Field of the Invention
The present invention relates to a sheet supporting apparatus supporting sheets, and an image forming apparatus utilizing the sheet supporting apparatus.
Description of the Related Art
Hitherto, image forming apparatuses adopting an electro-photographic system are widely applied as copiers, printers, plotters, facsimile machines, and multifunction machines having such multiple functions. An image forming apparatus including a sheet supporting apparatus supporting a large number of sheets is becoming widespread. For example, Japanese unexamined patent application publication No. 2008-105791 teaches a widely-used sheet supporting apparatus having a sheet supporting unit capable of supporting a large number of sheets, and a conveyance guide for manual sheet feed. In this type of sheet supporting apparatus, the conveyance guide is disposed movably to a sheet conveyance position disposed upward of the sheet supporting unit and forming a sheet conveyance path, and a freeing position freeing the sheet conveyance path.
In this type of image forming apparatus, in order to form an image on a sheet having a regular, frequently-used size, the user stacks sheets on a sheet supporting unit, and the sheets are fed one at a time from the uppermost sheet by a sheet feeding unit. In order to form an image on a sheet having a regular size but not used frequently, such as a cardboard, or on a special sheet having a size other than the regular size, such as a long sheet, the user feeds the sheet manually on the conveyance guide.
In the image forming apparatus, a feed roller is disposed above the conveyance guide. When replacing the feed roller, for example, operation is performed in a state where the conveyance guide is positioned at the freeing position.
However, the above-described sheet supporting apparatus does not adopt a configuration of regulating movement of the conveyance guide positioned at the freeing position with respect to the apparatus body. Therefore, when the conveyance guide is positioned at the freeing position to replace the feed roller, the conveyance guide may be moved with respect to the apparatus body, hindering the replacement operation of the feed roller.
Especially, when the apparatus body is turned 90 degrees and erected so that a bottom portion of the apparatus body is visible from the side with the aim to facilitate the replacement operation of the feed roller, the conveyance guide may move by its own weight and hide the feed roller, or narrow the operation space. If the replacement operation of the feed roller is continued in this state, operation time is elongated by the deteriorated workability. It may be possible to remove the conveyance guide from the apparatus body to improve the workability during replacement of the feed roller, but an operation of removing the conveyance guide must be additionally performed, and the operation time could not be shortened easily. Such drawback does not only occur at the timing of replacement of the feed roller, but may occur during general maintenance operation, such as replacement or inspection of an internal component, of an apparatus body having its workability possibly deteriorated by the movement of the conveyance guide in the freeing position.
The present invention provides a sheet supporting apparatus including an apparatus body, a supporting unit being capable of being drawn from and inserted to the apparatus body, and comprising a supporting member on which a sheet is supported, a conveyance guide disposed on the apparatus body and being capable of moving to a first position at which a sheet conveyance path is constituted, and a second position distant from the first position, and a regulation unit regulating the conveyance guide positioned at the second position from moving in an upward direction, a downward direction, a drawing direction and an inserting direction of a supporting unit.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Now, a first embodiment of the present invention will be described in detail with reference to
As illustrated in
In the present embodiment, a side on which the door 11 is provided, that is, the side from which a sheet cassette 21 described later is drawn out, is referred to as a front side of the image forming apparatus 1. Further, in the respective drawings, a front side direction is referred to as frontward F, a direction opposite therefrom toward a direction in which the sheet cassette 21 is inserted is referred to as backward B, and an upper direction in a state facing the door 11 is referred to as upward U, a lower direction is referred to as downward D, a left side direction is referred to as leftward L, and a right side direction is referred to as rightward R. Moreover, a front and back direction may also be referred to as an inserting and drawing direction of the sheet cassette 21, and a left and right direction may also be referred to as a width direction W.
A sheet feeding unit 20 is disposed below the apparatus body 10, and configured to feed sheets S to the image forming unit 30. The sheet feeding unit 20 includes an apparatus body 20a, a sheet cassette, i.e., supporting unit, 21 capable of supporting sheets S, a conveyance guide 22, a roller unit 27, and a regulation unit 28 (refer to
The sheet cassette 21 can be drawn out from and inserted to the apparatus body 10, and includes an intermediate plate, i.e., supporting member, 25 on which sheets S are supported. In other words, the sheet cassette 21 is disposed in an attachable and removable manner with respect to the apparatus body 10. The intermediate plate 25 supports the supported sheets S, and is configured to push up the sheets S stored in the sheet cassette 21 and press the sheets against the roller unit 27. Horizontal linear sliding portions, i.e., guidance portions, 21a disposed with the front and back direction set as the longitudinal direction are provided on both side portions in the width direction W of the sheet cassette 21 (refer to
The roller unit 27 includes a feed roller 23 and a separation mechanism 24, and is disposed in an attachable and removable manner to a sheet conveyance path of the apparatus body 10. The separation mechanism 24 comprises a conveyance roller 24a and a separation roller, i.e., separation unit, 24b. The conveyance roller 24a and the separation roller 24b are in pressure contact with one another, and separate the sheets S fed from the feed roller 23 one by one. That is, the feed roller 23 is capable of feeding the sheets S supported on the intermediate plate 25. Further, the conveyance roller 24a is disposed downstream, in a sheet conveyance direction, of the feed roller 23, and cooperates with the separation roller 24b to separate the sheets S fed from the feed roller 23 one by one. In the present embodiment, the separation unit is composed of the separation roller 24b, but the configuration is not restricted thereto, and the separation unit can also be composed of a non-rotating friction plate.
A manual sheet feed port 12 is disposed between the conveyance guide 22 and the door 11. A manual sheet feed portion 26 utilizing a sheet conveyance path R1 is disposed backward B of the manual sheet feed port 12. Drive rollers, i.e., second roller portions, 90 and 91 disposed in the apparatus body 10, and driven rollers, i.e., first roller portions, 65 and 66 in pressure contact with the respective drive rollers 90 and 91 and disposed on the conveyance guide 22 are arranged on the sheet conveyance path R1. Transfer nips are respectively formed at a pressure contact portion between the drive roller 90 and the driven roller 65, and at a pressure contact portion between the drive roller 91 and the driven roller 66. A manually-fed sheet Sa set to the conveyance guide 22 from the manual sheet feed port 12 is conveyed via the drive rollers 90 and 91 and reaches the separation mechanism 24 via the feed roller 23. That is, the conveyance guide 22 conveys the manually-fed sheet Sa from the manual sheet feed portion 26 through the sheet conveyance path R1. The drive rollers 90 and 91 have a drive motor 92 as a drive source, and are rotated via gear trains 93 and 94. Further, the feed roller 23 and the conveyance roller 24a have the drive motor 92 as the drive source, and are rotated via a gear train not illustrated. The details of the sheet feeding unit 20 will be described later.
The image forming unit 30 includes an image forming unit 31, a laser scanner 33, an intermediate transfer unit 34, a secondary transfer unit 35, and a fixing unit 36, and forms images on a sheet conveyed through the sheet conveyance unit 40.
The image forming unit 31 includes four image forming units 31y, 31m, 31c and 31k forming toner images of four colors, which are yellow (y), magenta (m), cyan (c) and black (k). For example, the image forming unit 31y includes a photosensitive drum 37y forming a toner image, a charging roller 38y, a developing sleeve 39y, a drum cleaning blade not shown, a toner, and so on. The toner is stored in a container within the image forming unit 31y. The other image forming units 31m, 31c and 31k have similar configurations as the image forming unit 31y, except for the difference in toner colors, so that detailed descriptions thereof are omitted.
The laser scanner 33 exposes the surfaces of the photosensitive drums 37y, 37m, 37c and 37k, and forms electrostatic latent images on the surface.
The intermediate transfer unit 34 includes multiple rollers, such as a drive roller 34a and primary transfer rollers 34y, 34m, 34c and 34k, and an intermediate transfer belt 34b wound around these rollers. The primary transfer rollers 34y, 34m, 34c and 34k are respectively opposed to the photosensitive drums 37y, 37m, 37c and 37k, and abutted against the intermediate transfer belt 34b. By applying a transfer bias of positive polarity by the primary transfer rollers 34y, 34m, 34c and 34k to the intermediate transfer belt 34b, toner images having negative polarity formed respectively on the photosensitive drums 37y, 37m, 37c and 37k are sequentially superimposed and transferred to the intermediate transfer belt 34b. Thereby, a full-color image is formed on the intermediate transfer belt 34b.
The secondary transfer unit 35 includes a secondary transfer inner roller 35a and a secondary transfer outer roller 35b. The full-color image formed on the intermediate transfer belt 34b is configured to be transferred onto the sheet S by applying a secondary transfer bias having positive polarity to the secondary transfer outer roller 35b. The secondary transfer inner roller 35a is arranged on an inner side of the intermediate transfer belt 34b, and stretching the intermediate transfer belt 34b, with the secondary transfer outer roller 35b positioned to face the secondary transfer inner roller 35a with the intermediate transfer belt 34b nipped therebetween.
The fixing unit 36 includes a fixing roller 36a and a pressure roller 36b. When a sheet S is nipped and conveyed between the fixing roller 36a and the pressure roller 36b, the toner image transferred onto the sheet S is heated, pressed and fixed onto the sheet S.
The sheet conveyance unit 40 includes a pre-secondary-transfer conveyance path 41, a pre-fixing conveyance path 42 and a discharge path 43, configured so that the sheet S supported on the sheet feeding unit 20 can be conveyed from the image forming unit 30 to the sheet discharge unit 50.
The sheet discharge unit 50 includes a sheet discharge roller pair 51 disposed downstream of the discharge path 43, and a sheet discharge tray 52 disposed downstream of the sheet discharge roller pair 51. The sheet discharge roller pair 51 is configured to feed the sheet S conveyed from the discharge path 43 through the nip portion, and discharge the sheet S onto the sheet discharge tray 52.
The control unit 2 is composed of a computer, and includes, for example, a CPU, a ROM storing programs controlling respective units, a RAM storing temporal data, and an input/output circuit (I/F) inputting/outputting signals from/to an exterior. The CPU is a microprocessor administrating the overall control of the image forming apparatus 1, and it is a subject of a system controller. The CPU is connected via the input/output circuit to the sheet feeding unit 20, the image forming unit 30, the sheet conveyance unit 40 and the sheet discharge unit 50, and configured to communicate signals with the respective units and control operations thereof.
Next, an image forming operation according to the image forming apparatus 1 configured in this manner will be described.
When the image forming operation is started, at first, the photosensitive drums 37y, 37m, 37c and 37k rotate, and the surfaces thereof are charged by charging rollers 38y, 38m, 38c and 38k. Then, laser beams are irradiated from the laser scanner 33 to the photosensitive drums 37y, 37m, 37c and 37k based on image information, and electrostatic latent images are formed on the surface of the photosensitive drums 37y, 37m, 37c and 37k. By having toner adhere to the electrostatic latent images, the images are developed and visualized as toner images. At this time, an amount of toner being developed increases as a potential difference, which is the difference between an exposure amount and a bias applied to each of the developing sleeves 39y, 39m, 39c and 39k, increases. The visualized toner images are transferred to the intermediate transfer belt 34b.
Meanwhile, in parallel with such toner image forming operation, the feed roller 23 is rotated, separating and feeding an uppermost sheet S of the sheet cassette 21. Then, the sheet S is conveyed via the pre-secondary-transfer conveyance path 41 to the secondary transfer unit 35 at a timing matching the toner image on the intermediate transfer belt 34b. Further, the sheet S on which an image has been transferred from the intermediate transfer belt 34b is conveyed to the fixing unit 36, where heat and pressure is applied to the non-fixed toner image to fix the image on the surface of the sheet S, and then the sheet S is discharged through the sheet discharge roller pair 51 and stacked on the sheet discharge tray 52.
Furthermore, when feeding the sheet S manually, the user inserts a manually-fed sheet Sa through the manual sheet feed port 12 to the conveyance guide 22 of the manual sheet feed portion 26, by which the sheet S is sent into the sheet conveyance path R1. The sheet conveyance path R1 for manual sheet feed is continued from the manual sheet feed port 12 to the separation mechanism 24. The manually-fed sheet Sa set through the manual sheet feed port 12 to the conveyance guide 22 is conveyed by drive rollers 90 and 91, passes the feed roller 23 and reaches the separation mechanism 24. A color toner image is transferred and fixed to the manually-fed sheet Sa having reached the separation mechanism 24, similarly as the sheet S supported in the sheet cassette 21, and discharged onto the sheet discharge tray 52.
Next, the sheet feeding unit 20 in the above-mentioned image forming apparatus 1 will be described in detail with reference to
As illustrated in
The conveyance guide 22 of the sheet feeding unit 20 includes a guide plate 60, and guide projections, i.e., engagement portions or pin members, 61 through 64 protruding sidewise, i.e., width direction, from front and rear portions of the left and right sides of the guide plate 60. Further, the conveyance guide 22 includes driven rollers 65 and 66 supported rotatably on the guide plate 60, and biasing springs, i.e., biasing portions, 67 and 68 (refer to
As shown in
The guide projection 61 on the left front side of the conveyance guide 22 is configured to engage with a front portion of the horizontal portion 71a and the front side oblique portion 71c and capable of moving in sliding motion. The guide projection 62 on the left back side of the conveyance guide 22 is configured to engage with the horizontal portion 71a, the rear side oblique portion 71d and the rear side step portion 71e, and capable of moving in sliding motion. A sliding portion 21a disposed on a left side of the sheet cassette 21 is supported slidably in the drawing and inserting direction by the horizontal portion 71a and the rear side horizontal portion 71b.
That is, the guide groove 71 includes the horizontal portion 71a disposed horizontally from the drawing direction side toward the inserting direction of the apparatus body 20a, and the front side oblique portion 71c disposed to intersect with an intersect portion 71x with respect to the horizontal portion 71a and formed diagonally upward U in the inserting direction from the intersect portion 71x. When the conveyance guide 22 is positioned at a first position, the guide projection is positioned at an uppermost portion of the front side oblique portion 71c, and when the conveyance guide 22 is positioned at a second position, the guide projection 61 is positioned at the drawing direction side than the intersect portion 71x of the horizontal portion 71a.
Further, a lower front section of the horizontal portion 71a is formed as a shallow groove, defining a stopper 71f. The stopper 71f is formed to such a depth not allowing the guide projections 61 and 62 to pass through but allowing the sliding portion 21a to pass through. A first mold spring, i.e., first contact portion, 72 protruding inward at the front side, and a second mold spring, i.e., second contact portion, 73 protruding inward at an adjacent portion backward B of the first mold spring 72 are disposed at the upper side of the stopper 71f. The first mold spring 72 is elastically deformable in the width direction W, and has an inclined plane 72a facing the inner frontward direction, and a stopper plane 72b facing the backward direction (refer to
Further, the support plate 70 has a bearing hole 70c opening to the inner side and rotatably supporting a rotation shaft 95, and a bearing hole 70d opening to the inner side and rotatably supporting a rotation shaft 96. A link member 79 is formed on the guide projection 62. The link member 79 has a rotation shaft 79a, and a cam hole 79b through which the guide projection 62 passes. The support plate 70 has a bearing hole 70e rotatably supporting the rotation shaft 79a.
As illustrated in
The latch member 75 includes a rotation shaft 75a, a contact portion 75b in contact with the operation lever 76, an inclined plane 75c to which the guide projection 61 having been elevated within the front side oblique portion 71c can contact, and an engagement portion 75d with which the guide projection 61 can engage. The rotation shaft 75a is rotatably supported by a bearing hole 70a formed to the support plate 70. The biasing spring 77 is formed of a compression coil spring, and disposed in a compressed manner between a rear portion of the latch member 75 and a rear side surface of the dent portion 74. Therefore, in
The operation lever 76 is disposed slidably in the front and back direction within the dent portion 74. The operation lever 76 has a contact portion 76a formed on the trailing edge portion, and a pressing portion 76b formed on the leading edge portion. The contact portion 76a is capable of being in contact with the contact portion 75b of the latch member 75. The pressing portion 76b is protruded frontward F from a lever hole 70b formed on a leading edge surface of the support plate 70. Thus, when the user presses the pressing portion 76b of the operation lever 76 backward B, the operation lever 76 moves backward B, and rotates the latch member 75 against the biasing spring 77 in a clockwise direction in
As illustrated in
A guide projection 63 on a front right side of the conveyance guide 22 is engaged with the front portion of the horizontal portion 81a and the front side oblique portion 81c in a slidable manner. A guide projection 64 on a rear right side of the conveyance guide 22 is engaged with the horizontal portion 81a, the rear side oblique portion 81d and the rear side step portion 81e in a slidable manner. A sliding portion 21a on the right side of the sheet cassette 21 is slidably supported in the drawing direction and the inserting direction by the horizontal portion 81a and the rear side horizontal portion 81b.
That is, the guide groove 81 includes the horizontal portion 81a disposed horizontally from the drawing direction side toward the inserting direction of the apparatus body 20a, and the front side oblique portion 81c intersecting the horizontal portion 81a at an intersect portion 81x and disposed diagonally upward U in the inserting direction from the intersect portion 81x. When the guide groove 81 is positioned at a first position, the guide projection 63 is positioned at the uppermost portion of the front side oblique portion 81c, and when the guide groove 81 is positioned at a second position, the guide projection 63 is positioned at the drawing direction side than the intersect portion 81x of the horizontal portion 81a.
Therefore, the sheet cassette 21 has the left and right sliding portions 21a respectively slidably supported by the horizontal portions 71a and 81a and the rear side horizontal portion 71b, so that the cassette 21 can be slid in the drawing direction and the inserting direction. In the present embodiment, the sheet cassette 21 is slidably supported by the sliding portion 21a, the horizontal portions 71a and 81a and rear side horizontal portion 71b with respect to the respective support plates 70 and 80, but a supporting structure is not restricted to a sliding structure. The structure supporting the sheet cassette 21 in a guided manner toward the drawing direction and the inserting direction with respect to the respective support plates 70 and 80 can adopt a known or new appropriate configuration, such as a mechanism for allowing a relatively linear movement using a roller and a rail.
The lower front section of the horizontal portion 81a is formed in the shape of a shallow groove, defining a stopper 81f. The stopper 81f is formed to such a depth not allowing the guide projections 63 and 64 to pass through but allowing the sliding portion 21a to pass through. A first mold spring, i.e., first contact portion, 82 protruding inward at the front side and a second mold spring, i.e., second contact portion, 83 protruding inward at an adjacent portion backward B of the first mold spring 82 are disposed at the upper side of the stopper 81f. The first mold spring 82 is elastically deformable in the width direction W, and includes an inclined plane 82a facing the inner frontward direction, and a stopper plane 82b facing the backward direction (refer to
Further, the support plate 80 has a bearing hole 80c formed on the inner side and rotatably supporting the rotation shaft 95, and a bearing hole 80d formed on the inner side and rotatably supporting the rotation shaft 96. A link member 89 is formed on the guide projection 64. The link member 89 has a rotation shaft 89a, and a cam hole 89b through which the guide projection 64 passes. The support plate 80 has a bearing hole 80e rotatably supporting the rotation shaft 89a.
As illustrated in
The latch member 85 includes a rotation shaft 85a, a hook portion 85b to which a biasing spring 87 is hooked, an inclined plane 85c to which the guide projection 63 having been elevated within the front side oblique portion 81c can contact, and an engagement portion 85d capable of engaging the guide projection 63. The rotation shaft 85a is rotatably supported by a bearing hole 80a formed to the support plate 80. The biasing spring 87 is formed of a compression coil spring, and locked between the hook portion 85b of the latch member 85 and the hook portion 80f formed on the support plate 80. Therefore, the latch member 85 is biased toward the counterclockwise direction in
The latch member 85 is connected via the connecting shaft 97 to the left side latch member 75 (refer to
Next, the operation of the sheet feeding unit 20 described above will be described in detail with respect to
As illustrated in
Thus, when the user presses the pressing portion 76b of the operation lever 76, the operation lever 76 moves backward B, and rotates the latch member 75 in a clockwise direction against the biasing spring 77. Thereby, the guide projection 61 is disengaged from the engagement portion 75d of the latch member 75, and is lowered along the front side oblique portion 71c. Along therewith, the guide projection 62 is pressed frontward F by the link member 79 and lowered from the rear side step portion 71e along the rear side oblique portion 71d. As a result, as illustrated in
Now, if the conveyance guide 22 is inclined with respect to the horizontal plane while being lowered, and the guide projections 61 through 64 are caught by the guide grooves 71 and 81, the lowering of the conveyance guide 22 may not be started, and the guide 22 may be stopped in a state where a space G1 cannot be ensured. In contrast, according to the present embodiment, the conveyance guide 22 is lowered toward the second position by a force greater than its own weight, through the biasing force of the biasing springs 67 and 68 applied to the conveyance guide 22 at the first position. That is, when the operation lever 76 is operated and the conveyance guide 22 is moved from the first position to the second position, the force releasing the transfer nip is applied to the conveyance guide 22. Thereby, supporting of the operation freeing the sheet conveyance path is enabled, and a space G1 can be ensured.
As illustrated in
When moving the conveyance guide 22 positioned at the third position to the first position, the user holds the guide plate 60, and elevates the plate 60 while inserting the plate in the inserting direction. Thereby, the guide projection 61 is elevated along the front side oblique portion 71c, and the guide projection 62 is elevated along the rear side oblique portion 71d. Then, the guide projection 61 presses the inclined plane 75c of the latch member 75, rotates the latch member 75 against the biasing spring 78, and is engaged to the engagement portion 75d. Thereby, as illustrated in
Further, as illustrated in
In this state, since the first mold spring 72 has a stopper plane 72b facing the backward direction, the guide projection 61 will not go over the stopper plane 72b even when it is biased toward the drawing direction, and the guide projection is fixed to this position. That is, the regulation unit 28 regulates the guide projection 61 of the conveyance guide 22 positioned at the second position from moving in the upward direction, i.e., upward U, downward direction, i.e., downward D, drawing direction, i.e., frontward F, and inserting direction, i.e., backward B. Further, in the state where the conveyance guide 22 is positioned at the second position, the first mold springs 72 and 82 contact the guide projections 61 and 63 when the guide projections 61 and 63 are biased toward the drawing direction, by which the movement of the conveyance guide 22 toward the drawing direction is regulated. Moreover, in the state where the conveyance guide 22 is positioned at the second position, the second mold springs 73 and 83 contact the guide projections 61 and 63 when the guide projections 61 and 63 are biased toward the inserting direction, by which the movement of the conveyance guide 22 toward the inserting direction is regulated. That is, the first mold springs 72 and 82 and the second mold springs 73 and 83 are disposed to protrude to the inner side of the horizontal portions 71a and 81a at the drawing direction side than the intersect portions 71x and 81x of the horizontal portions 71a and 81a, and regulate the movement of the guide projections 61 and 63 positioned at the second position in the drawing and inserting directions.
Upper walls 71g and 81g of the guide grooves 71 and 81 contact the guide projections 61 and 63 when the guide projections 61 and 63 are biased upward U, by which the movement of the conveyance guide 22 toward the upward direction is regulated. Upper surfaces 71h and 81h of the stoppers 71f and 81f contact the guide projections 61 and 63 when the guide projections 61 and 63 are biased downward D, by which the movement of the conveyance guide 22 toward the downward direction is regulated. That is, the upper walls 71g and 81g and the upper surfaces 71h and 81h form upper and lower walls of the horizontal portions 71a and 81a at the drawing direction side than the intersect portions 71x and 81x of the horizontal portions 71a and 81a, regulating the upward and downward movement of the guide projections 61 and 63 positioned at the second position. When assembling the conveyance guide 22 to the support plates 70 and 80 during assembly of the sheet feeding unit 20, the guide projections 62 and 61 are guided by the inclined plane 72a of the first mold spring 72 and inserted to the guide groove 71.
As illustrated in
When moving the conveyance guide 22 positioned at the second position to the third position, the user holds the guide plate 60 and inserts the plate 60 with a sufficient force toward the inserting direction. Thereby, the guide projection 61 is guided by the inclined plane 73a of the second mold spring 73, elastically deforms and goes over the second mold spring 73, to be positioned at the horizontal portion 71a and to be lowered along the front side oblique portion 71c so that the conveyance guide 22 is positioned at the third position (refer to
Next, the operation for performing replacement of the roller unit 27 in the sheet feeding unit 20 described above will be described in detail with respect to
The user pulls out the sheet cassette 21, and rotates the image forming apparatus 1 for 90 degrees so that the apparatus 1 is erected with the rear side of the image forming apparatus 1 positioned downward D. At this time, the conveyance guide 22 is positioned at the first position, so that when the sheet feeding unit 20 is viewed from a bottom side, as illustrated in
Then, the user operates the operation lever 76 to unlock the lock of the conveyance guide 22, holds the guide plate 60, and moves the position of the conveyance guide 22 from the first position to the second position. Thereby, as illustrated in
When the replacement operation is completed, the user moves the guide plate 60 with sufficient force to unlock the lock at the second position and move the guide plate to the first position, to prepare for the subsequent printing process.
As described above, according to the sheet feeding unit of the present embodiment, the second position is distant from the first position opposed to the sheet conveyance path R1, so that replacement of the roller unit 27 and the like can be performed when the conveyance guide 22 is positioned at the second position. The regulation unit 28 regulates the conveyance guide 22 positioned at the second position from moving upward U, downward D, in the drawing direction, i.e., frontward F, and in the inserting direction, i.e., backward B, with respect to the conveyance guide 22. Thereby, the workability of replacing the roller unit 27 and the like can be improved, even with the movable conveyance guide 22 disposed on the apparatus body 10.
According further to the sheet feeding unit 20 of the present embodiment, the conveyance guide 22 can be positioned at the third position suitable for treating sheet jamming, in addition to the first and second positions. Therefore, the workability regarding sheet jam can be improved.
According further to the sheet feeding unit 20 of the present embodiment, the regulation unit 28 is disposed at a position not interfering with the guide grooves 71 and 81. Therefore, the regulation unit 28 does not affect the movement of the conveyance guide 22 and the sheet cassette 21, and does not deteriorate the usability of the apparatus by the user.
Next, the second embodiment of the present invention will be described in detail with reference to
In the present embodiment, the regulation unit 128 is disposed lower portion of the front side oblique portion 71c. The regulation unit 128 has a mold spring, that is, contact portion, 128a having an inclined plane respectively inclined toward the upward and downward directions, as in the second mold springs 73 and 83 of the first embodiment. Therefore, when the guide projection 61 is lowered along the front side oblique portion 71c during the movement of the conveyance guide 22 from the first position, the guide projection 61 contacts the mold spring 128a. In this case, the guide projection 61 is guided by the inclined plane facing upward U of the mold spring 128a, and as illustrated in
When moving the conveyance guide 22 positioned at the second position to the first position, the user holds the guide plate 60, and pushes the plate upward U with sufficient force. Thereby, the guide projection 61 is guided by the inclined plane facing downward D of the mold spring 128a, elastically deforms and goes over the mold spring 128a, passes through the front side oblique portion 71c to be positioned at the first position.
That is, the guide groove 71 includes the horizontal portion 71a disposed horizontally from the drawing direction side toward the inserting direction of the apparatus body 20a, and the front side oblique portion 71c intersecting the horizontal portion 71a at the intersect portion 71x and disposed diagonally upward U in the inserting direction from the intersect portion 71x, regulating the guide projection 61 in the downward direction and in the drawing and inserting direction at the downward side D than the intersect portion 71x. Then, when the conveyance guide 22 is positioned at the first position, the guide projection 61 is positioned at the uppermost position of the front side oblique portion 71c, and when the conveyance guide 22 is positioned at the second position, the guide projection 61 is positioned downward D than the intersect portion 71x of the front side oblique portion 71c. Further, the regulation unit 128 includes a wall 71j of the front side oblique portion 71c regulating the guide projection 61 in the drawing and inserting direction and in the downward direction at the downward side D than the intersect portion 71x when the conveyance guide 22 is positioned at the second position, and the mold spring 128a regulating the movement in the upward direction of the guide projection 61 by protruding to the inner side of the front side oblique portion 71c and being in contact with the guide projection 61 when the projection 61 is biased in the upward direction.
Also according to the sheet feeding unit 20 of the present embodiment, the second position is distant from the first position opposed to the sheet conveyance path R1, so that replacement of the roller unit 27 and the like can be performed when the conveyance guide 22 is positioned at the second position. The regulation unit 28 regulates the conveyance guide 22 positioned at the second position from moving upward U, downward D, in the drawing direction, i.e., frontward F, and in the inserting direction, i.e., backward B, with respect to the conveyance guide 22. Thereby, the workability of replacing the roller unit 27 and the like can be improved, even with the movable conveyance guide 22 disposed on the apparatus body 10.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary 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.
This application claims the benefit of Japanese Patent Application No. 2015-108834, filed May 28, 2015, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2015-108834 | May 2015 | JP | national |