The present application claims priority from Japanese Patent Application Nos. 2006-208692 and 2006-207833, both of which were filed on Jul. 31, 2006, the disclosure of which is herein incorporated by reference in its entirety.
1. Field of the Invention
The present invention relates to an inkjet recording apparatus for forming or recording an image on a recording medium.
2. Description of Related Art
An inkjet printer as a type of the inkjet recording apparatus is disclosed in JP-A-2006-131353. The inkjet printer includes an inkjet head, a feeder belt, and a medium holder. The inkjet head has an ink ejection surface in which openings of a plurality of nozzles are arranged, and the medium holder is capable of accommodating a stack of recording media, which may be cut sheets of paper. Recording media stacked on the medium holder are one by one picked up from the medium holder and fed by the feeder belt to a position to be opposed to the ink ejection surface of the inkjet head. When each recording medium reaches this position, droplets of ink are ejected from the nozzle openings to form an image on the recording medium.
It is often the case that foreign matter, such as paper dust, is present on a recording medium. Further, a recording medium is subject to an external force or vibrations while fed inside the printer. Hence, it may occur that during a recording medium is fed to the position to be opposed to the ink ejection surface after picked up from the medium holder, foreign matter on a surface of the recording medium departs from the surface and scatters around. Some of the foreign matter thus scattering may waft around the feeder belt and land on the ink ejection surface of the inkjet head, leading to closure of the nozzle openings or entrance of the foreign matter into the nozzles, which causes defect or failure in ejection of ink droplets. A remover can be disposed near the inkjet head in order to remove the foreign matter on the surface of the recording medium. However, it is impossible to perfectly remove the foreign matter from the surface of the recording medium with the remover, and a portion of the foreign matter inevitably scatters around. It is difficult to reliably inhibit the wafting foreign matter from landing on the ink ejection surface.
This invention has been developed in light of the above-described situations, and it is an object of the invention, therefore, to provide an inkjet recording apparatus which can reliably inhibit that foreign matter scattering from a surface of a recording medium lands on an ink ejection surface.
To attain the above object, the invention provides an inkjet recording apparatus including a feeding device, a remover, and an inkjet head. The feeding device feeds a recording medium along a feed path passing through a removing area. An opposingly-feeding surface at least a part of which is opposed to the ink ejection surface extends along the feed path, and the removing area is located under the opposingly-feeding surface and within the opposingly-feeding surface as seen in a vertical direction. The remover removes foreign matter from a surface of the recording medium during the recording medium is fed through the removing area by the feeding device. The inkjet head is disposed downstream of the remover with respect to a feeding direction in which the recording medium is fed. The inkjet head has an ink ejection surface in which a nozzle is open, and an ink droplet is ejected from the nozzle toward a recording surface of the recording medium while the recording medium is fed along the part of the opposingly-feeding surface.
Since the removing area is located under the opposingly-feeding surface as well as within the opposingly-feeding surface as seen in a vertical direction, the foreign matter, which scatters from the recording medium upon the removal at the removing area and wafts, is inhibited from entering a clearance between the opposingly-feeding surface and the ink ejection surface. Thus, the wafting foreign matter is reliably inhibited from landing on the ink ejection surface.
A first preferable form of the inkjet recording apparatus is such that the opposingly-feeding surface is a planar surface having a greatest area among all the planar surfaces extending along the feed path.
A second preferable form of the inkjet recording apparatus is such that the whole remover is located within the opposingly-feeding surface as seen in the vertical direction.
According to this form, the inkjet recording apparatus can be downsized.
A third preferable form of the inkjet recording apparatus is such that the opposingly-feeding surface is horizontal, and the recording surface of the recording medium does not once face vertically upward at a segment of the feed path between the removing area and the opposingly-feeding surface.
According to this form, the foreign matter scattering from the recording surface of the recording medium does not tend to land back on the recording surface, at the segment of the feed path between the removing area and the opposingly-feeding surface. Hence, less foreign matter is introduced to the opposingly-feeding surface. Thus, landing of foreign matter on the ink ejection surface is further reliably inhibited.
A fourth preferable form of the inkjet recording apparatus further includes a recording-area cover which covers at least the inkjet heads and a portion of the opposingly-feeding surface which portion is opposed to the ink ejection surface of the inkjet head.
According to this form, the foreign matter is further reliably inhibited from landing on the ink ejection surface.
A fifth preferable form of the inkjet recording apparatus further includes a removing-area cover which covers at least the remover and the removing area.
According to this form, the foreign matter departing from the recording medium is prevented from scattering around.
A sixth preferable form of the inkjet recording apparatus is such that the medium supply device includes a medium holder which accommodates a stack of the recording media, and an upper surface of each of the stack of the recording media is the recording surface from which the foreign matter is removed by the remover.
Foreign matter or dust may be accumulated on the topmost one of the stack of the recording media while the inkjet recording apparatus is not in use. According to this form, such foreign matter or dust is removed by the remover.
A seventh preferable form of the inkjet recording apparatus is such that the medium supply device includes a medium holder and a pickup roller. The medium holder accommodates a stack of the recording media. The pickup roller rotates in contact with a surface of a topmost one of the stack of the recording media in the medium holder in order to supply the topmost recording medium, the surface of the topmost recording medium in contact with the pickup roller is the recording surface from which the foreign matter is removed by the remover.
According to this form, even when dust is produced as the foreign matter upon supply of the recording medium from the medium holder to the feeding device, such dust is removed by the remover.
The above and other objects, features, advantages and technical and industrial significance of the present invention will be better understood by reading the following detailed description of preferred embodiments of the invention, when considered in connection with the accompanying drawings, in which:
Hereinafter, there will be described presently preferred embodiments of the invention with reference to the accompanying drawings.
Referring to
In
The sheet supply device 11 includes a sheet holder 11a as a medium holder, a pickup roller 11b, guide rollers 16a, 16a′, and a pair of guide plates 16b, namely, an inner guide plate and an outer guide plate. The guide plates 16b function as a first turnover guide. The sheet holder 11a accommodates a stack of cut sheets P. The pickup roller 11b is driven by a motor (not shown) to sequentially pick up the cut sheets P from inside the sheet holder 11a from the topmost sheet P, and feed out the cut sheet P leftward as seen in
The feeding device 13 feeds the cut sheet P as fed out from the sheet supply device 11, and includes the intermediate feeder belt 17a, a guide plate 18 as a second turnover guide, a primary feeder belt 8, a platen 15, and a nip roller 17b′. The intermediate feeder belt 17a is an endless belt wound around two belt rollers 17b, 17c, and the primary feeder belt 8 is an endless belt wound around two belt rollers 6, 7. The platen 15 is disposed inside a circle formed by the endless feeder belt 8 and opposed to the four inkjet heads 1. At least the feeding surface of the intermediate feeder belt 17a is formed of silicone resin, and thus the feeding surface of the intermediate feeder belt 17 has such a tackiness that the cut sheet P fed out from the sheet supply device 11 is nipped between the nip roller 17b′ and the belt roller 17b disposed adjacent to the nip roller 17b′ in pressed contact to pressure-sensitively adhere to the feeding surface of the intermediate feeder belt 17a. The cut sheet P is fed upward and rightward as seen in
The cut sheet P as detached from the feeding surface of the intermediate feeder belt 17a by the separating plate 17d is guided by the guide plate 18 onto an outer circumferential surface, or a feeding surface, of the primary feeder belt 8 disposed above the intermediate feeder belt 17a. The feeding surface of the primary feeder belt 8 also has a tackiness. The guide plate 18 is curved along an outer circumferential surface of the belt roller 7. More specifically, the guide plate 18 functions to upward feed the cut sheet P as detached from the feeding surface of the intermediate feeder belt 17a, while turning over the cut sheet P, and change the feeding direction from rightward to leftward as seen in
When a feeder motor (not shown) rotates the belt roller 6, the primary feeder belt 8 circulates and feeds the cut sheet P that is pressed onto the feeding surface thereof by the nip roller 4 and pressure-sensitively adhering thereto. The cut sheet P is thus fed toward the catch tray 12 via an area where the cut sheet P is opposed to the inkjet heads 1.
At a position on the primary feeder belt 8 and near a sheet ejection opening, there is disposed a separating plate 14. The cut sheet P having been fed by the primary feeder belt 8 is detached from the feeding surface of the primary feeder belt 8 by the separating plate 14, and ejected onto the catch tray 12 disposed downstream of the primary feeder belt 8.
The four inkjet heads 1 are for ejecting droplets of respective color inks, i.e., magenta, yellow, cyan, and black inks, and arranged along a feeding direction in which the cut sheet P is fed. That is, the inkjet printer 101 is a line printer. In each of the inkjet heads 1 are formed ink passages each including a nozzle 108 from which an ink droplet is ejected. Each inkjet head 1 is a rectangular parallel-piped long in a direction perpendicular to the feeding direction. An under surface of the inkjet head 1 constitutes an ink ejection surface 2a in which the nozzles 108 open. A part of the opposingly-feeding surface of the primary feeder belt 8, is opposed to the ink ejection surfaces 2a of the inkjet heads 1, extends along the feed path of the cut sheet P, and corresponds to a recording area A. As the cut sheet P is fed by the primary feeder belt 8 and passes through the recording area A, i.e., just under the four inkjet heads 1, droplets of the respective color inks are ejected from the ink ejection surfaces 2a of the inkjet heads 1 toward the recording surface of the cut sheet P, in order to form or record a desired color image within a printing area in the cut sheet P. A recording-area cover 3 is disposed to cover the inkjet heads 1 and a portion of the primary feeder belt 8 corresponding to the recording area A. A positive-pressure keeper 17 is attached to the recording-area cover 3. The positive-pressure keeper 17 keeps positive an internal pressure of the recording-area cover 3. Thus, there is formed an air flow from an internal space of the recording-area cover 3 to an external space thereof, thereby preventing entrance of paper dust and ink mist into the recording-area cover 3.
The remover roller 20 operates to remove the foreign matter, e.g., paper dust, from the recording surface of the cut sheet P being fed by the intermediate feeder belt 17a. The remover roller 20 is disposed near an upstream end of the intermediate feeder belt 17a at which the cut sheet P is received by the intermediate feeder belt 17a. The remover roller 20 contacts a downward-facing surface in the feeding surface of the intermediate feeder belt 17a. A planar surface in the downward-facing surface of the feeding surface of the intermediate feeder belt 17a, which planar surface is opposed to the remover roller 20, corresponds to a removing area B where the foreign matter is removed from the recording surface of the cut sheet P. An outer circumferential surface of the remover roller 20 has such a tackiness that when the outer circumferential surface of the remover roller 20 contacts the recording surface of the cut sheet P on the downward-facing surface of the feeding surface of the intermediate feeder belt 17a, the foreign matter, such as paper dust, on the recording surface is moved away from the cut sheet P onto the remover roller 20. More specifically, the tackiness of the outer circumferential surface of the remover roller 20 is set at a sufficiently small value with respect to the tackiness of the feeding surface of the intermediate feeder belt 17a, such that contact between the remover roller 20 and the cut sheet P does not cause detachment of the cut sheet P from the intermediate feeder belt 17a. However, this does not necessarily mean that the tackiness of the outer circumferential surface of the remover roller 20 per unit area is smaller than that of the feeding surface of the intermediate feeder belt 17a. For instance, the tackiness per unit area may be equal between the outer circumferential surface of the remover roller 20 and the feeding surface of the intermediate feeder belt 17a. That is, an area at which the intermediate feeder belt 17a contacts the cut sheet P is relatively wide whereas the remover roller 20 contacts the cut sheet P at a partial cylindrical surface which is relatively narrow, and equality in tackiness per unit area between the outer circumferential surface of the remover roller 20 and the feeding surface of the intermediate feeder belt 17a does not result in detachment of the cut sheet P from the feeding surface of the intermediate feeder belt 17a. However, where the tackiness of the outer circumferential surface of the remover roller 20 per unit area is smaller than that of the feeding surface of the intermediate feeder belt 17a, detachment of the cut sheet P from the intermediate feeder belt 17a is inhibited with more reliability.
In place of the remover roller 20, other kinds of removers may be employed. For instance, an antistatic brush or an antistatic blower for eliminating static electricity may be employed in place of the remover roller 20.
The removing area B is located under an “opposingly-feeding surface” in the feeding surface of the primary feeder belt 8. The opposingly-feeding surface includes or encompasses the recording area A, and extends along the feed path of the cut sheet P. The opposingly-feeding surface is a planar surface having a greatest area among all the planar surfaces included in the feeding surfaces of the primary feeder belt 8 and the intermediate feeder belt 17a. As
As described above, the cut sheet P is fed out by the pickup roller 11b, leftward as seen in
As illustrated above, in the present embodiment the removing area B is disposed under the primary feeder belt 8 and within the area corresponding to the primary feeder belt 8 as seen in the vertical direction. Hence, the foreign matter, which has scattered from the recording surface of the cut sheet P upon the removal of the foreign matter from the recording surface and wafts, is inhibited from entering a clearance between the primary feeder belt 8 and the ink ejection surfaces 2a. Therefore, the wafting foreign matter is reliably inhibited from landing on the ink ejection surfaces 2a.
Since the whole remover roller 20 is disposed within the area corresponding to the primary feeder belt 8 as seen in the vertical direction, the inkjet printer 101 can be downsized.
The recording surface of the cut sheet P does not once face vertically upward at the segment between the removing area B and the primary feeder belt 8, that is, after the cut sheet P has passed the removing area B and before the cut sheet P is placed on the primary feeder belt 8. Thus, the foreign matter, e.g., paper dust, that has been once removed does not tend to land back on the cut sheet P. Hence, landing of foreign matter on the ink ejection surfaces 2a via the cut sheet P is reliably inhibited.
Since the inkjet heads 1 and the portion of the primary feeder belt 8 corresponding to the recording area A are covered by the recoding-area cover 3, landing of foreign matter on the ink ejection surfaces 2a is further reliably inhibited.
Since the remover roller 20 and the part of the intermediate feeder belt 17a corresponding to the removing area B are covered by the removing-area cover 21, the foreign matter departing from the recording surface of the cut sheet P is prevented from scattering around.
Although in the above-described embodiment, the feed path in the inkjet printer 101 along which the cut sheet P is fed is S-shaped in side view, the feed path may have other shapes. For instance, the feed path may be U-shaped. Hereinafter, there will be described an inkjet printer 201 according to a second embodiment of the invention, in which the feed path is U-shaped, by referring to
In the second embodiment, the intermediate feeder belt 17a used in the first embodiment is omitted, and a cut sheet P as turned over or turned 180-degree by a turnover guide plate 216b is made to pressure-sensitively adhere to a downward-facing surface 208a of a feeder belt 208.
In the first embodiment, the cut sheet P is guided and turned over by a pair of guide plates 16b, namely, an outer guide plate and an inner guide plate. In the second embodiment, on the other hand, the inner guide plate 16b is omitted and a guide roller 216a having a relatively large diameter is employed, and the cut sheet P is guided by an outer circumferential surface of the guide roller 216a and the guide plate 216b.
Further, a dust tray 218 is disposed between the downward-facing surface 208a of the feeder belt 208 and the sheet holder 11a. More specifically, the dust tray 218 is disposed above a topmost one of a stack of cut sheets P accommodated in the sheet holder 11a, with a clearance between the dust tray 218 and the topmost cut sheet P. The dust tray 218 has such a size as to cover almost an entire upper surface of the topmost cut sheet P. Hence, dust wafting inside the inkjet printer 201 is effectively prevented from accumulating on the upper surface of the topmost cut sheet P.
The other parts of the second embodiment are identical with the first embodiment and description thereof is omitted.
Although two presently preferred embodiments of the invention have been described above, the invention is not limited to details thereof, but may be otherwise embodied with various modifications which do not depart from the scope and spirit of the invention as defined in the appended claims.
For instance, although in each of the above-described embodiments the whole remover (namely, remover roller 20) is disposed within the area corresponding to the primary feeder belt 8, or the feeder belt 208, as seen in the vertical direction. However, at least a part of the remover may be outside the area corresponding to the primary feeder belt 8 or the feeder belt 208 as seen in the vertical direction.
In the first embodiment, the feed path along which the cut sheet P is fed is constructed such that the recording surface of the cut sheet P does not once face vertically upward at the segment of the feed path between the removing area B and the primary feeder belt 8. Similarly, in the second embodiment, the feed path is constructed such that the recording surface does not once face vertically upward at a segment of the feed path between the removing area B and the opposingly-feeding surface 8b of the feeder belt 208. However, the feed paths may be constructed such that the recording surface of the cut sheet P faces vertically upward somewhere in these segments.
In each of the above-described embodiments, the recording-area cover 3 covers only the inkjet heads 1 and a part of the primary feeder belt 8, or the feeder belt 208, which part includes the portion corresponding to the recording area A. However, the recording-area cover 3 may further cover a surface of the primary feeder belt 8 or the feeder belt 208 which surface includes the recording area A, and also another area over the surface. Alternatively, the recording-area cover 3 may be omitted.
In each of the above-described embodiments, the removing-area cover 21 covers only the remover roller 20 and a part of the intermediate feeder belt 17a, or the feeder belt 208, which part includes the portion corresponding to the removing area B. However, in the first embodiment, the removing-area cover 21 may further cover another area of the feeding surfaces except the opposingly-feeding surface in the primary feeder belt 8 which surface includes the recording area A. For instance, the removing-area cover 21 may cover substantially the whole intermediate feeder belt 17a. Similarly, in the second embodiment, the removing-area cover 21 may further cover another area of the feeder belt 208 except the opposingly-feeding surface including the recording area A. Alternatively, the removing-area cover 21 may be omitted in each of the above-described embodiments.
In each of the above-described embodiments, the endless belt 17a, 8, 208 constructs a part of the feed path of the cut sheet P. However, in place of the endless belt, rollers or guide plates may be employed to construct the feed path.
As in the above-described embodiments, the cut sheet P as a recording medium can be easily held on the outer circumferential surface or feeding surface of each feeder belt 17a, 8, 208, when the feeding surface has a tackiness. However, the way in which the cut sheet P is held on the feeding surface is not limited thereto. For instance, it may be arranged such that the feeder belt 17a, 8, 208 is formed of a material having an air permeability, and the air is sucked through the feeder belt 17a, 8, 208 from the inner circumferential side of the belt 17a, 8, 208 in order to hold the cut sheet P on the feeding surface.
Although each of the above-described inkjet printers 101, 201 is a line printer, the invention is applicable to other types of inkjet printers, such as serial printer.
Number | Date | Country | Kind |
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2006-207833 | Jul 2006 | JP | national |
2006-208692 | Jul 2006 | JP | national |
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