This application claims priority from Japanese Patent Application No. 2010-278870, which was filed on Dec. 15, 2010, the disclosure of which is herein incorporated by reference in its entirety.
1. Field of the Invention
The present invention relates to: a recording apparatus which conducts recording using a liquid curable by irradiation of ultraviolet light; and a controller used in the recording apparatus.
2. Description of Related Art
There has been known a recording apparatus which conducts recording using a liquid curable by irradiation of ultraviolet (UV) light, such as UV curable ink. The recording apparatus may have: a head which ejects, to a recording medium, the liquid curable by irradiation of ultraviolet light; and a UV irradiator such as a light source which applies ultraviolet light to the recording medium, for example. The UV irradiator is positioned downstream of the head in a conveyance direction of the recording medium.
Meanwhile, as maintenance for the head, there has been known wiping, an operation in which foreign matter such as ink or paper dust attached to an ejection surface of the head is wiped out using a wiper, which is constituted of an elastic member and the like and is moved relatively to the ejection surface while contacting the ejection surface.
However, there may arise a problem that liquid attached to the wiper is cured, by ultraviolet light applied from the UV irradiator, thereby causing a decrease in wiping performance.
One idea to deal with this problem is to turn off the UV irradiator for a while i.e., to stop irradiation of ultraviolet light, in order to prevent ultraviolet light from being applied to the wiper. However, if the UV irradiator is turned off during the wiping and then is turned on for resuming a recording operation, some period of time is needed, before an intensity of ultraviolet light is stabilized, and this causes a loss of time.
An object of the present invention is to provide a recording apparatus and a controller each of which makes it possible to prevent liquid attached to the wiper from being cured, without turning off the UV irradiator during the wiping.
According to a first aspect of the present invention, provided is a recording apparatus comprising a conveyor, a head, a UV irradiator, a wiper, a first shading member, a first controller, and a second controller. The conveyor conveys a recording medium in a conveyance direction. The head includes an ejection surface at which a plurality of ejection openings are formed from which openings liquid curable by irradiation of ultraviolet light is ejected to the recording medium. The UV irradiator is positioned downstream of the head in the conveyance direction and applies ultraviolet light to the recording medium. The wiper is movable relatively to the ejection surface while contacting the ejection surface and performs wiping in which foreign matter attached to the ejection surface is wiped out. The first shading member is movable in a cross direction crossing the ejection surface, and shades an opposed space being opposed to the ejection surface from ultraviolet light applied by the UV irradiator in a state where the first shading member is taking a protruding position, in the protruding position the first shading member protruding from the ejection surface in the cross direction. The first controller controls the first shading member to take the protruding position. The second controller controls the wiper to move relatively to the ejection surface while causing the wiper to contact the ejection surface in a state where the wiper is positioned in the opposed space and the first shading member is taking the protruding position, when the wiping is performed.
According to a second aspect of the present invention, provided is a controller which is used in a recording apparatus. The recording apparatus includes: a conveyor which conveys a recording medium in a conveyance direction; a head including an ejection surface at which a plurality of ejection openings are formed from which openings liquid curable by irradiation of ultraviolet light is ejected, to the recording medium; a UV irradiator which is positioned downstream of the head in the conveyance direction and applies ultraviolet light to the recording medium; a wiper which is movable relatively to the ejection surface while contacting the ejection surface and performs wiping in which foreign matter attached to the ejection surface is wiped out; and a first shading member which is movable in a cross direction crossing the ejection surface, and shades an opposed space being opposed to the ejection surface from ultraviolet light applied by the UV irradiator in a state where the first shading member is taking a protruding position, in the protruding position the first shading member protruding from the ejection surface in the cross direction. The controller comprises: a first controller which controls the first shading member to take the protruding position; and a second controller which controls the wiper to move relatively to the ejection surface while causing the wiper to contact the ejection surface in a state where the wiper is positioned in the opposed space and the first shading member is taking the protruding position, when the wiping is performed.
Other and farther objects, features and advantages of the invention will appear more fully from the following description taken in connection with the accompanying drawings in which:
The following describes preferred embodiments of the present invention, with reference to the drawings.
First, with reference to
The printer 1 has a housing 1a of a rectangular parallelepiped shape. A discharged paper receiver 31 is provided on a top panel of the housing 1a. An internal space of the housing 1a is capable of being divided into spaces A, B, and C, from the top to the bottom. In the space B, a paper feed unit 1b is disposed. A sheet conveyance path from the paper feed unit 1b to the discharged paper receiver 31 is formed in the spaces A and B.
In the space A, there are disposed: a sheet sensor 32; four heads 10; four UV irradiators 60; a conveyor; guides 29 which guide a sheet P; a controller 1p; and the like. The conveyor is constituted by: four platens 7 disposed so as to be opposed to the four heads 10 respectively; and pairs of feed rollers 22 to 27 disposed along the sheet conveyance path, and the conveyor conveys a sheet P in a conveyance direction indicated with bold, arrows in
Each head 10 is a line-type ink-jet head which extends in a main scanning direction and has a substantially rectangular parallelepiped shape. At the time of recording, magenta, cyan, yellow, and black UV curable inks which are curable by irradiation of ultraviolet light are respectively ejected from under surfaces, i.e., ejection surfaces 10a, of the four heads 10. In the vicinity of a lower end of each head 10, there is provided an annular cap 40 which surrounds an outer circumference of its ejection surface 10a. Further, a wiper unit 70 and a shading plate 80 (see
The UV irradiators 60 are respectively provided for the heads 10, and each of the UV irradiators 60 is disposed downstream of the corresponding head 10 in a direction along which a sheet P is conveyed by the conveyor. This direction is indicated with the bold arrows in
The heads 10 and the UV irradiators 60 are aligned in a sub scanning direction at predetermined intervals, and are supported by the housing 1a via a not-shown frame.
The paper feed unit 1b has a paper feed tray 20 and a paper feed roller 21. Of these, the paper feed tray 20 is removable from the housing 1a. The paper feed tray 20 is a box having an open top, and is capable of containing different sizes of sheets P. The paper feed roller 21 forwards an uppermost sheet P of the sheets P contained in the paper feed tray 20.
The controller 1p controls an operation of each unit of the printer 1, and thereby controlling an overall operation of the printer 1. Based on image data supplied from an external device such as a PC connected to the printer 1, the controller 1p controls the following operations of: preparation related to recording; feed, conveyance, and discharge of a sheet P; ejection of ink and irradiation of ultraviolet light in synchronization with the conveyance of the sheet P; and the like, so that an image is formed on the sheet P. Further, the controller 1p controls a later-described maintenance operation related to recovery and maintenance of ejection performance of the heads 10.
Based on a recording command received from the external device, the controller 1p drives a paper feed motor 125 (see
Here, the sub scanning direction is a direction parallel to the conveyance direction, and the main scanning direction is a direction parallel to a horizontal surface and orthogonal to the sub scanning direction.
In the space C, a cartridge unit 1c is disposed removably from the housing 1a. The cartridge unit 1c has a tray 35, and four cartridges 39 placed side-by-side with one another in the tray 35. The cartridges 39 communicate with the heads 10 via not-shown tubes, respectively, and each of the cartridges 39 reserves UV curable ink of a color corresponding to the associated head 10. The ink reserved in each cartridge 39 is supplied to the associated head 10, where necessary.
Next, a structure of each head 10 will be described in more detail, with reference to
As shown in
As shown in
The reservoir unit 11 is a stack constituted of four metal plates 11a to 11d attached to one another, in each of which plates a through hole and/or a recess is/are formed. Protrusions are formed on a surface of the plate 11d. An ink passage including a reservoir 72 is formed inside the reservoir unit 11. One end of the ink passage is connected to the corresponding cartridge 39 via the tube or the like, while the other end of the passage is connected to openings provided at an under surface of the reservoir unit 11. In the plate 11d, there are formed ink outflow passages 73 communicating with the reservoir 72. One end of each of the ink outflow passages 73 is connected to an opening provided at an end surface of the corresponding protrusion of the plate 11d, which surface is bonded to the upper surface 12x.
The passage unit 12 is a stack constituted of nine quadrangular metal plates 12a, 12b, 12c, 12d, 12e, 12f, 12g, 12h, and 12i (see
As shown in
As shown in
The FPCs 50 are respectively provided for the actuator units 17, and each of the FPCs 50 has wires associated with the electrodes of the corresponding actuator unit 17. These wires are respectively connected to output terminals of the corresponding driver IC 57. Under the control of the controller 1p (see
Next, with reference to
The maintenance operation includes: preliminary ejection such as purging or flushing; wiping; capping; and the like. Here, the purging is an operation in which ink is discharged from ail the ejection openings 14a (see
Each of the caps 40 is made of a lightproof elastic material such as rubber, and has an annular shape which surrounds an entire outer circumference of the corresponding ejection surface 10a, in a plan view, A sponge 40S capable of retaining ink is provided on an inner surface of the each cap 40 along its entire circumference. The sponge 40S is interposed between the inner surface of the cap 40 and side surfaces of the corresponding passage unit 12. The sponge 40S extends, inside the cap 40, from an upper end of the cap 40 to a position in the vicinity of a lower end 40a.
Each cap 40 is movable upward and downward, by driving a corresponding gear 40G (see
As shown in
As shown in
Each wiper 71 is a plate-like member made of an elastic material such as rubber and extends in the sub scanning direction and the vertical direction. With respect to the sub scanning direction, a length (width) of each wiper 71 is slightly longer than a length (width) of the corresponding ejection surface 10a. A lower end of each wiper 71 is fixed to its holder 71h.
As shown in
Each case 78 is a rectangular parallelepiped, box, and an opening 78x is formed through its top wall 78t. A thin-film cover 79 which covers the opening 78x is attached to a top surface of the top wall 78t. The cover 79 has a through hole 79x in a form of a slit. The through hole 79x has a width larger than a thickness of the corresponding wiper 71, and has a length longer than the length of the wiper 71 with respect to the sub scanning direction (see
Inside each case 78, there are provided, a pair of plates 77 which sandwich the corresponding holder 71h from both sides in the main scanning direction. The holder 71h is moved upward and downward while being guided by the pair of plates 77. A spring 71S is disposed between the pair of plates 77, and between the holder 71h and the ease 78. The spring 71S urges the holder 71h upward.
Slits 77s and 78s are formed in one of the pair of plates 77 and a side wall of the case 78, respectively. A rod 71p protruding from a side surface of the holder 71h in the main scanning direction is inserted through these slits 77s and 78s, and is connected to a drive shaft of the corresponding solenoid 75. Therefore, as the drive shaft of the solenoid 75 extends and contracts, the rod 71p is moved upward and downward within the slits 77s and 78s, and the holder 71h and the wiper 71 are moved upward and downward.
Each sponge 70S is provided in the vicinity of a bottom of the corresponding case 78 in a space within the case 78, except a space between the pair of plates 77.
As shown in
When the corresponding platen 7 is in the non-opposed position depicted with the alternate long and two short dashes lines in
The following describes an electrical structure of the printer 1, with reference to
As shown in
The controller 1p is connected to: each of the motors 125 and 127; the sheet sensor 32; the control substrates of the heads 10; the UV irradiators 60, and the like. Further, the controller 1p is connected to: platen pivot motors 7M which pivot the respective platens 7; cap drive motors 40M which drive the respective gears 40G (see
The following describes control processing of a wiping operation executed by the controller 1p, with reference to
As shown in
On receiving the wiping command (S1: YES), the controller 1p drives each platen pivot motor 7M, to withdraw the corresponding platen 7, that is, to move the corresponding platen 7 from the opposed position to the non-opposed position (S2). At this time, the end portion of the L-shaped portion 7p of each platen 7 is in the upright posture, and the inner wall surface of the L-shaped portion 7p is opposed to the side wail of the corresponding cap 40, which side wall located downstream in the conveyance direction, and is opposed to the lower end 40a of the cap 40. On the other hand, the flat portion of each platen 7 is hanged, downward. As a result, each platen 7 shades the corresponding opposed space V1 from ultraviolet light applied by the UV irradiator 60 located downstream of the corresponding head 10 in the conveyance direction.
After the S2, the controller 1p drives each cap drive motor 40M, to move the corresponding cap 40 downward from the withdrawal position to the second, protruding position (S3). At this time, as shown in
After the S3, the controller 1p drives each wiper unit drive motor 70M, to move the corresponding wiper unit 70 together with its case 78, from the standby space V3, via the intermediate space V4, to the opposed, space V1, along the main scanning direction (S4). Note that, in the standby space V3, the wiper unit 70 is positioned below the lower end 40a of the corresponding cap 40 which is in the second protruding position. Therefore, when the wiper unit 70 is moved below the cap 40 in the S4, no collision occurs between the wiper unit 70 and the cap 40. The controller 1p stops the movement of each wiper unit 70 along the main scanning direction when the wiper unit 70 reaches an end of the corresponding opposed space V1, which end is farther from the standby space V3 with respect to the main scanning direction, i.e., a right end of the opposed space V1 in
After the S4, the controller 1p drives each solenoid 75, to move the corresponding wiper 71 from the housed position to the exposed position (S5). Note that, at this moment, the wiper 71 has not contacted the corresponding ejection surface 10a yet.
After the S5, the controller 1p drives each wiper unit drive motor 70M, to move the corresponding wiper unit 70 together with its case 78 slightly upward to a position where each wiper 71 contacts the corresponding ejection surface 10a while being warped. Further, the controller 1p drives each wiper unit drive motor 70M, to move the corresponding wiper unit 70 together with its case 78 toward its standby space V3 within its opposed space V1 along the main scanning direction, and thereby performs the wiping (S6). Ultraviolet light does not reach an area where each wiper 71 is moved during this operation. At this time, the upper end portion of each wiper 71 is moved relatively to the corresponding ejection surface 10a, while contacting the ejection surface 10a. As a result, foreign matter attached to the ejection surface 10a is wiped out. The controller 1p stops the movement of each wiper unit 70 along the main scanning direction when the wiper unit 70 reaches an other end of the corresponding opposed space V1, which end is closer to the standby space V3 with respect to the main scanning direction, i.e., a left end of the opposed, space V1 in
Note that, depending on a manner of the downward movement, there is a possibility that, when the wiper 71 is separated from the ejection surface 10a, elasticity of the wiper 71 rapidly returns the wiper 71 into a state where the wiper 71 has not yet contacted, the ejection surface 10a, with the result that ink attached to the wiper 71 is spattered in the housing 1a. Therefore, the sponge 40S is provided inside each cap 40 in this embodiment. This allows the ink attached to each wiper 71 to be absorbed by the sponge 40S, and minimizes problems such as above-described spattering of ink.
Before and after the wiping of the S6, that is, when each wiper 71 is in the exposed position and does not contact the corresponding ejection surface 10a, each wiper 71 is at a substantially central position in the corresponding through hole 79x (see
During the wiping of the S6, the wiper 71 contacts the ejection surface 10a and is warped, and the back surface 71w2 contacts the cover 79. At this time, the width x2 is approximately equal to zero, while the width x1 is larger than the width x1 observed before and after the wiping (see
After the S6, the controller 1p drives each solenoid 75, to move the corresponding wiper 71 from the exposed position to the housed position (S7).
After the S7, the controller 1p drives each wiper unit drive motor 70M, to move the corresponding wiper unit 70 together with its case 78 downward to a position where the case 78 does not overlap the corresponding cap 40 with respect to the vertical direction. The controller 1p further drives each wiper unit drive motor 70M, to move the corresponding wiper unit 70 together with its case 78, from the opposed space V1 via the intermediate space V4 to the standby space V3, along the main scanning direction (S8). The controller 1p stops the movement of each wiper unit 70 along the main scanning direction when each wiper unit 70 reaches the standby space V3.
After the S8, the controller 1p drives each cap drive motor 40M to move the corresponding cap 40 upward, from the second, protruding position to the withdrawal position (S9).
After the S9, the controller 1p drives each platen pivot motor 7M, to return the corresponding platen 7, that is, to move the corresponding platen 7 from the non-opposed position to the opposed position (S10). With this, the wiping operation is completed.
As described above, according to the printer 1 and the controller 1p of this embodiment, each opposed space V1 is shaded by the corresponding cap 40 which is in the second protruding position from ultraviolet light applied, by the UV irradiators 60, as shown in
The caps 40 are used not only for shading but also for capping (see
The platens 7 are used for the capping. This eliminates the necessity to provide another member for the capping, leading to a simplification of the structure of the apparatus. In addition, this realizes a speedy shift from the recording operation to the capping.
Each platen 7 is pivotable. This realizes: an easy shift from the opposed position to the non-opposed position; and an easy shift from the non-opposed position to the opposed position. Further, this leads to space conservation.
There are provided the shading sheets 7b, each of which is interposed between the corresponding cap 40 and platen 7 when the cap 40 is positioned in the second protruding position and the platen 7 is positioned in the non-opposed position. The shading sheet 7b prevents ultraviolet light applied, by the corresponding UV irradiator 60 from entering into the corresponding opposed, space V1 through a gap between the cap 40 and the platen 7, and this further ensures that curing of ink attached to the corresponding wiper 71 is prevented.
Since the wiping is performed, in each opposed space V1, there may be a case where the wiper 71 contacts the inner surface of the corresponding cap 40, which surface defines the opposed space V1, or a case where ink having been wiped out during the wiping is spattered to be attached to the inner surface. Such cases provide a possibility that the ink attached to the surface drops and is attached to the platen 7, a sheet P, or another member inside the housing 1a. The sponge 40S is provided on the inner surface of each cap 40 in this embodiment, and therefore occurrence of the above-described problem is decreased.
Each wiper 71 is shaded from ultraviolet light applied by the UV irradiators 60, by the corresponding cap 40 during the wiping, and by its wiper case 78 and the corresponding shading plate 80 when the wiper 71 is positioned in the standby space V3 or in the intermediate space V4. That is, each wiper 71 is always shaded from ultraviolet light applied, by the UV irradiators 60, not only during the wiping. Accordingly, it is possible to prevent ink attached to the wipers 71 from being cured, without switching the UV irradiators 60 between on and off.
Moreover, the wipers 71 are shaded from ultraviolet light using a relatively simple structure, i.e., by the wiper cases 78 and the shading plates 80.
Each wiper case 78 has the cover 79, and each wiper 71 passes through the through hole 79x of the corresponding cover 79 to be exposed. As shown in
Since the sponge 70S is provided in each wiper case 78, ink which has been wiped out during the wiping and has entered into each wiper case 78 is retained, by the sponge 70S.
The following describes an ink-jet printer which is a second embodiment of the recording apparatus of the present invention, with reference to
Each of platens 207 of this embodiment is movable in the sub scanning direction, and this movement allows each platen 207 to selectively take: an opposed position where the platen 207 is opposed to a corresponding ejection surface 10a in the vertical direction, as depicted with a solid line in
The following describes an ink-jet printer which is a third embodiment of the recording apparatus of the present invention, with reference to
Each of caps 340 of this embodiment corresponds to each cap 40 of the first embodiment, but does not have a side wall which is near a corresponding standby space V3. That is, each cap 340 has an approximate U-shape in a plan view. In this case, it is possible to limit the movement direction of each wiper unit 70 for the wiping, to the main scanning direction. That is, in the first embodiment, since the above-described side wall is provided, control operation is performed so as to avoid a collision between each cap 40 and the corresponding wiper unit 70. Specifically, as shown in
Note that, in addition to the caps 340, it is preferable to provide other caps so that the respective opposed spaces V1 are entirely covered by them in cooperation with the corresponding caps 340 and thereby the opposed spaces V1 are separated from the external space. This realizes preferable capping.
The following describes an ink-jet printer which is a fourth embodiment of the recording apparatus of the present invention, with reference to
Each of the platens of this embodiment is constituted by: a partial platen 407a located upstream in the conveyance direction; and a partial platen 407b located, downstream in the conveyance direction. Each of the partial platens 407a and 407b has a flat portion and an L-shaped portion 7p, and has a pivot axis 7x extending in the main scanning direction at a connection between the flat portion and the L-shaped portion 7p. Pivoting movement about the pivot axis 7x allows each partial platen 407a, 407b to selectively take: an opposed position where its flat portion is held, horizontally with respect to the vertical direction and opposed to a corresponding ejection surface 10a in the vertical direction, as depicted with solid lines in
The partial platens 407a and 407b are symmetrical with respect to a vertical line passing through a center, in the sub scanning direction, of a corresponding head 10, when viewed from the main scanning direction. In the partial platen 407a, its pivot axis 7x is located, at an end of its flat portion, which end is located upstream in the conveyance direction. In the partial platen 407b, its pivot axis 7x is located, an end of its flat portion, which end is located downstream in the conveyance direction. As depicted with the solid lines in
The structure of the platens of this embodiment is preferably employed particularly in the case where each cap 40 acting as the first shading member is in the same position during the wiping and during the capping.
In each of the second, third, and fourth embodiments, the structures same as those of the first embodiment bring about advantageous effects same as those of the first embodiment.
The conveyor does not have to be constituted of the platens and the pairs of feed rollers, but may be constituted, of a pair of rollers positioned apart from each other and an endless conveyor belt looped around, the rollers, for example.
The first shading member may be in the same position during the wiping and during the capping. To be more specific, in the first embodiment, the position of each cap 40 acting as the first shading member during the wiping is different from the position during the capping. That is, the position during the capping is the first protruding position, while the position during the wiping is the second protruding position. However, the position during the wiping and the position during the capping may be the same, for example, the first protruding position.
The first shading member does not limited, to the annular caps 40 or the caps 340 each having the approximate U-shape in a plan view, but may be plates like the shading plates 80. For example, the first shading member may be plates provided to sides of each head 10, which sides are opposed to the UV irradiators 60. In this case, the plates may be disposed so that the plates sandwich each head 10 from both sides in the conveyance direction.
The first shading member does not have to be used for the capping. Further, a medium support member such as a platen does not have to be used for the capping.
The timing at which the first shading member is positioned in the protruding position may be before or after the wiper is positioned in the opposed space. To be more specific, in the first embodiment, after each cap 40 is positioned in the protruding position, each wiper 71 is positioned in the corresponding opposed space V1. That is, the timing at which the first shading member is positioned in the protruding position is before the wiper is positioned in the opposed space. However, the present invention is not limited thereto, and for example, each cap 40 may be positioned in the protruding position after each wiper 71 is positioned in the opposed space V1. That is, the timing at which the first shading member is positioned in the protruding position may be after the wiper is positioned in the opposed space.
The shading sheets 7b, the sponges 40S, or the like may be omitted, if appropriate.
The wiper may be non-movable relatively to the wiper case. The holding member such as the sponges 70S does not have to be provided in the wiper case. The cover of the wiper case may be attached so that the cover is slightly movable relatively to the wiper case in a movement direction where the wiper moves relative to the ejection surface. In this case, the wiper warped during the wiping moves the cover slightly since the cover is pushed by the back surface of the wiper, which is the opposite surface of the wiper from the wipe surface, and as a result, a gap is reserved between the wipe surface and a portion of the cover which defines the through hole and is opposed to the wipe surface in the movement direction. Then, when the wiping is completed and the wiper is separated from the ejection surface and is returned from a warped state, a size of the gap in the movement direction may become smaller than that during the wiping.
Both of the wiper eases 78 and the shading plates 80 are used as the shading unit in the first embodiment; however, either of them may be used as the shading unit. For example, the wiper eases 78 may be omitted, and only the shading plates 80 may be used for shading the wipers 71 from ultraviolet light applied by the UV irradiators 60, with respect to spaces from the standby spaces V3 to the opposed spaces V1. Alternatively, the shading plates 80 may be omitted, and only the wiper cases 78 may be used for shading the wipers 71 from ultraviolet light applied by the UV irradiators 60, with respect to spaces from the standby spaces V3 to the opposed spaces V1.
The recording apparatus may include an arbitrary number of heads. When the recording apparatus includes a plurality of heads, the UV irradiator does not have to be provided downstream of each of the heads in the conveyance direction, as long as the UV irradiator is provided downstream of at least one of the heads in the conveyance direction. Further, the first shading member does not have to be provided for every head, as long as it is provided for at least one of the heads. To be more specific, in the first embodiment, the UV irradiators 60 are respectively provided, for the four heads 10; however, another arrangement is also possible, for example, only one UV irradiator 60 may be provided downstream, in the conveyance direction, of a most downstream head 10 in the conveyance direction, i.e., the rightmost head 10 in
The head may eject any liquid other than ink as long as the liquid is curable by irradiation of ultraviolet light. For example, the head, is not limited to a recording head which ejects recording liquid directly contributing to image formation, but may be a head which ejects treatment liquid having a function of preventing bleed of the recording liquid on a recording-medium, or the like.
The platen is constituted by one member in the first embodiment, and is constituted by two members in the fourth embodiment; however, the platen may be constituted by three or more members, and various other alterations thereto are possible.
The present invention is applicable to both of a line-type apparatus and a serial-type apparatus. In addition, the present invention is applicable not only to a printer, but also to another recording apparatus such as a facsimile machine, a copy machine, or the like.
The recording medium is not limited to a sheet, but may be various media on which recording is possible.
The present invention brings about an advantageous effect that it is possible to prevent liquid attached to the wiper from being cured without turning off the UV irradiator during the wiping. However, the UV irradiator may be turned, off during the wiping, or the UV irradiator may be switched between on and off.
While this invention has been described in conjunction with the specific embodiments outlined above, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the preferred, embodiments of the invention as set forth above are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the invention as defined in the following claims.
Number | Date | Country | Kind |
---|---|---|---|
2010-278870 | Dec 2010 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
20030184631 | Suzuki et al. | Oct 2003 | A1 |
20050190248 | Konno et al. | Sep 2005 | A1 |
20070146415 | Jung et al. | Jun 2007 | A1 |
20080074484 | Sugahara | Mar 2008 | A1 |
20080204536 | Suzuki | Aug 2008 | A1 |
20080278537 | Watanabe | Nov 2008 | A1 |
20110242204 | Shinoda | Oct 2011 | A1 |
Number | Date | Country |
---|---|---|
H09-085959 | Mar 1997 | JP |
H11-291511 | Oct 1999 | JP |
2003-103793 | Apr 2003 | JP |
2004-314478 | Nov 2004 | JP |
2005-280346 | Oct 2005 | JP |
2006-116907 | May 2006 | JP |
2006-205517 | Aug 2006 | JP |
2007-253391 | Oct 2007 | JP |
2007-253592 | Oct 2007 | JP |
Entry |
---|
Japan Patent Office, Notice of Reasons for Rejection for Japanese Patent Application No. 2010-278870 (counterpart to above-captioned patent application), mailed Nov. 19, 2013. |
Number | Date | Country | |
---|---|---|---|
20120154485 A1 | Jun 2012 | US |