The present disclosure relates to a sheet accommodating device and an image forming apparatus, such as a copier, an MFP, a printer, or a facsimile apparatus, including the same.
In general, an image forming apparatus includes a sheet accommodating device (or more specifically, a paper feed cassette or a paper feed tray) that accommodates sheets such as recording paper, and in performing an image forming operation, the sheets accommodated in the sheet accommodating device are fed one by one from the sheet accommodating device to an image forming apparatus body by a sheet feeding member (or more specifically, a pickup roller) for image formation in the image forming apparatus body.
Some sheet accommodating device includes a plate member on which sheets are loaded and that turns around an axis extending along a width direction orthogonal to a sheet feed direction and a biasing member that presses up the plate member toward the sheet feeding member. In such a sheet accommodating device, the pressing force of the biasing member against the sheet feeding member becomes smaller as the size of the sheets becomes larger (i.e. as the weight of the sheets becomes heavier), and to that extent, empty feeding is likely to occur. On the other hand, the pressing force of the biasing member against the sheet feeding member becomes larger as the size of the sheets becomes smaller (i.e. as the weight of the sheets becomes lighter), and to that extent, multiple feeding is likely to occur.
In this regard, Japanese Unexamined Patent Application Publication. No. 2001-63836 discloses a sheet accommodating device including a first plate member on which sheets are mounted, a first biasing member that presses up the first plate member, a second plate member disposed on a side of the first date member opposite to a side of the first plate member on which the sheets are mounted, and a second biasing member that presses up the second plate member, wherein the biasing member presses up the first plate member or both the first and second biasing members press up both the first and second plate members. The sheet accommodating device prevents the occurrence of empty feeding or multiple feeding regardless of the size of the sheets by properly adjusting the pressing force of the sheets against the sheet feeding member by changing, according to the size of the sheets, the upward pressing force acting on the first plate member.
However, in the configuration described in Japanese Unexamined Patent Application Publication No. 2001-63836, the first and second plate members are provided on coaxial fulcrum axis line in a body (housing) of the sheet accommodating device. This makes it necessary to attach the first and second plate members to the body of the sheet accommodating device, causing deterioration in assembly workability of the plate members to the body of the sheet accommodating device accordingly.
it is desirable to provide a sheet accommodating device and an image forming apparatus that make it possible to improve assembly workability of plate members to a body of the sheet accommodating device.
According to an aspect of the disclosure, there is provided a sheet accommodating device including: a first plate member on which sheets are mounted; a first biasing member that presses up the first plate member; a second plate member disposed on a side of the first plate member opposite to a side of the first plate member on which the sheets are mounted; and a second biasing member that presses up the second plate member, the sheet accommodation q ice having a configuration in which, according to a size of the sheets, the first biasing member presses up the first plate member or both the first and second biasing members press up both the first and second plate members, wherein the first plate member is provided so as to be turnable with respect to the second plate member around a first fulcrum axis line extending along a width direction orthogonal to a sheet feed direction in which the sheets are fed, and the second plate member is provided so as to be turnable with respect to a body of the sheet accommodating device around a second fulcrum axis line extending along the width direction. Further, according to an aspect of the disclosure, there is provided an image forming apparatus including the sheet accommodating device according to the foregoing aspect of the present disclosure.
An embodiment of the present disclosure is described below with reference to the drawings.
The image forming apparatus 100 shown in
The image forming apparatus 100 includes an image forming apparatus body 110 and an image reading device 120. The image forming apparatus body 110 is provided. with an image forming unit 101 and a sheet conveyance system 102.
The image forming apparatus 100 includes a sheet accommodating device 200 (or more specifically, a paper feed cassette or a paper feed tray) that accommodates sheets. The image forming apparatus 100 is configured such that in performing an image forming operation, the sheets accommodated in the sheet accommodating device 200 are fed one by one from the sheet accommodating device 200 to the image forming apparatus body 110 by a sheet feeding member (or more specifically, a pickup roller 271; not illustrated in
The sheet accommodating device 200 includes a first plate member 210 (see
The first plate member 210 is provided so as to be turnable with respect to the second plate member 220 around a first fulcrum axis line α (see
More specifically, the first plate member 210 turns with respect to the second plate member 220 by means of engagement of projections and depressions. Further, the second plate member 220 turns with respect to the housing 201 by means of engagement of projections and depressions. Specifically, the first plate member 210 has a rear-end notch 210b (see
Incidentally, the first and second plate members 210 and 220 may be coaxially provided; however, in this case, in order for the first plate member 210 to be laid on top of the second plate member 220, the shape of the first plate member 210 as seen from the sheet feed direction W and the shape of the second plate member 220 as seen from the sheet feed direction W (in this example, an L shape) is substantially identical, and to that extent, upsizing of the first plate member 210 is invited. Accordingly, it is desirable to downsize the first plate member 210.
In this regard, the first embodiment is configured such that the first fulcrum axis line α of the first plate member 210 is provided in a position dip laced from the second fulcrum axis line β of the second plate member 220. This makes it possible to make a difference between the shape of the first plate member 210 as seen from the sheet feed direction W and the shape of the second plate member 220 as seen from the sheet feed direction N (in this example, an L shape), thereby making it possible to achieve downsizing of the first plate member 210.
The first embodiment is configured such that the first fulcrum axis line α of the first plate member 210 is displaced downward from the second fulcrum axis line β of the second plate member 220. This makes it possible to make the shape of the first plate member 210 as seen from the sheet feed direction W a linear shape in a state where the first plate member 210 is laid on top of the second plate member 220.
The first embodiment is configured such that the first fulcrum axis line α of the first plate member 210 and the second fulcrum axis line β of the second plate member 220 overlap in the vertical direction Z (when seen from the vertical direction Z) when the second plate member 220 is located in the lowest position. This makes it possible to reduce an amount of change in relative position of the first and second plate members 210 and 220 that is caused by the second plate member 220 turning when switching between the first and second upward pressing actions takes place.
Incidentally, when the second fulcrum axis line β of the second plate member 220 is located in either the position of a sheet mounting surface 210a (see
In this regard, the first embodiment is configured such that the second fulcrum axis line β of the second plate member 220 is located in a higher position than the sheet mounting surface 210a of the first plate member 210 during the time that both the first and second plate members 210 and 220 are located in the lowest position. In this way, upward turning of the second plate member 220 by the second upward pressing action causes the front end of a sheet that is mounted on the first plate member 210 to draw a trajectory that comes closer to the sheet outlet of the housing 201, thereby making it possible to shorten the feed distance that the sheet travels during the second upward pressing action.
Incidentally, when there is a great difference in level between an upper surface of the first plate member 210 overlapping the second plate member 220 and an upper surface of the second plate member 220, both end portions of the sheet in the width direction H bend to that extent, so that there is high likelihood of inconvenience such as catching of the sheet on a guide (not illustrated) during feeding of the sheet during the second upward pressing action. As for this, especially, in a case where the upper surface of the first plate member 210 is lower than the upper surface of the second plate member 220, both end portions of the sheet in the width direction H bend upward, so that there is high likelihood of inconvenience such as corner buckling (so-called edge buckling). Accordingly, it is desirable to avoid inconvenience such as catching of the sheet on the guide during feeding of the sheet.
In this regard, the first embodiment is configured such that the second plate member 220 is provided with a depressed portion 221 (see
More specifically, the second plate member 220 has its depressed portion 221 formed by downward bending of a region of the second plate member 220 that overlaps the first plate member 210. The depressed portion 221 is provided in a region including at least the sheet mounting surface.
Incidentally, the first biasing member 230 (or more specifically, a pressure spring), which presses up the first plate member 210 by the first upward pressing action, and the second biasing member 240 (or more specially a pressure spring), which presses up the second plate member 220 together with the first plate member 210, which has been pressed up by the first biasing member 230, by the second upward pressing action, can be selected in the following manner. That is, prior to selection of the second biasing member 240, a biasing member that has a predetermined upward pressing force during the first upward pressing action is selected as the first biasing member 230. That is, the upward pressing force of the first biasing member 230 during the first upward pressing action is an upward pressing force that serves as a pressing force by which sheets of a maximum accommodatable size (in this example, 16K size) that are mounted on the first plate member 210 during the first upward pressing action are pressed against the pickup roller 271 properly (i.e. to the extent that empty feeding or multiple feeding does not occur) via the first plate member 210 with the sheets mounted on the first plate member 210. Next, a biasing member that has a predetermined upward pressing force during the second upward pressing action is selected as the second plate member 240 in consideration of the upward pressing force of the first biasing member 230 during the first upward pressing action. That is, the upward pressing force of the second biasing member 240 during the second upward pressing action is an upward pressing force that serves as a pressing force that supplements the pressing force of the first biasing member 230 so that sheets of a maximum accommodatable size (i.e. a size that is larger than the maximum accommodatable size that is accommodated during the first upward pressing action; in this example, A4 size or 8½ size) that are mounted on the first plate member 210 during the second upward pressing action are pressed against the pickup roller 271 via the second plate member 220 with the sheets mounted on the first plate member 210.
Accordingly, normally, the upward pressing force of the second biasing member 240 during the second upward pressing action is smaller than the upward pressing force of the first biasing member 230 during the first upward pressing action. This makes it possible not only to properly press the sheets against the pickup roller 271 during the first upward pressing action but also co properly press the sheets against the pickup roller 271 during the second upward pressing action.
It should be noted that the upward pressing force of the second biasing member 240 during the second upward pressing action is smaller than the upward pressing force of the first biasing member 230 by any compression length during the first upward pressing action regardless of compression length. The first biasing member 230 may include a single biasing member or a plurality of biasing members. In this example, the first biasing member 230 includes two first biasing members 230. In the case of a plurality of first biasing members, it is preferable that they all have the same or substantially the same upward pressing characteristics (or more specifically, spring characteristics). This makes it easy to evenly press up the first plate member 210. Similarly, the second biasing member 240 may include a single biasing member or a plurality of biasing members. In this example, the second biasing member 240 includes two first biasing members 240. In the case of a plurality of second biasing members, it is preferable that they all have the same or substantially the same upward pressing characteristics (or more specifically, spring characteristics). This makes it easy to evenly press up the first and second plate members 210 and 220.
More specifically, the second plate member 220 has a front-end notch 220g (see
The first embodiment is configured such that the first and second biasing members 230 and 240 are provided side by side so as to be aligned in the width direction H. This makes it possible to stably press the sheets against the pickup roller 271 in a balanced manner during the second upward pressing action.
Specifically, the first and second biasing members 230 and 240 are disposed so that their axial centers are lined up on a virtual straight line along the width direction H. The first and second biasing members 230 and 240 are placed at regular intervals in the width direction H.
The first embodiment is configured such that the sheet accommodating device 200 includes a regulating member (or more specifically, width regulating members and/or a rear-end regulating member; in this example, both the width regulating members and the rear-end regulating member) that regulates a size width of the sheets. Width regulating members 250 (see
The first and second plate members 210 and 220 are provided with width notches 210d (see
More specifically, the width regulating members 250 have insertion holes 251 (see
Specifically, the width regulating members 250 are movable along the width direction H and provided on the bottom member 201b of the housing 201 so as to be slidable in tandem with each other to one or the other side along the width direction H. The width regulating members 250 have side surfaces, formed so as to extend along the vertical direction Z, that face the sheets. In this example, the width regulating members 250 are provided with sliders 252 (see
The sliders 252 constitute a pair of slide rails 252a (see
Incidentally, the area of the first plate member 210 is larger than the area of the second plate member 220. For this reason, the first plate member 210 is normally heavier than the second plate member 220, and it is necessary to use, as the first biasing member 230, which presses up the first plate member 210, a biasing member that has a great upward pressing force accordingly. In general, the first biasing member 230, which presses up the first plate member 210, becomes greater in tolerance as it becomes greater in upward pressing force. This causes deterioration in pressure accuracy of the pressing force of the sheets against the pickup roller 271. Accordingly, it is desirable to improve the pressure accuracy of the pressing force of the sheets against the pickup roller 271. Note here that the areas of the first and second plate members 210 and 220 (areas as seen from a vertical direction) are the projected areas of the first and second plate members 210 and 220 in a horizontal position (areas of shadows formed by irradiation with parallel light from directly above).
In this regard, the first embodiment is configured such that the area of the first plate member 210 is smaller than the area of the second plate member 220 (see
Incidentally, the second plate member 220 is subject to load, as the first plate member 210 is mounted on the second plate member 220 and the sheets are further mounted on the first plate member 210. Accordingly, it is desirable to reduce the weight of the first plate member 210 and improve the strength of the second plate member 220.
In this regard, the first embodiment is configured such that the first plate member 210 is made of a resin material and the second plate member 220 is made of a metal material (or more specifically, a metal plate). This makes it possible to reduce the weight of the first plate member 210 and improve the strength of the second plate member 220.
The first embodiment is configured such that the first plate member 210 is provided so as to be wholly laid on top of the second plate member 220. This makes it possible to surely mount the sheets on the first plate member 210 with its weight further reduced.
The first embodiment is configured such that a dimension L (see
This makes it possible to feed the sheet with its front-end portion mounted on a front-end region on a continuous flat surface of the first plate member 210 during both the first and second upward pressing actions. This makes it possible to achieve stably feed the sheet.
The dimension L of the predetermined region of the front-end side of the first plate member 210 in the width direction H is not limited to the dimension of the first embodiment, but, as shown in
Incidentally, if, in a case where the first fulcrum axis line α of the first plate member 210 is located in a lower position than the second fulcrum axis line β of the second plate member 220, the first fulcrum axis line α of the first plate member 210 is provided in a position further away from the front end of a sheet that is mounted on the first plate member 210 than the second fulcrum axis line β of the second plate member 220 in a state where both the first and second plate members 210 and 220 are located in the lowest position, it is necessary to lower the bottom member 201b of the housing 201 in order to prevent a portion of the first fulcrum axis line α of the first plate member 210 from coming into contact with the bottom member 201b of the housing 201 when the second plate member 220 turns upward, and to that extent, upsizing of the sheet accommodating device 200 is invited. Accordingly, it is desirable not to lower the bottom member 201b.
Incidentally, the first biasing member 230 has an upward pressing force by which sheets of a maximum accommodatable size (in this example, 16K size) that are mounted on the first plate member 210 during the first upward pressing action are properly pressed against the pickup roller 271 via the first plate member 210 with the sheets mounted on the first plate member 210. However, when the size of the sheets is too small, the weight of the sheets mounted on the first plate member 210 is too light. Further, depending on the upward pressing characteristics (or specifically, spring characteristics) of the first biasing member 230, the pressing force of the sheets against the pickup roller 271 by the first biasing member 230 is too great. This may make it impossible to press the sheets against the pickup roller 271 properly (i.e. to the extent that multiple feeding does not occur). Accordingly, it is desirable to properly press the sheets against the pickup roller 271 regardless of the size of the sheets.
More specifically, the sheet feeding device 270 includes a sheet conveying member (or specifically, a sheet conveying roller 272) in addition to the pickup roller 271. Together with a separating member 280 (see
Moreover, the sheet accommodating device 200 is provided in the image forming apparatus body 110 so as to be freely attached to and detached from the image forming apparatus body 110 by being slid along the width direction H.
The present embodiment is configured such that the first plate member 210 is made of a resin material and the second plate member 220 is made of a metal material. Alternatively, the first plate member 210 may be made of a metal material, and the second plate member 220 may be made of a resin material. Further, both the first and second plate members 210 and 220 may be made of a metal material or a resin material. Further, although the present embodiment is configured such that each of the first and second biasing members 240 includes a plurality of biasing members, each of the first and second biasing members 240 may alternatively include a single biasing member. In this case, the first and second biasing members 230 and 240 can be provided side by side along the length direction N. Further, although the present embodiment is configured such that the regulating member includes the width regulating members 250, the regulating member may alternatively or additionally include the rear-end regulating member 260.
The present disclosure is not limited to the embodiments described above but may be carried out in other various forms. Therefore, the embodiments are mere examples in all respects and should not be interpreted in a limited way. The scope of the present disclosure is indicated by the scope of the claims and is not bound in any way by the body of the specification. Furthermore, all modifications and alternations belonging to the equivalents of the scope of the claims are encompassed in the scope of the present disclosure.
The present disclosure contains subject matter related to that disclosed in Japanese Priority Patent Application JP 2017-212000 filed in the Japan Patent Office on Nov. 1, 2017, the entire contents of which are hereby incorporated by reference.
Number | Date | Country | Kind |
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2017-212000 | Nov 2017 | JP | national |