This application claims priority from Japanese Patent Application No. 2013-028763, filed on Feb. 18, 2013, which is incorporated herein by reference in its entirety.
Aspects described herein relate to a conveyor device that conveys a sheet by a conveyor roller rotatably supported by bearings.
There has been known a conveyor device that is allowed to convey a sheet along a conveyance path. As an example of such a conveyor device, there is an image recording apparatus, such as a printer or a multifunction device. The conveyor device includes one or more roller pairs to convey a sheet while pinching the sheet. Each of the one or more roller pairs includes a conveyor roller that extends in a width direction and rotates by transmission of a drive force from a motor and a following roller that is disposed facing the conveyor roller while being urged toward the conveyor roller and rotates following the rotation of the conveyor roller. A middle portion of the conveyor roller in the width direction comes into contact with a sheet and end portions of the conveyor roller in the width direction are rotatably supported by bearings, respectively. The bearings are supported by a frame of the conveyor device.
As an example of the above-described conveyor device, there has been known an inkjet recording apparatus in which both end portions of a shaft of a conveyor roller in the width direction are supported by bearings, respectively, and the bearings are disposed on a frame constituting a portion of the inkjet recording apparatus.
In the known conveyor device, both end portions of the conveyor roller in the width direction may be supported by the bearings, respectively, nevertheless, the middle portion of the conveyor roller in the width direction might not be supported by any member. Therefore, there may be a risk that the conveyor roller may be deformed due to the urging of the following roller.
In order to solve the above-described problem, it may be conceivable that a distance in the width direction between the bearings that may support the respective end portions of the conveyor roller may be shortened. Nevertheless, the distance between the bearings might not be permitted to be less than a dimension in the width direction of the sheet having a maximum size that may be allowed to be conveyed in the conveyor device.
Accordingly, aspects of the disclosure have been made in light of the above-described problem. That is, aspects of the disclosure provide for a conveyor device that may reduce deformation of a conveyor roller.
In at least one aspect, a conveyor device includes a conveyor roller extending in a width direction orthogonal to a conveyance direction, the conveyor roller configured to receive a force orthogonal to both the width direction and the conveyance direction; a bearing configured to rotatably support the conveyor roller, and the bearing including a first shaft-support portion configured to rotatably support the conveyor roller and disposed outside of a conveyance area of the conveyor roller in the width direction; and a second shaft-support portion extending from the first shaft-support portion at least to the conveyance area with respect to the width direction, and configured to rotatably support the conveyor roller and expose a portion of a surface of the conveyor roller to the conveyance area.
According to the above-described configuration, the second support portion disposed on at least one of the pair of bearings may extend to the sheet conveyance area. Thus, the distance between the bearings in the width direction may be shortened. Accordingly, the deformation of the conveyor roller caused by the urging of the following roller may be reduced. According to the above-described configuration, the second support portion may support the conveyor roller such that the portion, facing the following roller, of the conveyor roller may be exposed. Thus, the extension of the second support portion of at least one of the pair of bearings to the conveyance area might not interfere with the sheet conveyance and might not increase the size of the conveyor device in the width direction.
According to the aspects of the disclosure, the deformation of the conveyor roller may be reduced.
For a more complete understanding of the present disclosure, needs satisfied thereby, and the objects, features, and advantages thereof, reference now is made to the following descriptions taken in connection with the accompanying drawings.
An illustrative embodiment according to one or more aspects is described below with reference to the accompanying drawings. The illustrative embodiment described below is merely an example. Various changes, arrangements and modifications may be applied therein without departing from the spirit and scope of the disclosure. In the description below, an up-down direction 7 may be defined with reference to an orientation of a multifunction device 10 that may be disposed in which it may be intended to be used (e.g., an orientation depicted in
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A pair of side guides (not depicted) that may be allowed to move in the right-left direction 9 may be supported by the bottom plate 22 of the feed tray 20. One side surface of each side guide may contact one of right and left edges of one or more recording sheets 12 placed on the bottom plate 22. As one of the side guides moves toward one side in the right-left direction 9, the other of the side guides may move toward the other side in the right-left direction 9 in synchronization with the movement of the one side guide. With this configuration, in the illustrative embodiment, one or more recording sheets 12 that may be placed in the feed tray 20 and may be to be conveyed in a conveyance path 65 and to be recorded with an image by a recording unit 24, may be aligned with a center line in the right-left direction 9.
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The feed roller 25 may be configured to rotate by transmission of a drive force from a conveyor motor 53 (see
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The curved section 33 may be defined by an outside guide member 18 and an inside guide member 19 that may face each other and may be spaced apart from each other at a predetermined interval. The outside guide member 18 may define the outside portion of the curved section 33. The inside guide member 19 may define the inside portion of the curved section 33. The straight section 34 may be defined by the recording unit 24 and the platen 42 at a position where the recording unit 24 may be disposed, wherein the recording unit 24 and the platen 42 may face each other and be spaced apart from each other at a predetermined interval. The outside and inside guide members 18 and 19 may extend in the right-left direction 9 that may be orthogonal to a direction that the surface of the drawing sheet of
The one or more recording sheets 12 supported by the feed tray 20 may be conveyed one-by-one by the feed roller 25 such that the recording sheet 12 may move upward and make a U-turn in the curved section 33, and thus, the recording sheet 12 may reach the conveyor roller pair 59. The recording sheet 12 pinched by the conveyor roller pair 59 may be then conveyed in the straight section 34 toward the recording unit 24 along the front-rear direction 8. The recording sheet 12 reached under the recording unit 24 may be recorded with an image by the recording unit 24. The recording sheet 12 recorded with the image may be then further conveyed in the straight section 34 along the front-rear direction 8 and thus may be outputted onto the output tray 21. As described above, the recording sheet 12 may be conveyed along a conveyance direction 15 indicated by a dotted-and-dashed line with an arrow in
The outside guide member 18 may be configured to be pivotable in directions indicated by an arrow 66 on a shaft 48 disposed at a lower portion of the outside guide member 18. The outside guide member 18 may define the outside portion of the curved section 33 in a first state where the outside guide member 18 may be located at a position indicated by a solid line in
In other embodiments, the state change of the outside guide member 18 may be implemented in another manner instead of the pivot. For example, the outside guide member 18 may be configured to be attachable to and detachable from the printer unit 11. In this case, the state of the outside guide member 18 may be changed between a first state where the outside guide member 18 may be attached on the printer unit 11 and define the outside portion of the curved section 33 and a second state where the outside guide member 18 may be removed from the printer unit 11 and expose the curved section 33.
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The carriage 40 may be supported by two guide rails 56 and 57 so as to be able to reciprocate in the front-rear direction 8, wherein the guide rails 56 and 57 may be disposed spaced apart from each other. The recording head 38 may be mounted on the carriage 40. Ink may be supplied to the recording head 38 from an ink cartridge (not depicted). The recording head 38 may have nozzles 39 in its lower surface. While the carriage 40 moves in the right-left direction 9, the recording head 38 may eject ink droplets toward the platen 42 from the nozzles 39. Thus, an image may be recorded on the recording sheet 12 that may be supported by the platen 42 while being conveyed in the conveyance direction 15.
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The conveyor roller pair 59 may comprise a conveyor roller 60 disposed at the lower side of the straight section 34 and a pinch roller 61 (as an example of a following roller) disposed at the upper side of the straight section 34 with facing the conveyor roller 60. As depicted in
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The conveyor roller 60 and the discharge roller 62 may be configured to rotate by the transmission of a drive force from the conveyor motor 53 (see
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The first shaft-support portion 81 may have a circular tubular shape. The opening 79 may be defined in the first shaft-support portion 81. The conveyor roller 60 may pass through the opening 79. At least a portion of an internal circumferential surface of the opening 79 may be in contact with a surface of the conveyor roller 60 while the conveyor roller 60 may pass through the opening 79.
A recording sheet 12 being conveyed in the conveyance path 65 may come into contact with a portion of the surface of the conveyor roller 60 (more specifically, a portion that may extend in the right-left direction 9 and around an entire circumferential area of the surface of the conveyor roller 60). An area, with which the recording sheet 12 being conveyed in the conveyance path 65 may come into contact, of the surface of the conveyor roller 60 (as an example of a conveyance area) may be located between a more left position than the first shaft-support portion 81 that may be disposed at the more right position than the conveyance path 65 in the right-left direction 9 and a more right position than the first shaft-support portion 81 that may be disposed at the more left position than the conveyance path 65 in the right-left direction 9.
That is, the first shaft-support portion 81 may be disposed outside of the area, with which a recording sheet 12 may be come into contact, of the conveyor roller 60 in the right-left direction 9. More specifically, the first shaft-support portion 81 of the right bearing 80 (e.g., one of the pair of bearings 80) of the pair of bearings 80 may be disposed at a more right position than the area, which may come into contact with a recording sheet 12, of the conveyor roller 60 (e.g., further outside than the area on one side in the right-left direction 9). The first shaft-support portion 81 of the left bearing 80 (e.g., the other of the pair of bearings 80) of the pair of bearings 80 may be disposed at a further left position than the area, which may come into contact with a recording sheet 12, of the conveyor roller 60 (e.g., further outside than the area on the other side in the right-left direction 9).
The second shaft-support portion 82 may extend inward from the first shaft-support portion 81 in the right-left direction 9. More specifically, the second shaft-support portion 82 of the right bearing 80 of the pair of bearings 80 may extend leftward from the first shaft-support portion 81, and the second shaft-support portion 82 of the left bearing 80 of the pair of bearings 80 may extend rightward from the first shaft-support portion 81. The second shaft-support portion 82 may extend, in the right-left direction 9, from the first shaft-support portion 81 to the area, which may come into contact a recording sheet 12 being conveyed in the conveyance path 65, of the surface of the conveyor roller 60, and may contact the surface of the sheet contact area of the conveyor roller 60.
In the illustrative embodiment, the pinch rollers 61 may be disposed more inside than the second shaft-support portions 82 in the right-left direction 9. More specifically, the pinch rollers 61 may be disposed at respective positions that may be more left than the second shaft-support portion 82 of the right bearing 80 of the pair of bearings 80 in the right-left direction 9 and more right than the second shaft-support portion 82 of the left bearing 80 of the pair of bearings 80 in the right-left direction 9.
The second shaft-support portion 82 may be an arc-shaped thin plate. An arc-shaped inner surface 84 of the second shaft-support portion 82 may be contiguous to the internal circumferential surface of the opening 79 of the first shaft-support portion 81. The inner surface 84 may be in contact with the surface of the conveyor roller 60. The conveyor roller 60 may be rotarable in contact with the inner surface 84. That is, the second shaft-support portion 82 may support the conveyor roller 60 to be rotatable.
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The first projection 90 may project from a portion of an external circumferential surface of the first shaft-support portion 81. The first projection 90 may extend along a circumferential direction of the external circumferential surface of the first shaft-support portion 81 to have a predetermined width. The predetermined width may be narrower than a width of a recess 94 defined in the engagement portion 71 of each of the side frames 55.
The flange 83 may be disposed more inside than the first projection 90 in the right-left direction 9 on the external circumferential surface of the first shaft-support portion 81. That is, the flange 83 may be disposed at a more left position than the first projection 90 and spaced apart from the first projection 90 at a predetermined interval in the right bearing 80 of the pair of bearings 80, and the flange 83 may be disposed at a more right position than the first projection 90 and spaced apart from the first projection 90 at the predetermined interval in the left bearing 80 of the pair of bearings 80. The predetermined interval may be substantially the same as a thickness of an end portion of the engagement portion 71 defined in each side frame 55 (i.e., a dimension in the right-left direction 9).
With this configuration, the end portion of the engagement portion 71 of the side frame 55 may be inserted between the first projection 90 of the bearing 80 and the flange 83 and thus the bearing 80 may be fitted in the engagement portion 71 of the side frame 55. That is, the flange 83 and the first projection 90 may define a groove therebetween such that the bearing 80 may be engaged in the engagement portion 71 of the side frame 55. In the state where the bearing 80 is disposed on the engagement portion 71, the first projection 90 and the second shaft-support portion 82 may be located on opposite sides of the side frame 55 and the flange 83 may be located on the second shaft-support portion 82 side with respect to the side frame 55 (see
The second projection 91 may be disposed on the flange 83. The second projection 91 may project outward from the flange 83 in the right-left direction 9. That is, the second projection 91 may project rightward from a right surface of the flange 83 in the right bearing 80 of the pair of bearings 80, and the second projection 91 may project leftward from a left surface of the flange 83 in the left bearing 80 of the pair of bearings 80.
Each of the side frames 55 may have an opening 93 and the recess 94. The first shaft-support portion 81 may be configured to be fitted in the engagement portion 71 and be rotatable with being fitted in the engagement portion 71. The opening 93 may be disposed such that the opening 93 may coincide with the second projection 91 in side view when the bearing 80 is rotated with being fitted in the engagement portion 71. The opening 93 may have substantially the same shape and substantially the same size as the second projection 91. Thus, the second projection 91 may pass through the opening 93 and thus may be engagable in the opening 93 while the second projection 91 may coincide with the opening 93 in side view.
The recess 94 may be defined in the internal circumferential surface of the arc-shaped engagement portion 71. The recess 94 may be recessed in a direction from a center of the opening 79 to the outside when the bearing 80 is fitted in the engagement portion 71. The recess 94 may be disposed at a position that the recess 94 may coincide with the first projection 90 in side view when the bearing 80 is rotated with being fitted in the engagement portion 71. A length of the recess 94 along the internal circumferential surface of the engagement portion 71 may be longer than a length of the first projection 90 along the external circumferential surface of the first projection 90 disposed on the external circumferential surface of the first shaft-support portion 81. A depth of the recess 94 may be greater than a height of the first projection 90. Thus, the first projection 90 may pass the recess 94 in the right-left direction 9 while the first projection 90 may coincide with the recess 94 in side view.
The first projection 90 and the second projection 91 of the bearing 80 and the opening 93 and the recess 94 of the side frame 55 may be disposed at the respective positions to satisfy a condition described below. That is, the positions of the first projection 90, the second projection 91, the opening 93, and the recess 94 may be determined such that the first projection 90 might not be allowed to pass the recess 94 when the second projection 91 is in engagement with the opening 93. In other words, the second projection 91 may be allowed to pass the opening 93 of the side frame 55 when the first projection 90 does not coincide with the recess 94 in side view.
Hereinafter, a procedure of how to fit the left bearing 80 of the pair of bearings 80 into the engagement portion 71 of the left side frame 55 of the pair of side frames 55 is described with reference to
The bearing 80 may be located on the right of the engagement portion 71 while the first projection 90 may coincide with the recess 94 in side view. Then, the bearing 80 may be moved leftward. Thus, the first projection 90 may pass the recess 94 and the first shaft-support portion 81 may be fit in the engagement portion 71. After that, the first shaft-support portion 81 may be rotated such that the second projection 91 may coincide with the opening 93 in side view. Although the second projection 91 may come into contact with the right side-surface of the side frame 55 to interfere with the rotation of the first shaft-support portion 81, the first shaft-support portion 81 may be continuously rotated with the flange 83 being warped.
When the second projection 91 and the opening 93 coincide with each other in side view, the second projection 91 and the opening 93 may be engaged with each other. Thereafter, the first shaft-support portion 81 may become impossible to rotate unless the flange 83 is warped to release the engagement of the second projection 91 and the opening 93. That is, the second projection 91 may pass through the opening 93 defined in the side frame 55 to restrict the rotation of the first shaft-support portion 81 fitted in the engagement portion 71. When the second projection 91 coincides with the opening 93 in side view, the first projection 90 might not coincide with the recess 94 in side view. Therefore, the movement of the bearing 80 in the right-left direction 9 may also be restricted. A removal of the bearing 80 from the side frame 55 may be reverse of the above-described procedure.
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The predetermined area 74 may be defined more inside than the second shaft-support portions 82 of the pair of bearings 80 in the right-left direction 9. In other words, the second shaft-support portions 82 may be disposed further outside than the predetermined area 74 of the surface of the conveyor roller 60 in the right-left direction 9. More specifically, the second shaft-support portion 82 of the left bearing 80 of the pair of bearings 80 may be disposed at a more left position than the predetermined area 74 and the second shaft-support portion 82 of the right bearing 80 of the pair of bearings 80 may be disposed at a more right position than the predetermined area 74.
In other embodiments, the surface of the conveyor roller 60 may be configured to apply higher friction to the recording sheet 12 in a manner other than the ceramic coating. For example, the surface of the conveyor roller 60 may comprise another material, such as rubber, instead of ceramic.
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Upper ends of coil springs 78 (as an example of a second urging member) may be secured to the lower surfaces of the rear protrusions 77, respectively. The other ends of the coil springs 78 may be secured to the side frames 55, respectively. Nevertheless, in other embodiments, for example, the other ends of the coil springs 78 may be secured to another frame instead of the side frames 55. A length of each coil spring 78 in the state where the upper surfaces of the rear protrusions 77 may be in contact with the respective lower surfaces of the second shaft-support portions 82 may be shorter than its length in natural state. Thus, the coil springs 78 may urge the upper surfaces of the rear protrusions 77, respectively, upward, that is, toward the corresponding second shaft-support portions 82.
According to the illustrative embodiment, the second shaft-support portions 82 of the pair of bearings 80 may extend to the conveyance area contacting the recording sheet 12. Thus, a distance between the bearings 80 in the right-left direction 9 may be shortened. As a consequence, the deformation of the conveyor roller 60 caused by the urging of the pinch rollers 61 may be restricted. According to the illustrative embodiment, the second shaft-support portions 82 may support the conveyor roller 60 such that the area, which may be located on the side where the pinch roller 61 may be present, of the surface of the conveyor roller 60 may be exposed. With this configuration, the presence of the second shaft-support portions 82 of the bearings 80 to the conveyance area might not interfere with the conveyance of the recording sheet 12 nor might not cause an increase in size of the multifunction device 10 in the right-left direction 9.
According to the illustrative embodiment, each of the bearings 80 may comprise the second shaft-support portion 82. Therefore, the distance between the bearings 80 in the right-left direction 9 may be further shortened as compared with a case where only one of the bearings 80 may have the second shaft-support portion 82.
According to the illustrative embodiment, the platen 42 may be pressed against the second shaft-support portions 82 by the coil springs 78. Thus, the platen 42 may be positioned with respect to the position of the conveyor roller 60. As described above, according to the illustrative embodiment, the deformation of the conveyor roller 60 may be restricted. Therefore, the platen 42 positioned with respect to the position of such a conveyor roller 60 may be positioned accurately.
According to the illustrative embodiment, the conveyor roller 60 may have the area on which the ceramic coating may be applied, on the portion of its surface. Thus, the nip force (at a nip point) between the conveyor roller 60 and the pinch rollers 61 may be increased. As a consequence, this configuration may allow the conveyor roller pair 59 to convey a recording sheet 12 easily. According to the illustrative embodiment, the second shaft-support portions 82 may be disposed further outside than the area, on which the ceramic coating may be applied, on the conveyor roller 60, in the right-left direction 9. Therefore, the portion coated with ceramic might not come into contact with the bearings 80. Thus, the bearings 80 may be avoided to be worn that may be caused by the frictional movement of the portion coated with ceramic on the bearings 80.
The hollow conveyor roller 60 may be likely to be deformed. Therefore, the configuration according to the illustrative embodiment may be preferable to implement the aspects of the disclosure.
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According to the illustrative embodiment, the first shaft-support portion 81 may be fitted in the engagement portion 71 by which the bearing 80 may be moved toward the engagement portion 71 of the side frame 55 in the right-left direction 9 after the first projection 90 coincides with the recess 94 in side view. Then, the first shaft-support portion 81 may be rotated while the first shaft-support portion 81 may be fitted in the engagement portion 71, whereby the first projection 90 might not coincide with the recess 94 in side view. Thus, the second projection 91 may be then allowed to pass through the opening 93. As a consequence, the rotation of the bearing 80 fitted in the engagement portion 71 may be prevented or reduced.
In the state where the second projection 91 passes through the opening 93, the first projection 90 might not coincide with the recess 94 in side view. Therefore, the movement of the bearing 80 in the right-left direction 9 might not be allowed because the end of the engagement portion 71 prevents the movement of the first projection 90. That is, according to the illustrative embodiment, this configuration may prevent or reduce the movement in the right-left direction 9 of the bearing 80 fitted in the engagement portion 71.
In the above-described illustrative embodiment, both of the bearings 80 each may comprise the first shaft-support portion 81 and the second shaft-support portion 82. Nevertheless, in a first variation, for example, only one of the bearings 80 may comprise the first shaft-support portion 81 and the second shaft-support portion 82. In this case, the other of the bearings 80 may be, for example, a known ball bearing having a circular tubular shape. That is, in the aspects of the disclosure, at least one of the bearings 80 may comprise the first shaft-support portion 81 and the second shaft-support portion 82.
In the above-described illustrative embodiment, the multifunction device 10 may be configured to align one or more recording sheets 12 placed on the feed tray 20 with respect to the center line in the right-left direction 9. Nevertheless, in a second variation, for example, the multifunction device 10 may be configured to align one or more recording sheets 12 placed on the feed tray 20 with respect to a side plate (not depicted) uprightly disposed at one of the left and right ends of the bottom plate 22 of the feed tray 20 in the right-left direction 9. This side alignment may be implemented by, for example, a single side guide that may be disposed on the feed tray 20 and be movable in the right-left direction 9, instead of the pair of side guides.
In the second variation, when only the one of the bearings 80 comprises the first shaft-support portion 81 and the second shaft-support portion 82 in like manner as the first variation, the bearing 80 that may correspond to the side edge, which may be used as the reference of the sheet alignment, of the recording sheet 13 in the right-left direction 9 may preferably comprise the first shaft-support portion 81 and the second shaft-support portion 82.
In the above-described illustrative embodiment, the pinch rollers 61 may be disposed more inside than the second shaft-support portions 82 in the right-left direction 9. Nevertheless, in a third variation, for example, as depicted in
In the third variation described above, one or more of the pinch rollers 61 may be disposed at the same positions as the second shaft-support portions 82 in the right-left direction 9. Nevertheless, in other embodiments, for example, another member other than the pinch rollers 61 may press the recording sheet 12 at the same positions as the second shaft-support portions 82 in the right-left direction 9. That is, the pinch rollers 61 may be disposed more inside than the second shaft-support portions 82 in the right-left direction 9 in like manner with the above-described illustrative embodiment, and one or more pressing members each comprising a protrusion protruding downward may be disposed at the same positions as the second shaft-support portions 82 in the right-left direction 9 so as to face the respective second shaft-support portions 82. The pressing members may be configured to come into contact with the upper surface of the recording sheet 12.
According to the third variation, the pressing members such as the pinch rollers 61 may come into contact with the both side edge portions of the recording sheet 12 in the right-left direction 9, thereby restricting a lifting of the both side edge portions of the recording sheet 12 in the right-left direction 9. In a case where the pinch rollers 61 are adopted as the pressing members, another pressing member might not be needed in addition to the pinch rollers 61.
In the above-described illustrative embodiment, as depicted in
For example, as depicted in
According to the fourth variation, the position 96 that may be opposite to the pinching position 95 of the recording sheet 12 by the conveyor roller pair 59 with respect to the conveyor roller 60 may be a supported position where the deformation of the conveyor roller 60 caused by the urging of the pinch rollers 61 may be effectively restricted. Therefore, according to the fourth variation, the second shaft-support portion 82 may support the portion including the position 96 described above.
Therefore, the restriction efficiency of the deformation of the conveyor roller 60 may be increased.
In the above-described illustrative embodiment, the conveyor roller 60 may be the hollow cylindrical member. Nevertheless, the shape of the conveyor roller 60 might not be limited to the hollow cylindrical shape. In a fifth variation, for example, the conveyor roller 60 might not necessarily have a hollow structure. The conveyor roller 60 may comprise a shaft extending in the right-left direction 9 and a roller portion covering the shaft. In this case, the conveyor roller 60 may comprise a single roller portion extending in the right-left direction 9 or a plurality of roller portions spaced apart from each other in the right-left direction 9.
In the above-described illustrative embodiment, the first shaft-support portion 81 of each of the bearings 80 may have the opening 79. Nevertheless, in a sixth variation, for example, the first shaft-support portion 81 may be configured to contact a portion of the surface of the conveyor roller 60 to support the conveyor roller 60 similar to the second shaft-support portion 82.
In the above-described illustrative embodiment, the conveyor roller 60 may be disposed at the lower side of the straight section 34 and the pinch rollers 61 may be disposed at the upper side of the straight section 34 with facing the conveyor roller 60. Nevertheless, in a seventh variation, for example, the conveyor roller 60 may be disposed at the upper side of the straight section 34 and the pinch rollers 61 may be disposed at the lower side of the straight section 34 with facing the conveyor roller 60 with the second support portion or portions 82 opposite at least a part of straight section 34.
Number | Date | Country | Kind |
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2013-028763 | Feb 2013 | JP | national |