the first hinge than to the second hinge.
In the sheet feeder 10, with the operation of the open-close member 20 opening the mount space S, the rotation member 22 rotates in such a direction as to stand erect while sliding with the contact portion 48 at the upper portion of the open-close member 20. Thus, compared with a structure where the open-close portion and the manual insertion portion are interlocked with each other with a link mechanism, the rotation member 22 of the sheet feeder 10 is more easily rotatable with a simpler structure in association with the operation of the open-close member 20.
The slide portion 52 that slides over the contact portion 48 at the upper portion of the open-close member 20 is attached to the rotation member 22 of the sheet feeder 10. Thus, in the sheet feeder 10, the slide portion 52 on the rotation member 22 is more easily slidable over the contact portion 48 at the upper portion of the open-close member 20 compared to the structure where the manual insertion portion is in direct contact with the open-close portion.
In the sheet feeder 10, the slide portion 52 is formed from a resin member softer than the resin member forming the contact portion 48 at the upper portion of the open-close member 20. Thus, in the sheet feeder 10, the contact portion 48 at the upper portion of the open-close member 20 is less easily damaged than in a structure where the upper portions of the slide portion and the open-close portion are formed from the same material.
The sheet feeder 10 includes the front wall 12A and the rear wall 12B that hold the mount space S over the mount portion 16 therebetween from both sides in the direction crossing the transportation direction of the recording media P. The first hinge 40 and the second hinge 42 are supported by the front wall 12A and the rear wall 12B. The sheet feeder 10 allows recording media P to be inserted across the front wall 12A and placed on the mount portion 16. Thus, the sheet feeder 10 improves its workability when the recording media P are inserted across the front wall 12A to be placed on the mount portion 16, compared to the structure where recording media are inserted across the pair of walls to be placed on the mount portion.
The sheet feeder 10 includes the handle 60 at the leading end portion 20A of the open-close member 20 in the transportation direction of the recording media P opposite to an end portion closer to the first hinge 40. The handle 60 unlocks the open-close member 20 from the body 12 while the open-close member 20 opens the mount space S. Thus, the sheet feeder 10 has a simpler structure than a structure that unlocks the open-close portion at a portion closer to the first hinge in the transportation direction of the recording media.
In the sheet feeder 10, the handle 60 is disposed in the open-close member 20 at a portion closer to the front wall 12A. Thus, the sheet feeder 10 improves operability of the open-close member 20 opening the mount space S compared to the structure including a handle located at a portion of the open-close portion closer to the rear wall.
The sheet feeder 10 also includes the damper 36 between the rear wall 12B and the open-close member 20. The damper 36 assists the operation of the open-close member 20 opening the mount space S. Thus, the sheet feeder 10 improves operability of the open-close member 20 opening the mount space S compared to a structure not including a damper between another wall and the open-close portion.
The sheet feeder 10 includes a single damper 36. Specifically, no damper is installed between the front wall 12A and the open-close member 20. Thus, the sheet feeder 10 improves workability for placing the recording media P on the mount portion 16 from the side near the front wall 12A without interference of the damper 36 compared to a structure where a damper is disposed between the front wall and the open-close portion.
The image forming apparatus 200 includes the sheet feeder 10, and transports recording media P from the sheet feeder 10 to the image forming apparatus body 202. Thus, in the image forming apparatus 200, the open-close member 20 is opened and closed within a wider range compared to an open-close portion installed to avoid a manual insertion portion included in a housing in a sheet feeder having an openable/closeable upper surface.
With reference to
As illustrated in
The rotation member 106 is rotatable alone about the hinge 108 located at the same position as the open-close member 104 (that is, about the hinge 108 common to the hinge 108 about which the open-close member 104 rotates). When the rotation member 106 is located to overlap the open-close member 104, manually inserted recording media are placeable on the rotation member 106. The rotation member 106 shifts from the position overlapping the open-close member 104 to the erect position with the operation of the open-close member 104 opening the mount space S.
Although not illustrated, in the sheet feeder 100, the length of the mount portion in the apparatus width direction (that is, the direction of arrow X) is equal to the length of the mount portion 16 of the sheet feeder 10 according to the first exemplary embodiment (refer to
The sheet feeder 100 has the following operations and functions in addition to the operations and functions of the structure of the sheet feeder 10 according to the first exemplary embodiment.
In the sheet feeder 100, the rotation member 106 is rotatable about the hinge 108 common to the open-close member 104, and rotates upward from the position overlapping the open-close member 104. Thus, in the sheet feeder having an openable/closeable upper surface and including a housing that includes a manual insertion portion, the open-close member 104 is opened and closed within a wider range compared to an open-close portion disposed to avoid the manual insertion portion.
In the sheet feeder 100, the rotation member 106 is rotatable about the hinge 108 common to the open-close member 104. Thus, the sheet feeder 100 has a smaller size than a structure where the second hinge that rotates the manual insertion portion is located closer to a first end of the housing in a first direction than the first hinge that rotates the open-close portion.
In the sheet feeder 100, the open-close member 104 and the rotation member 106 are rotatable about the common hinge 108. However, the present disclosure is not limited to this structure. For example, the rotation member 106 may be rotatable about a second hinge located coaxial with the first hinge that rotates the open-close member 104 (located on an extension line of the first hinge that rotates the open-close member 104 in a side view).
Supplementary Explanation
In the first exemplary embodiment, the second hinge 42 is located at a higher position in the vertical direction of the sheet feeder 10 than the first hinge 40. However, the present disclosure is not limited to this structure. For example, the second hinge 42 and the first hinge 40 may be located at the same height or the second hinge 42 may be located at a lower height than the first hinge 40.
In the first exemplary embodiment, the shape of the contact portion 48 of the open-close member 20 is changeable, and the shape and the position of the slide portion 52 attached to the rotation member 22 are also changeable.
In the first exemplary embodiment, the handle 60 is located at a portion of the open-close member 20 closer to the front wall 12A in the apparatus depth direction. However, the present disclosure is not limited to this structure. The handle may be located around the center portion of the open-close member in the depth direction.
In the first and second exemplary embodiments, the position of the first hinge that rotates the open-close member and the position of the first hinge or the second hinge that rotates the rotation member are not limited to the above structure, and may be changed. For example, the first hinge that rotates the open-close member and the second hinge that rotates the rotation member may be arranged vertically at a first end portion of the body of the sheet feeder in the transportation direction of the recording media P. Here, the second hinge that rotates the rotation member is preferably disposed at a higher position than the first hinge that rotates the open-close member.
The present disclosure is described in detail using specific exemplary embodiments, but the present disclosure is not limited to these exemplary embodiments. It is apparent to practitioners skilled in the art that various other exemplary embodiments will be possible within the scope of the present disclosure.
The foregoing description of the exemplary embodiments of the present disclosure has been provided for the purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure to the precise forms disclosed. Obviously, many modifications and variations will be apparent to practitioners skilled in the art. The embodiments were chosen and described in order to best explain the principles of the disclosure and its practical applications, thereby enabling others skilled in the art to understand the disclosure for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the disclosure be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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JP2020-145005 | Aug 2020 | JP | national |
Number | Name | Date | Kind |
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8991811 | Iijima | Mar 2015 | B1 |
9359157 | Niikura et al. | Jun 2016 | B2 |
20160332828 | Wakakusa | Nov 2016 | A1 |
20200282751 | Suruga | Sep 2020 | A1 |
20210101765 | Morisawa | Apr 2021 | A1 |
Number | Date | Country |
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2016000653 | Jan 2016 | JP |
Number | Date | Country | |
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20220063937 A1 | Mar 2022 | US |