The disclosed information relates to sheet discharge devices for use in image forming apparatuses such as electrophotographic copying machines and electrophotographic printers.
Conventional image forming apparatuses such as electrophotographic copying machines and electrophotographic printers in which a tray for stacking sheets with images printed thereon by an image forming unit is provided above the image forming unit are known.
As illustrated in
A tray 91 provided above the image forming unit 10 can be opened and closed with a pivot shaft 91a (refer to
Sheets S stored in a cassette 6 are fed one by one by a roller 7, and a roller 8 conveys the fed sheet S to a transfer nip portion formed by the photosensitive drum 1 and the transfer member 5. The sheet S is conveyed while being sandwiched by the transfer nip portion, and during the conveying process, a toner image is transferred from the photosensitive drum 1 onto the sheet S by the transfer member 5. The sheet S with the unfixed toner image is passed through a fixing device 30 to heat and fix the toner image onto the sheet S. The sheet S ejected from the fixing device 30 is discharged onto the tray 91 by a roller (discharge unit) 40.
In order to allow stacking of longer sheets than a standard sheet length, the above-described image forming apparatus 200 includes an expansion tray 92 (refer to
Meanwhile, there are known methods for opening/closing an expansion tray. In one method, an expansion tray is opened by rotating the expansion tray with respect to a tray (Japanese Patent Application Laid-Open No. 2007-328302). In another method, an expansion tray is pulled from a tray (Japanese Patent Application Laid-Open No. 2005-247486).
If the image forming apparatus 200 illustrated in
According to an aspect of the present invention, a sheet discharge apparatus comprising: a main tray on which a sheet is to be stacked and which is pivotable between a closed position at which the main tray is closed with respect to a main body of the sheet discharge apparatus and an opened position at which the main tray is opened with respect to the main body of the sheet discharge apparatus, a discharge unit configured to discharge the sheet onto the main tray in a case where the main tray is at the closed position, and an expansion tray configured to expand a stacking area of the main tray, wherein the expansion tray is provided to the main tray and movable between a storage position at which the expansion tray is stored in the main tray and an expansion position at which the expansion tray is slid from the storage position in a sheet discharge direction and expands the stacking area, wherein, at the expansion position, the expansion tray is pivotable on a pivot center provided to the main tray, in a vertically upward direction, by a predetermined angle, independently of the main tray, and wherein a direction in which the expansion tray is pivoted in the vertically upward direction is the same as a direction in which the main tray is pivoted from the closed position to the opened position.
Further features of the present invention will become apparent from the following description of embodiments with reference to the attached drawings.
Embodiments will be described below with reference to the drawings. The present invention is not limited to the following embodiments and the following embodiments can be appropriately modified or changed depending on individual constructions and various conditions of apparatuses to which the present invention is applied.
An image forming apparatus according to an embodiment will be described with reference to
In the image forming apparatus 100, an image forming unit 10 configured to form a toner image on a sheet S such as a recording sheet includes a photosensitive drum (image bearing member) 1, a charging member 2, a development device 3, a laser scanner (exposure device) 4, and a transfer member 5. The photosensitive drum 1, the charging member 2, and the development device 3 are integrated as a cartridge 20, which is removably attached to the apparatus body 100A. Operation of the image forming unit 10 is well known, so detailed description thereof is omitted.
The sheets S stored in a cassette 6 are fed one by one by a roller 7, and a roller 8 conveys the fed sheet S to a transfer nip portion formed by the photosensitive drum 1 and the transfer member 5. The sheet S onto which a toner image is transferred at the transfer nip portion is conveyed to a fixing device (fixing portion) 30, and the toner image is heated and fixed onto the sheet S by the fixing device 30. The sheet S ejected from the fixing device 30 is discharged onto a sheet stacking device (stacking portion) 70 by a roller 40.
The sheet stacking device 70 provided in an upper portion of the apparatus body 100A includes the tray (main tray) 50 for stacking the sheets S and an expansion tray 60. The expansion tray 60 is provided to the tray 50 and is pulled from the tray 50 to expand a sheet staking area of the tray 50.
The tray 50 is provided in an upper portion of the apparatus body 100A with a pivot shaft 50s being a fulcrum in such a manner that the tray 50 can be pivoted between closed and opened positions with respect to the apparatus body 100A. To detach the cartridge 20 from the apparatus body 100A, a user pivots the tray 50 while moving upward an edge portion (hereinafter, “front edge portion”) 50c of the tray 50 which is on the opposite side to the pivot shaft 50s to open the opening portion 21 of the apparatus body 100A (refer to
To attach the cartridge 20 to the cartridge attachment portion 22, the user holds the cartridge 20 and pushes the cartridge 20 in the direction of an arrow A2 from the opening portion 21 to set the cartridge 20 into a predetermined position in the cartridge attachment portion 22. After the setting of the cartridge 20 is completed, the user pivots the tray 50 while pushing the front edge portion 50c of the tray 50 downward to close the opening portion 21 (refer to
The position of the tray 50 illustrated in
The following describes the sheet stacking device 70 according to the present embodiment with reference to
As illustrated in
The back surface 50e, which is on the opposite side to the sheet stacking surface 50a, of the tray 50 includes a pair of guide portions 51 in the width direction Y. The pair of guide portions 51 is provided to guide the expansion tray 60. The pair of guide portions 51 includes groove portions 51a for guiding the pair of pivot shafts (shaft) 61, which will be described below, of the expansion tray 60 from a retraction position to an extension position. The pair of groove portions 51a and the pair of pivot shafts 61 together form a rotation restriction unit Rr. The retraction position and the extension position will be described below.
In the present embodiment, the guide portions 51 are provided to the back side of the sheet stacking surface 50a of the tray 50 so that the sheet stacking surface 50a has a better appearance than that of a sheet stacking surface including guide portions provided on the front surface side of a tray.
As illustrated in
As illustrated in
Further, each of the pair of pivot shafts 61 includes two flat surface portions 61a connecting the two arc portions 61b in the direction T parallel to the pull direction of the expansion tray 60.
The expansion tray 60 is configured in such a manner that the position of the expansion tray 60 can be selected from (can be moved to) the retraction position illustrated in
The groove portion 51a is linearly formed. The groove portion 51a includes a first groove 51a1 and a second groove 51a2. The first groove 51a1 supports the pivot shaft 61 in such a manner that the pivot shaft 61 can be moved in a section I1 from the retraction position to a position before the extension position. The second groove 51a2 supports the pivot shaft 61 in such a manner that the pivot shaft 61 can be pivoted in the extension position.
In the retraction position, the flat surface portions 61a and the arc portions 61b of the pivot shaft 61 come into contact with the first groove 51a1 in the section I1 (refer to
In the extension position, the arc portions 61b of the pivot shaft 61 are in contact with the second groove portion 51a2 formed in the shape of a substantially semicircular arc (refer to a first contact portion E in
If the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V by a user, the arc portions 61b of the pivot shaft 61 are moved along an arc surface 51a21 of the second groove 51a2 (refer to
More specifically, in the section I1, the pivoting of the expansion tray 60 in the direction θ opposite to the vertical direction V is restricted, and in the extension position, the expansion tray 60 is pivotable in the direction θ opposite to the vertical direction V.
The pivoting of the expansion tray 60 in the vertical direction V in the extension position is restricted at two points that are the second contact portion F and the first contact portion E.
To retract the expansion tray 60 into the tray 50, the expansion tray 60 is pushed in an opposite direction to the discharge direction X with respect to the tray 50 when the expansion tray 60 is in the extension position.
In the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50. Further, the expansion tray 60 is supported in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V with respect to the tray 50. Thus, the expansion tray 60 can be moved and rotated with respect to the tray 50 with ease.
Further, in the sheet stacking device 70 according to the present embodiment, the direction in which the expansion tray 60 is pivoted in the direction θ opposite to the vertical direction V is the same as the direction in which the tray 50 is pivoted from the closed position to the opened position. Thus, when a user picks up a discharged sheet S from the tray 50, even if the user accidentally holds and moves the expansion tray 60 upward together with the sheet S, only the expansion tray 60 is pivoted in the direction θ opposite to the vertical direction V with respect to the tray 50 while the tray 50 is not pivoted. Similarly, when the user sets new sheets S into the cassette 6, even if the user accidentally pushes the expansion tray 60 upward, only the expansion tray 60 is pivoted with respect to the tray 50. As described above, even if the user accidentally moves or pushes the expansion tray 60 upward, the tray 50 remains at rest.
Meanwhile, there are cases in which an image reading apparatus (apparatus) is provided above the sheet stacking device 70 in the image forming apparatus 100.
In the image forming apparatus 200 according to the comparative example, a space B between the tray 91 and the image reading apparatus 80 may be set small in order to reduce the height of the image forming apparatus 200 (refer to
In order to facilitate removal and attachment of the cartridge 20, the image reading apparatus 80 is pivotably attached to the apparatus body 200A as illustrated in
In the image forming apparatus 200 according to the comparative example, the length C of the expansion tray 92 is short due to a constraint of the space B between the tray 91 and the image reading apparatus 80.
On the contrary, in the image forming apparatus 100 including the sheet stacking device 70 according to the present embodiment such as in
While the guide portion 51 is formed in the continuous integrated shape in the sheet stacking device 70 according to the present first embodiment (
Further, while the guide portion 51 is formed as a part of the tray 50, the guide portion 51 can be formed as a separate member from the tray 50. More specifically, a suitable shape can be selected within a range that rotation of the expansion tray 60 is restricted while the pivot shaft 61 is supported when the expansion tray 60 is in a position other than the extension position.
Another example of the sheet stacking device 70 will be described below.
A sheet stacking device 70 according to a second embodiment has a similar configuration to that of the sheet stacking device 70 according to the first embodiment, except that the rotation restriction unit Rr has a different configuration.
The expansion tray 60 includes a pair of large-diameter cylindrical portions 621 (only one of the cylindrical portions 621 is illustrated in
The two pairs of cylindrical portions 621 and 622 are located at a predetermined distance from each other in the direction U which is orthogonal to the sheet stacking surface 60a of the expansion tray 60 and which is orthogonal to the direction T parallel to a direction in which the expansion tray 60 is moved. The large-diameter cylindrical portion 621 is provided on the pull direction side (right hand side in
A guide portion 52 includes a pair of groove portions 52a (only one of the groove portions 52a is illustrated in
The groove portion 52a includes a first groove 52a1 and a second groove 52a2. The first groove 52a1 supports the large-diameter cylindrical portion 621 and the small-diameter cylindrical portion 622 in such a manner that the large-diameter cylindrical portion 621 and the small-diameter cylindrical portion 622 can be moved in the section I1 from the retraction position to a position before the extension position. The second groove 52a2 supports the large-diameter cylindrical portion 621 in such a manner that the large-diameter cylindrical portion 621 can be pivoted in the extension position. The second groove 52a2 serves as a pivot center of the expansion tray 60. The groove portion 52a further includes a third groove 52a3 into which the small-diameter cylindrical portion 622 is to be moved in a position between the section I1 and the extension position.
In the retraction position, peripheral surfaces of the large-diameter cylindrical portion 621 and the small-diameter cylindrical portion 622 come into contact with the first groove 52a1 in the section I1 (refer to
In the extension position, the large-diameter cylindrical portion 621 fits in the second groove 52a2. Further, in the extension position, the small-diameter cylindrical portion 622 is located directly above an inlet 52a31 of the third groove 52a3.
Then, when the expansion tray 60 is pivoted in the direction θ opposite to the vertical direction V on the large-diameter cylindrical portion 621 fitting in the second groove 52a2 in the extension position, the small-diameter cylindrical portion 622 is moved into the third groove 52a3. Then, as the expansion tray 60 is further pivoted in the direction θ, the small-diameter cylindrical portion 622 comes into contact with a bottom portion 52a32 of the third groove 52a3 to stop the pivoting of the expansion tray 60 in the direction θ. Thus, the expansion tray 60 can be pivoted on the large-diameter cylindrical portion 621 in the direction θ opposite to the vertical direction V within a predetermined range (predetermined angle). The predetermined angle of pivoting of the expansion tray 60 is desirably 20 degrees to 90 degrees with respect to the expansion position in the direction θ opposite to the vertical direction V.
Also in the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50, and the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. The direction in which the expansion tray 60 is pivoted in the direction θ opposite to the vertical direction V is the same as the direction in which the tray 50 is pivoted from the closed position to the opened position.
Accordingly, a similar benefit to that of the sheet stacking device 70 according to the first embodiment is produced.
While the third groove 52a3 is shaped to branch from the first groove 52a1 and include the bottom portion 52a32 in a closed shape in the sheet stacking device 70 according to the present embodiment, the third groove 52a3 can be in a cut portion with the bottom portion 52a32 being opened. Further, while the cylindrical portions 621 and 622 are provided to the expansion tray 60, this is not a limiting case, and the cylindrical portions 621 and 622 can be different parts. In other words, the shapes of the cylindrical portions 621 and 622 can be changed as appropriate to an extent that the above-described benefit is produced.
Further, while the pivot center of the expansion tray 60 is set on the tray 50 in the present embodiment, the pivot center can be set on the expansion tray 60. The pivot center of the expansion tray 60 can be is set in a position closer to an upstream edge of the expansion tray 60 than a downstream edge of the expansion tray 60 in the discharge direction X.
Yet another example of the sheet stacking device 70 will be described below.
A sheet stacking device 70 according to a third embodiment has a similar configuration to that of the sheet stacking device 70 according to the first embodiment, except that the rotation restriction unit Rr has a different configuration.
The expansion tray 60 includes the pair of large-diameter cylindrical portions 621 (only one of the cylindrical portions 621 is illustrated in
The three pairs of cylindrical portions 621, 622, and 623 are provided on the rear edge portion side in the longitudinal direction of the expansion tray 60. In the present embodiment, the three pairs of cylindrical portions 621, 622, and 623 are used in place of the pivot shafts 61 according to the first embodiment.
The three pairs of cylindrical portions 621, 622, and 623 are located at a predetermined distance from each other in the direction U which is orthogonal to the sheet stacking surface 60a of the expansion tray 60 and which is orthogonal to the direction T parallel to the direction in which the expansion tray 60 is moved. The large-diameter cylindrical portion 621 is provided on the pull direction side (right hand side in
The guide portion 52 includes the pair of groove portions 52a (only one of the groove portions 52a is illustrated in
The groove portion 52a includes the first groove 52a1 that supports the large-diameter cylindrical portion 621, the small-diameter cylindrical portion 622, and the smallest-diameter cylindrical portion 623 in such a manner that the large-diameter cylindrical portion 621, the small-diameter cylindrical portion 622, and the smallest-diameter cylindrical portion 623 can be moved in the section I1 from the retraction position to a position before the extension position. The groove portion 52a further includes the second groove 52a2 that supports the smallest-diameter cylindrical portion 623 and also supports the large-diameter cylindrical portion 621 in such a manner that the large-diameter cylindrical portion 621 can be pivoted in the extension position. The second groove 52a2 is the pivot center of the expansion tray 60. The groove portion 52a further includes the third groove 52a3 into which the small-diameter cylindrical portion 622 is to be moved in the position between the section I1 and the extension position.
In the retraction position and the region of the section I1 that is on the right hand side of the retraction position, peripheral surfaces of the large-diameter cylindrical portion 621, the small-diameter cylindrical portion 622, and the smallest-diameter cylindrical portion 623 come into contact with the first groove 52a1. The width D of the first groove 52a1 is set substantially equal to the diameter of the large-diameter cylindrical portion 621. Thus, the large-diameter cylindrical portion 621, the small-diameter cylindrical portion 622, and the smallest-diameter cylindrical portion 623 are movably supported by the first groove 52a1 so that the expansion tray 60 can be moved along the first groove 52a1.
In the extension position, the large-diameter cylindrical portion 621 fits in the second groove 52a2. Further, in the extension position, the small-diameter cylindrical portion 622 is located directly above an inlet 52a31 of the third groove 52a3. Further, in the extension position, a part of the peripheral surface of the smallest-diameter cylindrical portion 623 is in contact with the second groove 52a2.
Then, when the expansion tray 60 is pivoted in the direction θ opposite to the vertical direction V on the large-diameter cylindrical portion 621 fitting in the second groove 52a2 in the extension position, the small-diameter cylindrical portion 622 is moved into the third groove 52a3. Then, as the expansion tray 60 is further pivoted in the direction θ, the small-diameter cylindrical portion 622 comes into contact with the bottom portion 52a32 of the third groove 52a3 to stop the pivoting of the expansion tray 60 in the direction θ. Thus, the expansion tray 60 can be pivoted on the large-diameter cylindrical portion 621 in the direction θ opposite to the vertical direction V within a predetermined range.
Also in the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50, and the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Accordingly, a similar benefit to that of the sheet stacking device 70 according to the first embodiment is produced. In the sheet stacking device 70 according to the present embodiment, a part of the peripheral surface of the smallest-diameter cylindrical portion 623 is in contact with the second groove 52a2 to produce a benefit that the orientation (orientation of the expansion tray 60 before being pivoted) of the expansion tray 60 with respect to the tray 50 in the extension position is stabilized.
While the third groove 52a3 is shaped to branch from the first groove 52a1 and include the bottom portion 52a32 in a closed shape in the sheet stacking device 70 according to the present embodiment, the third groove 52a3 can be in a cut portion with the bottom portion 52a32 being opened. Further, while the cylindrical portions 621, 622, and 623 are provided to the expansion tray 60, this is not a limiting case, and the cylindrical portions 621, 622, and 623 can be different parts. In other words, the shapes of the cylindrical portions 621, 622, and 623 can be changed as appropriate to an extent that the above-described benefit is produced.
Yet another example of the sheet stacking device 70 will be described below.
A sheet stacking device 70 according to a fourth embodiment has a similar configuration to that of the sheet stacking device 70 according to the first embodiment, except that the rotation restriction unit Rr has a different configuration.
The expansion tray 60 includes a pair of cylindrical portions 624 (only one of the cylindrical portions 624 is illustrated in
The pairs of cylindrical portions 624 and 625 are provided on the rear edge portion side in the longitudinal direction of the expansion tray 60. In the present embodiment, the two pairs of cylindrical portions 624 and 625 are used in place of the pivot shafts 61 according to the first embodiment.
The pair of cylindrical portions 624 is provided on the pull direction side (right hand side in
The guide portion 52 includes the pair of groove portions 52a (only one of the groove portions 52 is illustrated in
The groove portion 52a includes the first groove 52a1 and the second groove 52a2. The first groove 52a1 supports the cylindrical portions 624 and 625 in such a manner that the cylindrical portions 624 and 625 can be moved in the section I1 from the retraction position to a position before the extension position. The second groove 52a2 supports the cylindrical portion 624 in such a manner that the cylindrical portion 624 can be pivoted in the extension position. The groove portion 52a further includes the third groove 52a3 into which the cylindrical portion 625 is to be moved in the position between the section I1 and the extension position.
In the retraction position, peripheral surfaces of the cylindrical portion 624 and the flat surface portions 625a and the arc-shaped portions 625b of the cylindrical portion 625 come into contact with the first groove 52a1 in the section I1. In a region of the section I1 that is on the right hand side of the retraction position, the peripheral surfaces of the cylindrical portion 624 and the arc-shaped portions 625b of the cylindrical portion 625 are in contact with the first groove 52a1. The width D of the first groove 52a1 is set substantially equal to the diameter of the cylindrical portions 624 and 625. Thus, the cylindrical portions 624 and 625 are movably supported by the first groove 52a1 so that the expansion tray 60 can be moved along the first groove 52a1.
In the extension position, the cylindrical portion 624 fits in the second groove 52a2. Further, in the extension position, the cylindrical portion 625 is located directly above the inlet 52a31 of the third groove 52a3. Further, in the extension position, the arc-shaped portions 625b of the cylindrical portions 625 are in contact with the second groove 52a2.
Then, when the expansion tray 60 is pivoted in the direction θ opposite to the vertical direction V on the cylindrical portion 624 fitting in the second groove 52a2 in the extension position, the flat surface portions 625a of the cylindrical portion 625 are moved into the third groove 52a3. Then, as the expansion tray 60 is further pivoted in the direction θ, the arc-shaped portions 625b of the cylindrical portion 625 come into contact with the bottom portion 52a32 of the third groove 52a3 to stop the pivoting of the expansion tray 60 in the direction θ. Thus, the expansion tray 60 can be pivoted on the cylindrical portion 624 in the direction θ opposite to the vertical direction V within a predetermined range.
Also in the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50, and the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Accordingly, a similar benefit to that of the sheet stacking device 70 according to the first embodiment is produced. Similar to the third embodiment (
While the third groove 52a3 is shaped to branch from the first groove 52a1 and include the bottom portion 52a32 in a closed shape in the sheet stacking device 70 according to the present embodiment, the third groove 52a3 can be in a cut portion with the bottom portion 52a32 being opened. Further, while the cylindrical portions 624 and 625 are provided to the expansion tray 60, this is not a limiting case, and the cylindrical portions 624 and 625 can be different parts. In other words, the shapes of the cylindrical portions 624 and 625 can be changed as appropriate to an extent that the above-described benefit is produced.
A sheet stacking device 70 according to a fifth embodiment will be described below.
In the present embodiment, components that are similar to those of the sheet stacking device 70 according to the first embodiment are given the same reference numerals, and description of the components is omitted.
The tray 50 and the expansion tray 60 connected to the tray 50 will be described with reference to
As illustrated in
In the width direction Y of the tray 50, a pair of guide portions 53 is provided to lateral surfaces of the attachment portion 50r. The pair of guide portions 53 is provided to guide the expansion tray 60. The pair of guide portions 53 includes groove portions 53a for guiding a pair of pivot shafts (shafts) 63, which will be described below, of the expansion tray 60 from the retraction position to the extension position. The pair of groove portions 53a and the pair of pivot shafts 63 together form the rotation restriction unit Rr.
As illustrated in
The pair of pivot shafts 63 includes arc portions 63a on the front edge portion 60c side of the expansion tray 60 on a rotation shaft. The pair of pivot shafts 63 has a predetermined radius in the direction U which is orthogonal to the direction T parallel to the pull direction of the expansion tray 60 and which is orthogonal to the sheet stacking surface 60a of the expansion tray 60.
The pair of pivot shafts 63 further includes projection portions 63b on the rear edge portion 60b side of the expansion tray 60 on the rotation shaft. The projection portions 63b each have a predetermined radius in the direction U which is orthogonal to the direction T parallel to the pull direction of the expansion tray 60 and the sheet stacking surface 60a of the expansion tray 60. The radius of the projection portions 63b is smaller than the arc portions 63a.
The pair of pivot shafts 63 further includes between the arc portions 63a and the projection portions 63b two flat surface portions 63c connecting the arc portions 63a and the projection portions 63b.
The groove portion 53a includes a first groove 53a1 that supports the pivot shaft 63 in such a manner that the pivot shaft 63 can be moved in the predetermined section 12 from the retraction position to a position before the extension position. The groove portion 53a further includes a second groove 53a2 which pivotably supports the pivot shaft 63 in a region beyond the section 12 and up to the extension position.
In the retraction position, a peripheral surface of the projection portion 63b, the flat surface portion 63c, and a part of a peripheral surface of the arc portion 63a of the pivot shaft 63 come into contact with the first groove 53a1 in the section 12. In a region of the section that is on the right hand side of the retraction position, the peripheral surface of the arc portion 63a of the pivot shaft 63 is in contact with the first groove 53a1. The width J of the first groove 53a1 is set substantially equal to the diameter of the arc portion 63a of the pivot shaft 63. Thus, the pivot shaft 63 fits in the first groove 53a1. Accordingly, in the section 12, the pivot shaft 63 is movably supported by the first groove 53a1 so that the expansion tray 60 can be moved along the first groove 53a1.
The width K of the second groove 53a2 is greater than the first groove 53a1. The width K is set to the size of an area in which the arc portion 63a and the projection portion 63b of the pivot shaft 63 are both in contact with the second groove 53a2. Thus, in the region beyond the section 12 and up to the extension position, the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V within a predetermined range after the arc portion 63a of the pivot shaft 63 comes into contact with the second groove 53a2 and until the projection portion 63b comes into contact with the second groove 53a2.
In the extension position, the arc portion 63a of the pivot shaft 63 fits in a semi-circular arc depressed portion 53a21 of the second groove 53a2, and the flat surface portion 63c and a part of the peripheral surface of the projection portion 63b of the pivot shaft 63 are in contact with the second groove 53a2 (refer to the first contact portion E in
If the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V by a user, the arc portion 63a of the pivot shaft 63 is pivoted with respect to the depressed portion 53a21 of the second groove 53a2. If the expansion tray 60 is further pivoted in the direction θ, the flat surface portion 63c and a part of the peripheral surface of the projection portion 63b of the pivot shaft 63 come into contact with an end surface 53a22 of the second groove 53a2 to stop the pivoting of the expansion tray 60 in the direction θ. Thus, the expansion tray 60 becomes pivotable on the pivot shaft 63 in the direction θ opposite to the vertical direction V within a predetermined range.
More specifically, in the section 12, the pivoting of the expansion tray 60 in the direction θ opposite to the vertical direction V is restricted, and in the region beyond the section 12 and up to the extension position, the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V.
The pivoting of the expansion tray 60 in the vertical direction V in the extension position is restricted at two points that are the second contact portion F and the first contact portion E.
To retract the expansion tray 60 into the tray 50, the expansion tray 60 is pushed into the tray 50 in the region beyond the section 12 and up to the extension position.
In the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50. Further, the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Accordingly, a similar benefit to that of the first embodiment is produced. Further, in the region beyond the section 12 and up to the extension position, the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Thus, the expansion tray 60 can be moved and rotated with respect to the tray 50 with ease, compared to the first embodiment.
Further, in the sheet stacking device 70 according to the present embodiment, even if the user accidentally moves or pushes the expansion tray 60 upward, the tray 50 remains at rest.
In the image forming apparatus 100 including the sheet stacking device 70 according to the present embodiment, the expansion tray 60 is pulled and pivoted, so the expansion tray 60 can be pulled to a necessary length for stacking long sheets without the constraint described in the first embodiment. Further, in the sheet stacking device 70, when the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V, the expansion tray 60 comes into contact with the image reading apparatus 80 to restrict the pivoting of the expansion tray 60 before the pivoting of the expansion tray 60 in the direction θ is restricted by the rotation restriction unit Rr.
Further, in the region beyond the section 12 and up to the extension position, the expansion tray 60 of the sheet stacking device 70 can be pivoted in the direction θ opposite to the vertical direction V. Thus, in the image forming apparatus 100 including the sheet stacking device 70 according to the present embodiment, the expansion tray can be pulled and pushed smoothly during printing operations.
Further, the position of the section 12 of the first groove 53a1 for restricting the pivoting of the expansion tray 60 and the number of sections 12 can be determined as appropriate for the type of usage.
Yet another example of the sheet stacking device 70 will be described below.
A sheet stacking device 70 according to a sixth embodiment has a similar configuration to that of the sheet stacking device 70 according to the fifth embodiment, except that the rotation restriction unit Rr has a different configuration.
The expansion tray 60 includes a pair of large-diameter cylindrical portions 631 (only one of the cylindrical portions 631 is illustrated in
The two pairs of cylindrical portions 631 and 632 are located at a predetermined distance from each other in the direction U which is orthogonal to the sheet stacking surface 50a of the tray 50 and which is orthogonal to the direction T parallel to the direction in which the expansion tray 60 is moved. The large-diameter cylindrical portion 631 is provided on the pull direction side (right hand side in
The guide portion 53 includes the pair of groove portions 53a (only one of the groove portions 53a is illustrated in
The groove portion 53a includes the first groove 53a1 that supports the large-diameter cylindrical portion 631 in such a manner that the large-diameter cylindrical portion 631 can be moved in the predetermined section 12 from the retraction position to a position before the extension position. The groove portion 53a further includes the second groove 53a2 that supports the large-diameter cylindrical portion 631 in such a manner that the large-diameter cylindrical portion 631 can be pivoted in the region beyond the section 12 and up to the extension position.
In the retraction position, peripheral surfaces of the large-diameter cylindrical portion 631 and the small-diameter cylindrical portion 632 come into contact with the first groove 53a1 in the section 12 (refer to
The width K of the second groove 53a2 is greater than the first groove 53a1. The width K is set to the size of an area in which the large-diameter cylindrical portion 631 and the small-diameter cylindrical portion 632 are both in contact with the second groove 53a2. Thus, in the region beyond the section 12 and up to the extension position, the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V within a predetermined range after the large-diameter cylindrical portion 631 comes into contact with the second groove 53a2 and until the small-diameter cylindrical portion 632 comes into contact with the second groove 53a2.
In the extension position, the large-diameter cylindrical portion 631 fits in the semi-circular depressed portion 53a21 of the second groove 53a2. If the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V by a user, the large-diameter cylindrical portion 631 is pivoted with respect to the depressed portion 53a21 of the second groove 53a2. If the expansion tray 60 is further pivoted in the direction θ, a part of the peripheral surface of the small-diameter cylindrical portion 632 comes into contact with the end surface 53a22 of the second groove 53a2 to stop the pivoting of the expansion tray 60 in the direction θ. Thus, the expansion tray 60 becomes pivotable on the pivot shaft 63 in the direction θ opposite to the vertical direction V within a predetermined range.
In the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50. Further, the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Accordingly, a similar benefit to that of the fifth embodiment is produced.
Further, in the sheet stacking device 70 according to the present embodiment, even if the user accidentally moves or pushes the expansion tray 60 upward, the tray 50 remains at rest.
Yet another example of the sheet stacking device 70 will be described below.
A sheet stacking device 70 according to a seventh embodiment has a similar configuration to that of the sheet stacking device 70 according to the first embodiment, except that the rotation restriction unit Rr has a different configuration.
The expansion tray 60 includes the pair of large-diameter cylindrical portions 631 (only one of the large-diameter cylindrical portions 631 is illustrated in
The three pairs of cylindrical portions 631, 632, and 633 are provided on the rear edge portion side in the longitudinal direction of the expansion tray 60. In the present embodiment, the three pairs of cylindrical portions 631, 632, and 633 are used in place of the pivot shafts 63 according to the fifth embodiment.
The three pairs of cylindrical portions 631, 632, and 633 are located at a predetermined distance from each other in the direction U which is orthogonal to the sheet stacking surface 60a of the expansion tray 60 and which is orthogonal to the direction T parallel to the direction in which the expansion tray 60 is moved. The large-diameter cylindrical portion 631 is provided on the pull direction side (right hand side in
The guide portions 53 include the pair of groove portions 53a (only one of the groove portions 53a is illustrated in
The groove portion 53a includes the first groove 53a1 that supports the large-diameter cylindrical portion 631 in such a manner that the large-diameter cylindrical portion 631 can be moved in the predetermined section 12 from the retraction position to a position before the extension position. The groove portion 53a further includes the second groove 53a2 that supports the large-diameter cylindrical portion 631 in such a manner that the large-diameter cylindrical portion 631 can be pivoted in the region beyond the section 12 and up to the extension position.
In the retraction position, the peripheral surfaces of the large-diameter cylindrical portion 631, the small-diameter cylindrical portion 632, and the smallest-diameter cylindrical portion 633 come into contact with the first groove 53a1 in the section 12. The peripheral surfaces of the large-diameter cylindrical portion 631, the small-diameter cylindrical portion 632, and the smallest-diameter cylindrical portion 633 are in contact with the first groove 53a1 also in a region of the section 12 that is on the right hand side of the retraction position. The width J of the first groove 53a1 is set substantially equal to the diameter of the large-diameter cylindrical portions 631. Thus, in the section 12, the large-diameter cylindrical portion 631, the small-diameter cylindrical portion 632, and the smallest-diameter cylindrical portion 633 are movably supported by the first groove 53a1 so that the expansion tray 60 can be moved along the first groove 53a1.
The width K of the second groove 53a2 is greater than the first groove 53a1. The width K is set to the size of an area in which the large-diameter cylindrical portion 631 and the small-diameter cylindrical portion 632 are both in contact with the second groove 53a2. Thus, in the region beyond the section 12 and up to the extension position, the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V within a predetermined range after the large-diameter cylindrical portion 631 comes into contact with the second groove 53a2 and until the small-diameter cylindrical portion 632 comes into contact with the second groove 53a2.
In the extension position, the large-diameter cylindrical portion 631 fits in the semi-circular depressed portion 53a21 of the second groove 53a2. Further, in the extension position, a part of the peripheral surface of the smallest-diameter cylindrical portion 633 is in contact with the second groove 53a2.
If the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V by a user, the large-diameter cylindrical portion 631 is pivoted with respect to the depressed portion 53a21 of the second groove 53a2. If the expansion tray 60 is further pivoted in the direction θ, a part of the peripheral surface of the small-diameter cylindrical portion 632 comes into contact with the end surface 53a22 of the second groove 53a2 to stop the pivoting of the expansion tray 60 in the direction θ. Thus, the expansion tray 60 becomes pivotable on the pivot shaft 63 in the direction θ opposite to the vertical direction V within a predetermined range.
In the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50. Further, the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Accordingly, a similar benefit to that of the fifth embodiment is produced. Further, in the sheet stacking device 70 according to the present embodiment, a part of the peripheral surface of the smallest-diameter cylindrical portion 633 is in contact with the second groove 52a2 in the extension position to produce a benefit that the orientation (orientation of the expansion tray 60 before being pivoted) of the expansion tray 60 with respect to the tray 50 in the extension position is stabilized.
Yet another example of the sheet stacking device 70 will be described below.
A sheet stacking device 70 according to an eighth embodiment has a similar configuration to that of the sheet stacking device 70 according to the fifth embodiment, except that the rotation restriction unit Rr has a different configuration.
The expansion tray 60 includes a pair of first cylindrical portions 634 (only one of the first cylindrical portions 634 is illustrated in
The pairs of cylindrical portions 634 and 635 are located at a predetermined distance from each other in the direction U which is orthogonal to the sheet stacking surface 60a of the expansion tray 60 and which is orthogonal to the direction T parallel to the direction in which the expansion tray 60 is moved. The pair of first cylindrical portions 634 is provided on the pull direction side (right hand side in
The guide portion 531 includes a pair of first groove portions 531a (only one of the first groove portions 531a is illustrated in
The first groove portion 531a includes a groove 531a1 that supports the first cylindrical portion 634 in such a manner that the first cylindrical portion 634 can be moved in the predetermined section 12 from the retraction position to a position before the extension position. The second groove portion 531b includes a first groove 531b1 and a second groove 531b2. The first groove 531b1 supports the second cylindrical portion 635 in such a manner that the second cylindrical portion 635 can be moved in the predetermined section 12 from the retraction position to a position before the extension position. The second groove 531b2 supports the second cylindrical portion 635 in such a manner that the second cylindrical portion 635 can be pivoted in the region beyond the section 12 and up to the extension position.
In the retraction position, a peripheral surface of the first cylindrical portion 634 is in contact with the groove 531a1 and the second cylindrical portion 635 fits in an edge portion of the first groove 531b1 in the section 12 (refer to
The peripheral surface of the first cylindrical portion 634 is in contact with the groove 531a1 also in a region of the section 12 that is on the right hand side of the retraction position, and the peripheral surface of the second cylindrical portion 635 is in contact with the first groove 531b1.
The width J1 of the groove 531a1 is set substantially equal to the diameter of the first cylindrical portion 634, and the width J2 of the first groove 531b1 is set substantially equal to the diameter of the second cylindrical portion 635. Thus, in the section 12, the first cylindrical portion 634 and the second cylindrical portion 635 are movably supported by the groove 531a1 and the first groove 531b1, respectively, so that the expansion tray 60 can be moved along the groove 531a1 and the first groove 531b1.
The width K of the second groove 531b2 is greater than the first groove 531b1. In other words, the width K is set greater than the diameter of the second cylindrical portion 635. Thus, in the region beyond the section 12 and up to the extension position, the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V within a predetermined range until the second cylindrical portion 635 comes into contact with the second groove 531b2 with the first cylindrical portion 634 being in contact with the groove 531a1.
In the extension position, the first cylindrical portion 634 fits in an edge portion of the groove 531a1. If the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V by a user, the second cylindrical portion 635 comes into contact with the second groove 531b1 to stop the pivoting of the expansion tray 60 in the direction θ. Thus, the expansion tray 60 becomes pivotable on the first cylindrical portion 634 in the direction θ opposite to the vertical direction V within a predetermined range.
In the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50. Further, the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Accordingly, a similar benefit to that of the fifth embodiment is produced.
A sheet stacking device 70 according to a ninth embodiment will be described below.
In the present embodiment, components that are similar to those of the sheet stacking device 70 according to the first embodiment are given the same reference numerals, and description of the components is omitted.
The following describes the tray 50 and the expansion tray 60 connected to the tray 50 with reference to
As illustrated in
As illustrated in
In the width direction Y of the tray 50, a pair of guide portions 54 is provided to the lateral surfaces of the attachment portion 50r. The pair of guide portions 54 is provided to guide the expansion tray 60. The pair of guide portions 54 includes groove portions 54a for guiding the pair of pivot shafts (shaft) 65, which will be described below, of the expansion tray 60 from the retraction position to the extension position. The pair of groove portions 54a includes grooves 54a1 which movably support the pair of pivot shafts 65. The pair of groove portions 54a, the pair of elastic portions 64, the pair of pivot shafts 65, a rotation restriction rib 55 described below, and a bottom surface 50r1 together form the rotation restriction unit Rr.
The position of the expansion tray 60 can be selected from the retraction position illustrated in
As illustrated in
In the retraction position, the lower edge portion 60b1 of the expansion tray 60 comes into contact with the rotation restriction rib 55 in the section 12 (refer to
In the region beyond the section 12 (refer to
In the extension position, the peripheral surface of the pivot shaft 65 fits in the groove 54a1 (refer to the first contact portion E in
Further, in the extension position, the space N is formed between the lower edge portion 60b1 of the expansion tray 60 and the bottom surface 50r1 of the attachment portion 50r. Thus, the expansion tray 60 can be pivoted on the pivot shaft 65 in the direction θ opposite to the vertical direction V within a range in which the elastic portions 64 is elastically deformable until the lower edge portion 60b1 of the expansion tray 60 comes into contact with the bottom surface 50r1.
More specifically, in the section 12, the pivoting of the expansion tray 60 in the direction θ opposite to the vertical direction V is restricted, and in the region beyond the section 12 and up to the extension position, the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V within a range in which the elastic portions 64 is elastically deformable.
In the sheet stacking device 70 according to the present embodiment, the expansion tray 60 can be pulled from and pushed into the tray 50. Further, the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Accordingly, a similar benefit to that of the fifth embodiment is produced. Further, the expansion tray 60 is supported by the tray 50 in such a manner that the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Accordingly, a similar benefit advantage to that of the first embodiment is produced. Further, in the region beyond the section 12 and up to the extension position, the expansion tray 60 can be pivoted in the direction θ opposite to the vertical direction V. Thus, the expansion tray 60 can be moved and rotated with respect to the tray 50 with ease, compared to the first embodiment.
Further, in the sheet stacking device 70 according to the present embodiment, when the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V, the elasticity of the elastic portions 64 produces force to bring the expansion tray 60 back to the extension position. Further, the elasticity of the elastic portions 64 can absorb a shake generated when the expansion tray 60 is pulled from the retraction position or pivoted from the extension position. This reduces the risk of damage to the pivot shaft 65.
Further, in the sheet stacking device 70 according to the present embodiment, even if the user accidentally moves or pushes the expansion tray 60 upward, the tray 50 remains at rest.
Further, in the sheet stacking device 70 according to the present embodiment, the position and height of the rotation restriction rib 55 and the number of rotation restriction ribs 55 can be changed to allow the expansion tray 60 to be pivoted in a specified position and to set the pivot angle restriction more suitably.
Further, the guide portion 54 can be provided to the back surface of the expansion tray 60 as in the sheet stacking device 70 according to the first embodiment so that the expansion tray 60 can be pivoted only in the extension position.
While the elastic portions 64 are integrated with the expansion tray 60 in the present embodiment, the elastic portions 64 and the expansion tray 60 can be separate members.
In the image forming apparatus 100 including the sheet stacking device 70 according to the present embodiment, the expansion tray 60 is pulled and pivoted, so the expansion tray 60 can be pulled to a necessary length for stacking long sheets without the constraint described in the first embodiment. Further, in the sheet stacking device 70, when the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V, the expansion tray 60 comes into contact with the image reading apparatus 80 to restrict the pivoting of the expansion tray 60 before the pivoting of the expansion tray 60 in the direction θ is restricted by the rotation restriction unit Rr.
Further, in the region beyond the section 12 and up to the extension position, the expansion tray 60 of the sheet stacking device 70 can be pivoted in the direction θ opposite to the vertical direction V. Thus, in the image forming apparatus 100 including the sheet stacking device 70 according to the present embodiment, the expansion tray can be pulled and pushed smoothly during printing operations.
Further, in the image forming apparatus 100 including the sheet stacking device 70 according to the present embodiment, the pivot shafts 65 are provided to the elastic portions 64 of the expansion tray 60. Thus, when the expansion tray 60 is pulled from the retraction position or pushed from the extension position, a damper effect is obtained to allow smoother movement of the expansion tray 60.
A sheet stacking device 70 according to a tenth embodiment will be described below.
In the present embodiment, components that are similar to those of the sheet stacking device 70 according to the first embodiment are given the same reference numerals, and description of the components is omitted.
A metal spring or a torsion spring made of resin is used as the elastic member 67. The elastic member (torsion spring) 67 is attached to the pivot shaft 61 of the expansion tray 60. One edge 67a of the torsion spring 67 is stopped in an engaged state by the expansion tray 60, and the other end 67b is stopped in an engaged state by a pin 56 provided to a sliding member (not illustrated) which is slidable on the tray 50. In this case, no elastic force is produced by the torsion spring 67. When the expansion tray 60 is pivoted in the direction θ opposite to the vertical direction V, a part (lower edge portion 60b1 as an example in
More specifically, when the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V, the torsion spring 67 produces force that acts to bring the expansion tray 60 back to the extension position.
The foregoing describes the case in which the torsion spring 67 is applied to the pivot shafts 61 of the sheet stacking device 70 according to the first embodiment. The torsion spring 67 is also applicable to the large-diameter cylindrical portions 621 according to the second and third embodiments and the cylindrical portions 624 according to the fourth embodiment. In this case, when the expansion tray 60 in the extension position is pivoted in the direction θ opposite to the vertical direction V, the torsion spring 67 produces force that acts to bring the expansion tray 60 back to the extension position.
Further, the torsion spring 67 is also applicable to the pivot shafts 63 according to the fifth embodiment, the large-diameter cylindrical portions 631 according to the sixth and seventh embodiments, and the cylindrical portions 634 according to the eighth embodiment. In this case, when the expansion tray 60 is pivoted in the direction θ opposite to the vertical direction V in the region beyond the section 12 and up to the extension position, the torsion spring 67 produces force that acts to bring the expansion tray 60 back to the extension position.
The load of the torsion spring 67, position of action, angle of action, position of attachment of the torsion spring 67 to the expansion tray 60, etc. can be selected as appropriate to set the timing of action of the torsion spring 67 and the elastic force more precisely.
The torsion spring 67 does not produce elastic force until the expansion tray 60 comes into contact with the tray 50 to allow smooth movement of the expansion tray 60 when the expansion tray 60 is pulled from the retraction position or pivoted from the extension position.
The elastic member 67 is not limited to the torsion spring, and the type, number, etc. of the elastic member 67 can be selected as appropriate.
An image forming apparatus 100 according to an eleventh embodiment will be described below.
The image forming apparatus 100 according to the present embodiment includes the provided above the sheet stacking device 70.
The image reading apparatus 80 is provided with a predetermined space between the image reading apparatus 80 and the tray 50. Further, the image reading apparatus 80 can be pivoted upward from a closing position (position specified by real line in
When the expansion tray 60 is in the extension position, if a user accidentally moves or pushes the expansion tray 60 upward, the expansion tray 60 abuts against a bottom surface (or side surface) of the image reading apparatus 80. Thus, the expansion tray 60 is not further rotated and is returned to the extension position due to the weight of the expansion tray 60 and the weight of the stacked sheets.
Even if the expansion tray 60 of the image forming apparatus 100 according to the present embodiment is accidentally moved or pushed upward, the expansion tray is returned to the extension position, so suitable printing operations are realized without disturbing the discharged sheets S.
In the case in which the sheet stacking device 70 according to the tenth embodiment is included, the speed of the expansion tray 60 is reduced before the expansion tray comes into contact with the bottom surface (or side surface) of the image reading apparatus 80 due to the action of the torsion spring 67. Consequently, an impact generated when the expansion tray 60 comes into contact with the image reading apparatus 80 is cancelled or the expansion tray 60 is returned to the extension position before coming into contact with the image reading apparatus to reduce unpleasant impact sound and damage to the expansion tray 60, the image reading apparatus 80, etc.
While the present invention has been described with reference to embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
Number | Date | Country | Kind |
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2016-141003 | Jul 2016 | JP | national |
This application is a continuation, and claims the benefit, of U.S. patent application Ser. No. 16/249,288 filed Jan. 16, 2019, which claims the benefit of U.S. patent application Ser. No. 15/642,202 filed Jul. 5, 2017 (now U.S. Pat. No. 10,221,033 issued Mar. 5, 2019) which claims the benefit of Japanese Patent Application No. 2016-141003 filed Jul. 19, 2016, each of which is hereby incorporated by reference herein in their entirety.
Number | Date | Country | |
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Parent | 16249288 | Jan 2019 | US |
Child | 16879404 | US | |
Parent | 15642202 | Jul 2017 | US |
Child | 16249288 | US |