The present application claims priority from Japanese Patent Application No. 2009-045832, filed on Feb. 27, 2009, the disclosure of which is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention relates to a processing liquid applying apparatus which applies a processing liquid to a surface of a processing liquid transfer roller and transfers the processing liquid to a transfer medium (for example, printing paper and recording sheet), and an image-forming apparatus provided with the processing liquid applying apparatus.
2. Description of the Related Art
For example, in an image-forming apparatus (for example, printer and facsimile) based on the “ink-jet system”, the inks, which are discharged from the nozzles, are adhered or deposited onto the surface of the printing paper. In this situation, the inks are not preferably deposited onto the printing paper depending on the type of the inks or the printing paper, and the image is blurred and/or the color development is deteriorated in some cases. Accordingly, in the case of a conventional technique, as disclosed in Japanese Patent Application Laid-open No. 2006-346534 (FIG. 12), the blurring of the image is avoided, and the deterioration of the color development performance is avoided by previously applying a processing liquid to the surface of the printing paper.
A liquid applying apparatus disclosed in Japanese Patent Application Laid-open No. 2006-346534 includes an applying roller which applies a processing liquid to a sheet member while rotating in a predetermined direction, and a liquid applying section which applies the processing liquid to the surface of the applying roller. The liquid applying section includes a space-forming member which forms a hermetically closed space with respect to the applying roller, an annular abutting member which seals the circumferential edge portion of the hermetically closed space, and a pressing member (spring) which supports the space-forming member and the abutting member and which presses them toward the applying roller. The processing liquid is supplied into the hermetically closed space, the applying roller is rotated, and thus the processing liquid is applied to the surface of the applying roller which constitutes a part of the hermetically closed space.
According to the conventional technique described above, a mechanism, which applies the processing liquid to the surface of the applying roller, can be easily constructed. However, the space-forming member and the abutting member are merely supported by the pressing member (spring). Therefore, the spacing distance between the abutting member and the applying roller cannot be maintained to be constant and/or the spacing distance cannot be appropriately changed. It is impossible to optionally and preferably adjust the applying amount of the processing liquid with respect to the applying roller.
For example, when the applying amount of the processing liquid is excessively increased in the “transfer mode” in which the processing liquid is transferred from the applying roller to the sheet member, it is feared that a long period of time may be required to dry the processing liquid transferred to the sheet member and/or the processing liquid, which remains on the surface of the applying roller, may inhibit the next transfer process. Therefore, it is necessary that the applying amount of the processing liquid should be stabilized to an appropriate amount. In the case of the conventional technique described above, the abutting member is moved in the tangential direction of the applying roller in accordance with the rotation of the applying roller, and the spacing distance, which is provided between the applying roller and the portion of the abutting member positioned on the downstream side in the direction of rotation of the applying roller, is undesirably widened. Therefore, a tendency arises such that the applying amount of the processing liquid is not only stabilized, but the applying amount is also increased undesirably. On the other hand, in the “cleaning mode” in which the applying roller is cleaned, it is desirable that the applying amount of the processing liquid applied to the applying roller is “relatively large” in order to wash out the foreign matter (paper dust or the like) adhered to the applying roller. In the case of the conventional technique described above, it is impossible to appropriately change the spacing distance between the abutting member and the applying roller. Therefore, it is impossible to intentionally increase the applying amount of the processing liquid in the “cleaning mode”, and it is impossible to obtain any sufficient cleaning effect.
The present invention has been made in order to solve the problem as described above, an object of which is to provide a processing liquid applying apparatus and an image-forming apparatus provided with the processing liquid applying apparatus which make it possible to preferably adjust the applying amount of a processing liquid with respect to a processing liquid transfer roller in the “transfer mode” and the “cleaning mode” respectively.
According to a first aspect of the present invention, there is provided a processing liquid applying apparatus which applies a processing liquid to a transfer medium, including: a processing liquid transfer roller which transfers the processing liquid to the transfer medium while rotating in a predetermined direction; a processing liquid applying section which makes a contact with a surface of the processing liquid transfer roller to apply the processing liquid to the surface of the processing liquid transfer roller; a downstream wall which is positioned on a downstream side in a rotating direction of the processing liquid transfer roller with respect to a contact point at which the surface of the processing liquid transfer roller makes a contact with the processing liquid in the processing liquid applying section; and a downstream wall moving mechanism which moves the downstream wall, in a tangential direction at the contact point of the processing liquid applying section and the processing liquid transfer roller, between a downstream wall first position at which the downstream wall is positioned while the processing liquid transfer roller is transferring the processing liquid to the transfer medium and a downstream wall second position at which the downstream wall is positioned while the surface of the processing liquid transfer roller is being washed with the processing liquid, wherein a distance between the downstream wall positioned at the downstream wall second position and the processing liquid transfer roller, is greater than a distance between the downstream wall positioned at the downstream wall first position and the processing liquid transfer roller.
In this arrangement, the distance between the downstream wall and the processing liquid transfer roller, which is provided when the downstream wall is positioned at the downstream wall second position, is greater than that provided when the downstream wall is positioned at the downstream wall first position. Therefore, the applying amount of the processing liquid to be applied to the surface of the processing liquid transfer roller is increased when the downstream wall is positioned at the downstream wall second position as compared with when the downstream wall is positioned at the downstream wall first position.
The present teaching is constructed as explained above. The applying amount of the processing liquid, with which the processing liquid transfer roller is applied, can be preferably adjusted in each of the “transfer mode” and the “cleaning mode”. In other words, in the “transfer mode” in which the processing liquid is transferred to the transfer medium, the applying amount of the processing liquid with respect to the processing liquid transfer roller can be adjusted to be “relatively small”, for example, in order to quicken the drying of the processing liquid transferred to the transfer medium. On the other hand, in the “cleaning mode” in which the surface of the processing liquid transfer roller is washed, the applying amount of the processing liquid with respect to the processing liquid transfer roller can be adjusted to be “relatively large” in order to wash out the foreign matter (for example, paper dust or paper powder) adhered to the processing liquid transfer roller.
An “image-forming apparatus” according to a preferred embodiment of the present invention will be explained below with reference to the drawings. A “processing liquid applying apparatus” according to a preferred embodiment of the present invention will be referred to as a constitutive part of the “image-forming apparatus” in the description of the “image-forming apparatus”.
Overall Arrangement of Image-Forming Apparatus
An image-forming apparatus 10 includes a casing 14, a paper feed cassette 16, a liquid discharge apparatus 18, a transport apparatus 20, a processing liquid applying apparatus 22, a detecting unit 24, and a control unit 26, and a processing liquid R (
The casing 14 is a box-shaped member which accommodates the constitutive parts as described above. An opening 14a through which the paper feed cassette 16 is taken in and out and a printing paper discharge port 14b through which the printing paper 12 is discharged are formed on the side surface of the casing 14. A paper discharge tray 28, which receives the printing paper 12 discharged from the printing paper discharge port 14b, is attached under or below the printing paper discharge port 14b.
The paper feed cassette 16 is a container or vessel which collectively accommodates a plurality of sheets of the printing paper 12. A pickup roller 30 for taking out the printing paper 12 is arranged over or above the paper feed cassette 16.
The liquid discharge apparatus 18 has an ink discharge head 18a based on the “ink-jet system” having a plurality of discharge nozzles. A platen 18b, which supports the printing paper 12, is arranged at a position opposed to the plurality of discharge nozzles. The ink discharge head 18a has a driving unit (for example, an actuator) which applies the discharge pressure to the ink based on the driving signal given from the control unit 26. The ink, to which the discharge pressure is applied, is discharged from the nozzles to the printing paper 12. The recording system of the liquid discharge apparatus 18 is not limited to the “ink-jet system”. The type of the ink is not specifically limited as well. However, the “ink-jet system” is adopted in this embodiment. Therefore, in order to avoid the nozzle clog-up caused by the drying of the ink, the ink, which is obtained by mixing a water-soluble high boiling point solvent (for example, glycol) and a soluble color material with water as the main component, is used. Therefore, the fixation performance of the ink with respect to the printing paper 12 is not sufficient. In the processing liquid applying apparatus 22 described later on, a processing liquid R, which is capable of enhancing the fixing of the ink, is applied to the printing paper 12.
The transport apparatus 20 includes transport rollers 32 which feed the printing paper 12 taken out by the pickup roller 30 to the liquid discharge apparatus 18 via the detecting unit 24 and the processing liquid applying apparatus 22, holding rollers 34 which hold the printing paper 12 fed to the processing liquid applying apparatus 22, and paper discharge rollers 36 which discharge the printing paper 12 formed with the image by the liquid discharge apparatus 18 from the printing paper discharge port 14b to a paper discharge tray 28. In this embodiment, a substantially C-shaped transport route M is constructed by the transport apparatus 20.
The processing liquid applying apparatus 22 applies the processing liquid R (
The detecting unit 24 is arranged on the upstream side in the transport direction of the printing paper 12 with respect to the processing liquid applying apparatus 22. The detecting unit 24 detects the type (for example, thickness, surface smoothness, and hardness) of the printing paper 12. The detection result of the detecting unit 24 is fed to the control unit 26.
The control unit 26 include a central processing unit (CPU) which executes various types of calculation processes, and storage devices (ROM, RAM) which store various types of data and programs. The control unit 26 controls the operations of, for example, the liquid discharge apparatus 18, the transport apparatus 20, the processing liquid applying apparatus 22, and a stopper driving apparatus 96 (
Overall Arrangement of Processing Liquid Applying Apparatus
In this embodiment, the ink, which contains the water-soluble high boiling point solvent (for example, glycol) and the soluble color material, is used as described above. Therefore, it is feared that the high quality is not obtained due to, for example, the blurring of the ink, when the ink is discharged to the unprocessed or untreated printing paper 12. Accordingly, in this embodiment, the processing liquid R, which makes it possible to enhance the fixation performance of the ink, is previously applied to the printing paper 12 by using the processing liquid applying apparatus 22. The type of the processing liquid R can be appropriately changed depending on, for example, the type of the printing paper 12, the type of the ink, or the purpose of the processing. For example, a liquid containing multivalent metal salt, a cationic surfactant, or a cationic polymer material, which agglutinate or react the color material contained in the ink and which are capable of increasing density or waterproofness of the ink as well as enhancing fixing of the ink, are usable as the processing liquid R. Further, the processing liquid R may contain fine particles such as silica particles, alumina particles, or resin emulsion. In order to perform high-speed printing, a liquid containing organic solvent or surfactant which enhance permeability of the ink is usable as the processing liquid. A liquid to keep the printing paper from curling (especially, a curl occurring immediately after the printing) may be used as the processing liquid R. In order to improve the brightness or whiteness of the printing paper 12, a “liquid containing a fluorescent whitener” may be used as the processing liquid R.
As shown in
Arrangement of Processing Liquid Transfer Roller
As shown in
A rotary driving unit (not shown), which includes a motor and a gear unit, is connected to the rotary shaft 52a of the core member 52 disposed on one side. The direction of rotation of the processing liquid transfer roller 42 (hereinafter simply referred to as “rotating direction”), which is brought about by the rotary driving unit, is not specifically limited. However, in this embodiment, as shown in
Arrangement of Applying Member
As shown in
The processing liquid accommodating cap 54 is a groove-shaped member which has an opening 80 disposed on the upper surface and which applies the processing liquid R to the surface of the processing liquid transfer roller 42 under or below the processing liquid transfer roller 42. As shown in
As shown in
The cap holder 56 is a container or vessel which holds the processing liquid accommodating cap 54 under or below the processing liquid transfer roller 42 and which recovers the processing liquid R and the foreign matter Q scraped off from the processing liquid transfer roller 42. As shown in
The processing liquid accommodating cap 54 is joined (for example, adhered) to the upper surface of the bottom plate section 70 positioned on the downstream side in the rotating direction with respect to the projection 76. Through-holes 78 (
Therefore, in this embodiment, the processing liquid R accommodated in the processing liquid accommodating cap 54 corresponds to the “processing liquid applying section” which applies the processing liquid R to the surface of the processing liquid transfer roller 42. The downstream wall 60 of the processing liquid accommodating cap 54 corresponds to the “downstream wall” which is positioned on the downstream side in the rotating direction with respect to the “contact point at which the processing liquid transfer roller makes a contact with the processing liquid in the processing liquid applying section”. The upstream wall 62 of the processing liquid accommodating cap 54 corresponds to the “upstream wall” which is positioned on the upstream side in the rotating direction with respect to the “contact point at which the processing liquid transfer roller makes a contact with the processing liquid in the processing liquid applying section”. The area, which is included in the internal space of the cap holder 56 and from which the area arranged with the processing liquid accommodating cap 54 is excluded, is the processing liquid recovery section S which recovers the processing liquid R and the foreign matter Q. Further, the applying member 44 is moved in a state in which the processing liquid accommodating cap 54 is brought in contact with the surface of the processing liquid transfer roller 42. In other words, the pressing force, which is transmitted from the processing liquid transfer roller 42 to the processing liquid accommodating cap 54 by the aid of the frictional force, acts as the “motive power” for moving the applying member 44 in the tangential direction at the lowermost position in the vertical direction of the processing liquid transfer roller 42 (hereinafter simply referred to as “tangential direction”), i.e., in the transport direction X. In this way, in this embodiment, the processing liquid transfer roller 42 functions as the “power source” for the moving mechanism G (
As shown in
As described above, the opening 80, which is the “processing liquid applying section”, is arranged under or below the processing liquid transfer roller 42. The lowest point of the processing liquid transfer roller 42 is positioned within the width of the opening 80. Therefore, when the applying member 44 is moved toward the downstream side in the rotating direction in the tangential direction, the distance D between the forward end 60a on the upper side in the vertical direction of the downstream wall 60 and surface of the processing liquid transfer roller 42 (hereinafter simply referred to as “distance D between the downstream wall 60 and the processing liquid transfer roller 42) is increased. On the contrary, when the applying member 44 is moved toward the upstream side in the rotating direction in the tangential direction, the distance D between the downstream wall 60 and the processing liquid transfer roller 42 is decreased. When the applying member 44 is moved toward the downstream side in the rotating direction in the tangential direction, the contact pressure between the upstream wall 62 and the processing liquid transfer roller 42 is increased. On the contrary, when the applying member 44 is moved toward the upstream side in the rotating direction in the tangential direction, the contact pressure between the upstream wall 62 and the processing liquid transfer roller 42 is decreased.
Arrangement of Support Member
As shown in
As shown in
As shown in
The transfer mode stoppers 86 are projections which position the applying member 44 at the “transfer mode position P1”. The transfer mode stoppers 86 are moved upwardly and downwardly and they are moved in the tangential direction by the stopper driving apparatus 96 (
In this embodiment, the coil spring 92 is used as the “restoring mechanism”. However, the arrangement of the “restoring mechanism” is not specifically limited. For example, it is also allowable to use any other elastic member including, for example, plate spring, rubber, and elastomer. It is also allowable to use any driving apparatus including, for example, motor and electromagnetic solenoid. It is also allowable to use any arrangement in which the restoration is effected manually. Further, the applying member 44 may be allowed to function as the “restoring mechanism” by forming a part or all of the applying member 44 with an elastic material including, for example, rubber and elastomer. However, when the “restoring mechanism” has an urging means for urging the applying member 44 toward the upstream side in the rotating direction, it is desirable to provide such a design that the frictional force, which is generated between the processing liquid accommodating cap 54 and the processing liquid transfer roller 42, is greater than the urging force of the “restoring mechanism” to be exerted on the applying member 44 in order to move the applying member 44 to the “transfer mode position P1”.
Arrangement of Processing Liquid Supply Apparatus
As shown in
Operation of Image-Forming Apparatus
When the image is formed on the printing paper 12 by using the image-forming apparatus 10, the image signal is inputted into the control unit 26 from the external device such as a personal computer or the like. Accordingly, the control unit 26 drives the transport apparatus 20. The printing paper 12, which is accommodated in the paper feed cassette 16, is taken out by the pickup roller 30, and the printing paper 12 is fed to the processing liquid applying apparatus 22 via the detecting unit 24. The detecting unit 24 detects the type (for example, thickness, surface smoothness, and hardness) of the printing paper 12 transported through the transport route M, and the detection result is given to the control unit 26.
Transfer Mode
When the processing liquid applying apparatus 22 is operated in the “transfer mode”, the transfer mode stoppers 86 are moved upwardly by the stopper driving apparatus 96 in the state in which the applying member 44 is positioned on the upstream side in the rotating direction as compared with the through-holes 88 of the sliding section 84, and the transfer mode stoppers 86 are allowed to protrude from the upper surface of the sliding section 84. In the state in which the applying member 44 is positioned on the upstream side in the rotating direction as compared with the through-holes 88, the lengths of the coil springs 92 are in the natural state, and the urging force is not generated in the coil springs 92 which press the applying member 44 toward the upstream side in the rotating direction. Therefore, when the processing liquid transfer roller 42 is thereafter driven and rotated, the pressing force, which is directed toward the downstream side in the rotating direction in the tangential direction, is applied by the aid of the frictional force to the upstream wall 62 from the surface of the processing liquid transfer roller 42. The pressing force is greater than the urging force of the coil springs 92. Therefore, the entire applying member 44 is moved toward the downstream side in the rotating direction in the tangential direction, and the fastening surface 72a of the applying member 44 is allowed to abut against the transfer mode stoppers 86. In other words, the applying member 44 is positioned at the “transfer mode position P1” by means of the transfer mode stoppers 86.
When the applying amount of the processing liquid R is adjusted depending on the type of the printing paper 12, the stopper driving apparatus 96 is controlled by the control unit 26 which serves as the “stopper control unit” based on the detection result obtained by the detecting unit 24. The transfer mode stoppers 86 are moved in the tangential direction. In other words, the “transfer mode position P1” is positionally adjusted in the tangential direction so that the preferred applying amount is obtained depending on the type of the printing paper 12. For example, if the control unit 26 judges that “the liquid absorption performance of the printing paper 12 is high” based on the detection result obtained by the detecting unit 24, it is necessary that the applying amount of the processing liquid R with respect to the processing liquid transfer roller 42 should be increased. In this case, the transfer mode stoppers 86 are moved toward the downstream side in the rotating direction, and thus the “transfer mode position P1” is moved toward the downstream side in the rotating direction. The distance D between the downstream wall 60 and the processing liquid transfer roller 42 is increased. In the “transfer mode”, the applying member 44 is positioned by the transfer mode stoppers 86. Therefore, the distance D between the downstream wall 60 and the processing liquid transfer roller 42 is stable at a constant distance. The applying amount of the processing liquid R with respect to the surface of the processing liquid transfer roller 42 is not undesirably varied or fluctuated. In other words, the downstream wall 60 functions as the “applying amount adjusting member” which adjusts the applying amount of the processing liquid R.
The processing liquid R, which has been applied to the surface of the processing liquid transfer roller 42 from the applying member 44, is transferred to the surface of the printing paper 12 brought in contact with the surface of the processing liquid transfer roller 42. The printing paper 12, to which the processing liquid R has been transferred, is fed to the liquid discharge apparatus 18. The image is formed on the surface of the printing paper 12, and then the printing paper 12 is discharged from the printing paper discharge port 14b by means of the paper discharge rollers 36. The processing liquid R, which remains on the surface of the processing liquid transfer roller 42, is scraped off toward the outer side surface of the upstream wall 62 by means of the upstream wall 62 upon the contact with the upstream wall 62. In other words, the upstream wall 62 functions as the “cleaning member” which scrapes the foreign matter Q and the processing liquid R remained on the surface of the processing liquid applying roller 42. Also in the “transfer mode”, the foreign matter Q, which is removed by the upstream wall 62, may be washed out with the processing liquid R by feeding the processing liquid R to the upstream wall 62 without transferring the processing liquid R to the printing paper 12 in the same manner as in the “cleaning mode” described below.
Cleaning Mode
For example, when the printing operation is not performed for a long period of time, then the remaining processing liquid R is deposited on the surface of the processing liquid transfer roller 42 in some cases, and the viscosity of the remaining processing liquid R is increased, resulting in the adhesion to the surface of the processing liquid transfer roller 42 together with the foreign matter Q or the like in other cases. When the printing operation is repeatedly performed in the “transfer mode”, then the remaining processing liquid R or the foreign matter Q (hereinafter referred to as “foreign matter Q or the like”) are adhered and accumulated on the surface of the processing liquid transfer roller 42 and the outer side surface of the upstream wall 62, the foreign matter Q or the like is interposed and accumulated between the upstream wall 62 and the processing liquid transfer roller 42, and/or the foreign matter Q or the like enters the interior of the processing liquid accommodating cap 54 in some cases. If the transfer operation is continued without removing the foreign matter Q or the like in such situations, the performance of the processing liquid applying apparatus 22 is conspicuously deteriorated, because any new processing liquid R is not transferred to the portion of the surface of the processing liquid transfer roller 42 to which the foreign matter Q or the like is adhered. When any gap appears between the upstream wall 62 and the processing liquid transfer roller 42 due to the foreign matter Q or the like interposed between the upstream wall 62 and the processing liquid transfer roller 42, it is feared that the air may enter the interior of the processing liquid accommodating cap 54 due to the negative pressure for sucking the processing liquid R, and/or the processing liquid R contained in the processing liquid accommodating cap 54 may leak to the outside due to the positive pressure for supplying the processing liquid R into the processing liquid accommodating cap 54. Further, when the foreign matter Q or the like enters the interior of the processing liquid accommodating cap 54, it is feared that any “uneven application or coating” of the processing liquid R may be caused in the step of applying the processing liquid R to the surface of the processing liquid transfer roller 42.
In view of the above, in order to remove the foreign matter Q or the like, for example, from the processing liquid transfer roller 42, the user starts the “cleaning mode”, for example, by operating a mode selection switch. In the “cleaning mode”, the transfer mode stoppers 86 are moved downwardly by means of the stopper driving apparatus 96, and the transfer mode stoppers 86 are retracted downwardly from the upper surface of the sliding section 84. Therefore, when the processing liquid transfer roller 42 is driven and rotated, then the upstream wall 62 is pressed toward the downstream side in the rotating direction in the tangential direction by the surface of the processing liquid transfer roller 42, and thus the entire applying member 44 is moved toward the downstream side in the rotating direction. The fastening surface 72a of the applying member 44 is allowed to abut against the cleaning mode stoppers 90. In other words, the applying member 44 is positioned at the “cleaning mode position P2” by means of the cleaning mode stoppers 90. When the process proceeds from the cleaning mode to the transfer mode again, the rotation of the processing liquid transfer roller 42 is stopped. When the rotation of the processing liquid transfer roller 42 is stopped, the pressing force, which is exerted from the surface of the processing liquid transfer roller 42, is not exerted on the upstream wall 62. Therefore, the coil springs 92, which have been compressed, are restored to the natural state. Accordingly, the applying member 44 is moved to the upstream side in the rotating direction as compared with the through-holes 88 of the sliding section 84. In this state, the transfer mode stoppers 86 are allowed to protrude from the upper surface of the sliding section 84 again, and the processing liquid transfer roller 42 is rotated. Accordingly, the transfer mode is started.
In this embodiment, the upstream wall 62 is formed integrally with the applying member 44. Therefore, the upstream wall 62 is also moved in accordance with the movement of the applying member 44. It is assumed that the position of the upstream wall 62 is referred to as “upstream wall first position P3” when the applying member 44 is positioned at the “transfer mode position P1”. It is assumed that the position of the upstream wall 62 is referred to as “upstream wall second position P4” when the applying member 44 is positioned at the “cleaning mode position P2”. On this assumption, the contact pressure between the upstream wall 62 and the processing liquid transfer roller 42 is great when the upstream wall 62 is positioned at the “upstream wall second position P4” as compared with when the upstream wall 62 is positioned at the “upstream wall first position P3”. Therefore, the force, with which the foreign matter Q adhered to the surface of the processing liquid transfer roller 42 is scraped off, is increased in the “cleaning mode”, i.e., when “the upstream wall 62 is at the upstream wall second position P4” as compared with the “transfer mode”, i.e., when “the upstream wall 62 is positioned at the upstream wall first position P3”.
In this embodiment, the downstream wall 60 is formed integrally with the applying member 44. Therefore, the downstream wall 60 is also moved in accordance with the movement of the applying member 44. It is assumed that the position of the downstream wall 60 is referred to as “downstream wall first position P5” when the applying member 44 is positioned at the “transfer mode position P1”. It is assumed that the position of the downstream wall 60 is referred to as “downstream wall second position P6” when the applying member 44 is positioned at the “cleaning mode position P2”. On this assumption, as shown in
Therefore, in the “cleaning mode”, the foreign matter Q or the like can be efficiently scraped off owing to the large contact pressure of the upstream wall 62 with respect to the processing liquid transfer roller 42, and it is possible to effectively prevent the foreign matter Q or the like from entering the space between the upstream wall 62 and the processing liquid transfer roller 42. Further, the foreign matter Q or the like, which has been scraped off by the upstream wall 62, can be efficiently washed out with the large amount of the processing liquid R. The grooves 62a, which guide the foreign matter Q or the like to the processing liquid recovery section S, are formed on the outer side surface of the upstream wall 62, and the water-attracting treatment is applied. Therefore, the foreign matter Q or the like can be efficiently washed out with the processing liquid R, and the foreign matter Q or the like can be recovered by the processing liquid recovery section S. Further, when the cleaning mode stoppers 90 are also constructed so that the cleaning mode stoppers 90 can be positionally adjusted in the “tangential direction” by means of the stopper driving apparatus (not shown), the applying member 44 can be positioned at the position appropriate to remove the foreign matter Q or the like depending on the type of the foreign matter Q or the like.
In this embodiment, the “moving mechanism G”, which moves the applying member 44 between the “transfer mode position P1” and the “cleaning mode position P2”, is constructed by the processing liquid transfer roller 42, the support member 46, the coil springs 92, the transfer mode stoppers 86, and the cleaning mode stoppers 90. The downstream wall 60 and the upstream wall 62 are formed integrally with the applying member 44 (processing liquid accommodating cap 54). Therefore, “the operation for adjusting the applying amount of the processing liquid R with respect to the processing liquid transfer roller 42” and “the operation for adjusting the force (contact pressure) to scrape off the foreign matter Q or the like” can be simultaneously performed by means of the “moving mechanism G”. The operations can be performed easily and quickly.
In a processing liquid applying apparatus 108 according to a second embodiment, as shown in
In a processing liquid applying apparatus 112 according to a third embodiment, as shown in
The position of arrangement in the tangential direction of the applying member 44 in the “waiting state” is not specifically limited. However, in order to allow the forward ends of the respective walls 60, 62, 64 to reliably abut against the surface of the processing liquid transfer roller 42, it is desirable that the position of arrangement in the tangential direction of the applying member 44 in the “waiting state” is slightly deviated toward the upstream side in the rotating direction as compared with the “transfer mode position P1”. When the downstream wall 60 and the upstream wall 62 have the same height, it is desirable that the lowest point of the processing liquid transfer roller 42 is positioned at the center in the widthwise direction (tangential direction) of the opening 80 in order to obtain the equivalent contact pressure in relation to the processing liquid transfer roller 42, the downstream wall 60, and the upstream wall 62 in the “waiting state”.
In the respective embodiments described above, the downstream wall 60 and the upstream wall 62, which constitute the processing liquid accommodating cap 54, are formed integrally. Therefore, the “downstream wall moving mechanism” which moves the downstream wall 60 between the “downstream wall first position” and the “downstream wall second position” and the “upstream wall moving mechanism” which moves the upstream wall 62 between the “upstream wall first position” and the “upstream wall second position” are unified into one “moving mechanism G”. However, the downstream wall 60 and the upstream wall 62 may be moved distinctly by distinctly forming the downstream wall 60 and the upstream wall 62.
In the respective embodiments described above, the processing liquid R is accommodated in the processing liquid accommodating cap 54. However, for example, a porous member such as sponge or urethane, in which the processing liquid R is absorbed, may be accommodated in the processing liquid accommodating cap 54. In this case, the porous member and the processing liquid R absorbed in the porous member correspond to the “processing liquid applying section”.
In the respective embodiments described above, the present invention is applied to the “ink-jet printer”. However, the present invention is also applicable to any “image-forming apparatus” of another type including, for example, the “facsimile” and the “multifunction machine”. Further, the present invention is also applicable to any recording system including, for example, the “thermal transfer system”, the “electronic photograph system”, and the “silver salt photograph system” in addition to the “ink-jet system”.
In the respective embodiments described above, the “processing liquid transfer” is performed by the processing liquid applying apparatus 22 before the “image formation” by the liquid discharge apparatus 18. However, the “processing liquid transfer” may be performed after the “image formation”, or the “processing liquid transfer” may be performed both before and after the “image formation”.
In the respective embodiments described above, the printing paper 12 is used as the “transfer medium”. However, the type of the “transfer medium” is not specifically limited. For example, when a transmission type manuscript is prepared, it is also allowable to use a plastic sheet composed of polyethylene terephthalate or the like.
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2009-045832 | Feb 2009 | JP | national |
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Number | Date | Country | |
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20100220160 A1 | Sep 2010 | US |