1. Field of the Invention
The present invention relates to a liquid applying apparatus and an ink jet printing apparatus, and specifically, to a liquid applying apparatus that applies a liquid to a medium for a predetermined purpose, for example, for starting the coagulation of pigments earlier when printing is carried out using inks composed of the pigments as color materials. Likewise, the present invention relates to an ink jet printing apparatus comprising a mechanism that applies the liquid to a print medium used for ink jet printing, for a predetermined purpose, for example, for starting the coagulation of pigments earlier when printing is carried out using inks composed of the pigments as color materials.
2. Description of the Related Art
A spin coater, a roll coater, a bar coater, and a die coater are known as systems for applying a liquid or an aqueous material to various media. These applying systems are premised on continuous applying on relatively long applying media. Thus, for example, if applying media having a relatively small size and intermittently conveyed are to be applied the liquid to, paint beads may be disturbed at a position at which applying is started or ended. In this case, the coats obtained may be non-uniform among the applying media.
A known configuration that can solve this problem is described in Japanese Patent Application Laid-open No. 2001-070858. On the basis of the die coater system, this configuration uses a rotating rod bar and ejects a paint to the rod bar through an ejection slit to form a coat on the rod bar. The coat formed is contacted with and transferred to an applying medium as the rod bar rotates. In this case, when the coat formed on the rod bar is not transferred or applied to the applying medium, the paint is returned to a head by the rotation of the rod bar. The paint is then collected via a collecting slit. In other words, the rod bar continues to rotate even during non-applying, while the paint is being formed into a coat on the rod bar. This enables a uniform coat to be obtained even if applying media are intermittently supplied and applied the paint.
Even in the field of ink jet printing apparatuses, those using a liquid applying mechanism are known. Japanese Patent Application Laid-open No. 2002-517341 describes an apparatus which uses a doctor blade contacting with a roller and in which the application liquid is collected between the blade and the roller so that the application liquid is applied to the roller as the roller rotates. As the roller rotates, the application liquid applied to the roller is transferred and applied to a support conveyed between this roller and another roller. Japanese Patent Application Laid-open No. 08-072227 (1996) similarly discloses a mechanism in an ink jet printing apparatus which applies a treatment liquid before printing which liquid insolubilizes dyes. In Embodiment 1 of this document, the treatment liquid in a replenishing tank is pumped by being attached to the rotating roller. At the same time, the treatment liquid pumped is applied to print paper.
With the configurations described in the above patent documents, an application liquid is applied or supplied to the surface of the rod bar or roller. However, the part of the rod bar or roller to which the application liquid is applied or supplied is open to or in communication with the air. Thus, disadvantageously, the application liquid may be evaporated or for example, the application liquid may leak when the posture of the apparatus is changed.
In particular, with an ink jet printing apparatus such as a printer, in view of, for example, the leakage of the liquid caused by a change in the posture of the apparatus, it is difficult to apply the applying mechanism described in the above documents to the apparatus if its size has been reduced.
In contrast, Japanese Patent Application Laid-open No. 08-058069 (1996) discloses a configuration that seals a part that applies or supplies inks, that is, application liquids, to a roller. The applying mechanism described in this document operates in a gravure printing apparatus to apply inks to a roller (applying roller) having the surface of which is formed with a pattern of a printing plate. This mechanism uses an ink chamber having two doctor blades arranged at two vertical positions along a peripheral surface of the roller and extending in a longitudinal direction of the roller and elastic members provided at the opposite sides of the two doctor blades. The chamber is contacted with the peripheral surface of the roller to form a liquid chamber between the ink chamber and the roller. Then, the roller is rotated to apply or supply the application liquid from the liquid chamber to the roller.
However, the sealing arrangement disclosed in Japanese Patent Application Laid-open No. 08-058069 (1996) may provide an insufficient sealing property. That is, the doctor blades are separate from the elastic members provided at the opposite ends of each of the doctor blades through both doctor blades and elastic members are abutted against the roller for sealing. Thus, for example, the pressure exerted on the roller upon abutment may vary significantly between these members. In this case, the abutting pressure differs markedly between the junctions between the doctor blades and the elastic members and the other parts. Thus, the sealing may be insufficient in parts with a lower abutting pressure, resulting in the leakage of the liquid. If the abutting pressure itself is set at a large value in order to prevent the leakage of the liquid caused by the non-uniform abutting pressure, the application of inks to the roller may be unsatisfactory, which application is carried out by the blades and the roller in cooperation.
Moreover, in Japanese Patent Application Laid-open No. 08-058069 (1996), the ink chamber comprising the doctor blades and the elastic members is moved by engaging the ink chamber with a shaft in which a thread groove is formed and then rotating the shaft. The abutting pressure between the roller and the doctor blades and elastic members is exerted by simply fixing the position of the chamber. Thus, for example, if there are small concaves and convexes on the peripheral surface of the roller, the abutment does not conform to the concaves and convexes. This may degrade the sealing property to prevent inks from being favorably applied to the roller.
Further, Japanese Patent Application Laid-open No. 08-058069 (1996) describes the doctor blades provided to scrape extra inks adhering to the surface of the roller. Accordingly, this document does not disclose the configuration of blades or abutting portions which are preferred in association with the sealing property if the liquid is applied to the entire surface of a medium such as paper which has a certain thickness.
As described above, in association with the supply of the coating liquid to the roller, an arrangement is important which uses the abutting portion to appropriately seal the coating liquid chamber formed between the abutting portion and the roller. More specially, it is extremely important to provide the liquid holding space with a good sealing condition in order to keep a good quality of the applying liquid and enhance a handling ability of the applying apparatus in moving and transporting it. Accordingly, it is required to prevent the applying liquid from being evaporated and/or leaked while a roller remains stopped for a long time and when the posture of the applying apparatus happens to be tilted.
It is an object of the present invention to provide a liquid applying apparatus which can prevent an applying liquid from evaporating while an applying operation is at a stop and which can reliably prevent the liquid from leaking even when for example, the posture of the apparatus is tilted.
A first aspect of the present invention provides a liquid applying apparatus comprising a applying member which applies a liquid to a medium and which has a applying surface and a liquid holding member that abuts against the applying surface of the applying member to form a liquid holding space in which the liquid is held, the applying surface of the applying member being rotatively moved to apply the liquid supplied to the applying surface to the applying medium, the apparatus being characterized in that an abutting portion of the liquid holding member which abuts against the applying surface of the applying member is annularly formed of a single member.
Further, a second aspect of the present invention provides a printing apparatus characterized by comprising conveying means for conveying a print medium along a predetermined conveying path, printing means for printing the print medium, and a liquid applying mechanism that applies a liquid to the print medium conveyed along the conveying path, wherein the liquid applying mechanism comprises a applying member which applies a liquid to a medium and which has a applying surface and a liquid holding member that abuts against the applying surface of the applying member to form a liquid holding space in which the liquid is held, the applying surface of the applying member is rotatively moved to apply the liquid supplied to the applying surface to the applying medium, and an abutting portion of the liquid holding member which abuts against the applying surface of the applying member is annularly formed of a single member.
According to the present invention, a sufficient liquid-tight state can be established between the applying surface and the abutting portion. This makes it possible to prevent the applying liquid supplied to the liquid holding space from evaporating even if the apparatus is not used for a long period. Moreover, the present invention can prevent the applying liquid from leaking even if the whole apparatus is tiled during movement, transportation, or the like.
The above and other objects, effects, features and advantages of the present invention will become more apparent from the following description of embodiments thereof taken in conjunction with the accompanying drawings.
Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
According to the present embodiment, if the applying operation is not performed, a liquid is collected from a liquid holding space formed between an applying roller and a liquid holding member to hold the liquid.
The liquid applying means has a cylindrical applying roller 1001, a cylindrical counter roller (medium supporting member) placed opposite the applying roller 1001, and a roller driving mechanism 1003 that drives the applying roller 1001. The roller driving mechanism 1003 comprises a roller driving motor 1004 and a transmission mechanism 1005 which transmits the driving force of the roller driving motor 1004 to the applying roller 1001 and which has a gear train and the like.
The liquid supplying means has, for example, a liquid holding member 2001 that holds the application liquid between the liquid holding member 2001 and a peripheral surface of the applying roller 1001, and a liquid channel 3000 (not shown in
The liquid applying apparatus according to the present embodiment further comprises an applying medium supplying mechanism 1006 which consists of a pickup roller or the like to convey an applying medium to a nip portion between the applying roller 1001 and the counter roller 1002. Further, in a conveying path for applying media, a sheet discharging mechanism 1007 consisting of a sheet discharging roller or the like is provided downstream of the applying roller 1001 and the counter roller 1002 to convey a applying medium on which the application liquid has been applied, to a sheet discharging section (not shown). Like the applying roller and the like, the sheet supplying mechanism and the sheet discharging mechanism are operated under the driving force of the driving motor 1004 transmitted via the transmission mechanism 1005.
The application liquid used in the present embodiment is intended to facilitate the coagulation of pigments when printing has been carried out using inks including the pigments as color materials.
An example of the components of the application liquid is shown below.
Tetrahydrate of calcium nitrate: 10%
Surface active agent: 1%
Water: remaining amount
The application liquid has a viscosity of 5 to 6 cp (centipoise) at 25° C.
In applications of the present invention, of course, the application liquid is not limited to the one described above. For example, a liquid including a component which insolubilizes or coagulate a dye may be used as another application liquid.
If water is used as a liquid to be applied, the slidability of the abutting portion between the applying roller and the liquid holding member according to the present invention is improved by containing a component that reduces surface tension in the liquid. In the above example of the components of the liquid to be applied, the glycerin and the surface active agent are components that reduce the surface tension.
Now, a detailed description will be given of the elements of the sections of the applying apparatus described above in brief.
The counter roller 1002 is biased by biasing means (not shown) toward the peripheral surface of the applying roller 1001. By rotating the applying roller 1001 clockwise in the figure, it is possible to sandwich an applying medium P on which the application liquid is to be applied, between the rollers, while conveying the applying medium P in the direction of an arrow in the figure.
According to the present embodiment, the applying roller is formed of silicon rubber and has a hardness of 40°, a surface roughness Ra of 1.6 μm, and a diameter of 23.169 mm. The counter roller 1002 is formed of iron and has a diameter of 14 mm.
Further, when urged and abutted against the peripheral surface of the applying roller 1001 under the biasing force of a spring member (pressing means) 2006, the liquid holding member 2001 forms an elongate liquid holding space S extending all over an area applied the liquid by the applying roller 1001. The application liquid from a liquid channel 3000, described later, is supplied to the interior of the liquid holding space S via the liquid holding member 2001. In this case, since the liquid holding member 2001 is configured as described below, the application liquid can be prevented from inadvertently leaking from the liquid holding space S to the exterior while the applying roller 1001 is stopped.
As shown in
As described above, in the liquid holding member according to this embodiment, the abutting member 2009, formed integrally and seamlessly, is continuously abutted without a gap against the outer peripheral surface of the applying roller 1001 under the biasing force of the spring member 2006. As a result, the liquid holding space S is substantially closed by the abutting member 2009, one surface of the space forming base material, and the outer peripheral surface of the applying roller 1001. The liquid is held in this space. Then, when the rotation of the applying roller 1001 is stopped, the abutting member 2009 and the outer peripheral surface of the applying roller 1001 maintain a liquid tight state. The liquid can be reliably prevented from leaking to the exterior. On the other hand, when the applying roller 1001 rotates, the applying liquid flows slippery between the outer peripheral surface of the applying roller 1001 and the abutting member 2009. The applying liquid then adheres to the outer peripheral surface of the applying roller in layers. In this case, when the applying roller 1001 is stopped and the liquid tight state is established between the outer peripheral surface of the applying roller 1001 and the abutting member 2009, the liquid cannot flow out of the space as described above. In this case, the abutting state of the abutting member 2009 includes not only direct abutment against the outer peripheral surface of the applying roller 1001 but also abutment against the outer peripheral surface via a liquid film formed under a capillary force.
As shown in
On the other hand, as shown in
If the liquid holding member 2001 is placed, in a vertical direction, below a horizontal line passing through a rotational center of the applying roller 1001 as shown in
As described below, according to the present embodiment, when the apparatus is powered off or if for example, no print instruction has been transmitted for a specified time, a collecting operation is performed to collect the applying liquid from the liquid holding space S and liquid channel 3000.
Now, consideration will be given of the case in which the liquid holding member 2001 is placed on the horizontal line passing through the rotational center of the applying roller 1001 as shown in
Accordingly, as shown in
As described above, the liquid holding member 2001 is desirably placed so that its applying abutting surface F1 is below its non-applying abutting surface F2 and that the liquid holding member 2001 is pressed against the applying roller 1001 in a direction inclined upward from the horizontal position in the vertical direction at least 10°. In other words, the liquid holding member 2001 is desirably placed in such an area as shown in
In the present embodiment, the applying abutting surface F1 is set below that the non-applying abutting surface F2. The applying roller 1001 and the liquid holding member 2001 are arranged so that the midpoint between the upper edge 2010 and lower edge 2011 of the liquid holding member 2001 is on a straight line inclined, in the forward rotating direction, at 45° from the horizontal line passing through the rotational center of the applying roller 1001.
(Application Liquid Channel)
The liquid channel 3000 has a first channel 3001 that connects the liquid supplying port 2004 of the space forming base member 2002, constituting the liquid holding member 2001, to a storage tank 3003 that stores the application liquid, a second channel (collecting channel) 3002 that connects the liquid collecting port 2005 of the space forming base material 2002 to the storage tank 3003 together. An air communicating port 3004 is formed in the storage tank 3003. The air communicating port 3004 is provided with an air communicating valve 3005 that selectively switches between a communicating state for the air and a closed state for the same. Further, the first channel 3001 is provided with a selector valve 3006. The selector valve 3006 switches between a communicating state of the first channel 3001 with the air and a closed state of the same. Moreover, the second channel 3002 connects to a pump 3007 used to force the application liquid and air to flow through the liquid channel 3000 in a desired direction. In this embodiment, the pump generates a flow of the liquid in a direction from the first channel 3001 to the second channel 3002 via the liquid holding space S (as shown by an arrow in
In this embodiment, the first channel 3001 and the second channel 3002 are formed of cylindrical tubes. An opening formed at an end of each tube is placed at the bottom of the storage tank 3003 or close to the bottom. The position of the opening allows the application liquid in the storage tank 3003 to be completely consumed.
According to this embodiment, various types of the selector valves 3006 are applicable provided that they selectively enable and disable the communication between the first channel 3001 and the air. In this case, a three-way valve is used as shown in
(Control System)
In
The control section 4000 connects to an input operation section 4004 including a keyboard, various switches, or the like with which predetermined instructions or data are input, a display section 4005 that provides various displays including inputs to and the set state of the liquid applying apparatus, and a detecting section 4006 including a sensor or the like which detects the position of a applying medium or the operational state of each section. The control section 4000 also connects to the roller driving motor 1004, a pump driving motor 4009, an air communicating valve 3005, and the selector valve 3006, via driving circuits 4007, 4008, 4010, and 4011.
(Liquid Applying Operation Sequence)
When the liquid applying apparatus is powered on, the control section 4000 executes an applying operation sequence described below, in accordance with the flowchart shown in
In step S1, the liquid holding space S is filled with the application liquid. In this filling step, the air communicating valve 3005 of the storage tank 3003 is first opened to the air. The selector valve (three-way valve) 3006 is also switched as shown in
Then, an applying start instruction is input (step S2). Then, the pump 3007 restarts operation (step S3). The applying roller starts rotating clockwise as shown by an arrow in
Then, an applying medium supplying mechanism 1006 conveys an applying medium to between the applying roller 1001 and the counter roller 1002. The applying medium is inserted between these rollers and conveyed to a sheet discharging section as the applying roller 1001 and the counter roller 1002 rotate (step S5). During this conveyance, the application liquid applied to the peripheral surface of the applying roller is transferred from the applying roller 1001 to the applying medium P as shown in
In
As described above, an applied part of the applying medium P is conveyed in the direction of the arrow under the conveying force of the applying roller 1001. Further, an unapplied part of the applying medium P is conveyed to the contact portion between the applying medium P and the applying roller 1001. This operation is continuously or intermittently performed to apply the application liquid to the entire applying medium.
The application liquid remaining on the applying roller 1001 slippery flows between the applying roller 1001 and the upper edge 2010 of the abutting member 2009 and returns to the liquid holding space S, against the pushing force of the abutting member 2009 of the liquid holding member 2001, which force acts on the applying roller 1001. The application liquid is then mixed with the application liquid filled into the space S.
The operation of returning the application liquid is similarly performed if the applying roller 1001 is rotated while no applying medium is present as shown in
Once the operation of applying the liquid to the applying medium has been performed as described above, the apparatus determines whether or not to finish the applying step. If the applying step is not to be finished, the process returns to step S5 to repeat the applying operation until the applying step is executed on the all the parts of the applying medium to which the liquid needs to be applied. When the applying step is finished, the applying roller 1001 is stopped (step S7). Moreover, the driving of the pump 3007 is stopped (step S8). Subsequently, the process shifts to step S2 to repeat the operations from step S2 to step S8 unless an applying start instruction is input before a predetermined period elapses. Even after the predetermined period has elapsed, if the applying start instruction is not input, a postprocess is executed such as a collecting operation of collecting the application liquid from the liquid holding space S and liquid channels (step S9). Then, the applying process is finished.
The collecting operation is performed by opening the air communicating valve 3005 and selector valve 3006 and driving the pump 3007 to cause the applying liquid in the applying liquid holding space S and second channel 3002 to flow into the liquid storing tank 3003. The collecting operation makes it possible to prevent the applying liquid from evaporating from the liquid holding space S. Further, after the collecting operation, the air communicating valve 3005 is closed and the selector valve 3006 is switched to block the communication between the liquid storing tank 3003 and both first channel 3001 and air communicating port 3013. The liquid storing tank 3003 is thus shut off from the air. Thus, the applying liquid can be prevented from evaporating from the liquid storing tank 3003. The applying liquid can also be prevented from flowing out even if the posture of the apparatus is tilted during movement, transportation, or the like.
As described above, in the liquid applying apparatus according to this embodiment, the rotation of the applying roller 1001 causes the applying liquid filled into the liquid holding space S to flow slipperily out of the liquid holding space S against the pressing force of the lower edge 2011 of the abutting member 2009 exerted on the applying roller 1001. The applying liquid is then supplied to the peripheral surface of the applying roller 1001 in layers. The thickness of the layers of the applying liquid, that is, the amount of applying liquid to be supplied to the applying roller 1001, depends on the viscosity of the applying liquid, the relative speed between the outer peripheral surface of the applying roller and the applying medium, and the pressing force of the abutting member exerted on the outer peripheral surface of the applying roller 1001.
As is apparent from the above graph, the stronger the pressing force of the abutting member 2009 exerted on the outer peripheral surface of the applying roller 1001, the smaller the thickness of the layer of the applying liquid flowing out slipperily from between the abutting member 2009 and the applying roller 1001. As a result, the amount of applying liquid applied decreases. On the other hand, the higher the relative speed, the larger the thickness of the layer of the applying liquid flowing out slipperily from between the abutting portions. As a result, the amount of applying liquid applied increases.
In this embodiment, foreign matter such as paper dust or dirt may be caught in the nip portion between the applying roller 1001 and the lower edge 2011 of the abutting member 2009, between the applying roller 1001 and the upper edge 2010 of the abutting member 2009. According to the present embodiment, a frictional force exerted between the applying roller 1001 and the foreign matter is stronger than that exerted between the abutting member 2009 and the foreign matter. Thus, the foreign matter moves together with the applying roller 1001 instead of remaining between the applying roller 1001 and the abutting member 2009. In contrast, if the frictional force exerted between the applying roller 1001 and the foreign matter is weaker than that exerted between the abutting member 2009 and the foreign matter, the foreign matter remains between the abutting member 2009 and the applying roller 1001. This may result in, for example, the nonuniform application of the applying liquid or the entry of air into the liquid holding space.
To set the frictional force exerted between the applying roller 1001 and the foreign matter stronger than that exerted between the abutting member 2009 and the foreign matter as described above, this embodiment sets the hardness of the applying roller 1001 lower than that of the lower edge 2011 or the upper edge 2010. Further, the abutting member 2009 is formed of a material that can slide more smoothly (that has a smaller coefficient of friction) than the applying roller 1001.
While the applying means of the present embodiment is carrying out applying, the applying liquid permeates through the abutting portion between the applying roller 1001 and the abutting member 2009 to function as a lubricant. Thus, the applying roller 1001 can slide more smoothly when rotated without any applying liquid than while carrying out applying. Even if the applying liquid is held in the liquid holding member, when the standing-by applying roller 1001, which is at a stop, is rotated, it can slide substantially as smoothly as when rotated without any applying liquid. The reason will be described below. Immediately after the applying roller 1001 has switched from the applying state to the stopped state, the applying liquid is present in the abutting portion between the applying roller 10014 and the abutting member 2009. However, as the time elapses, the applying liquid present in the abutting portion between the applying roller 1001 and the abutting member 2009 is pushed out of the abutting portion. The resulting state is comparable to that observed when the applying roller 1001 is rotated without any applying liquid.
If the applying roller cannot slide smoothly when rotated as described above, loads on a motor that is the driving source of the applying roller 1001 increase. It is thus necessary to use a large-scale motor or increase power consumption.
It is therefore desirable to allow the applying roller 1001 to slide smoothly over the abutting member 2009 even without any applying liquid. Thus, the applying roller 1001 was experimentally made using the materials listed below. Experiments were made for the slidability of the applying roller 1001 on the abutting member 2009.
Material 1: EPDM of rubber hardness 30°
Material 2: EPDM of rubber hardness 50°
Material 3: EPDM of rubber hardness 70°
Material 4: NBR (type A) of rubber hardness 30° (vulcanizing cross-linked)
Material 5: NBR (type B) of rubber hardness 40° (peroxide cross-linked)
Material 6: Silicon rubber (type A) of rubber hardness 40°
Material 7: Silicon rubber (type A) of rubber hardness 70°
Material 8: Silicon rubber (type B) of rubber hardness 50°
Material 9: Silicon rubber (type B) of rubber hardness 70°
Both materials 4 and 5 are NBR but are formed of different rubber materials. All materials 6, 7, 8, and 9 are silicon rubber but have different grades.
In the graph in
In the graph in
The above results indicate that the slidability of the applying roller 1001 upon rotation can be improved by forming at least one of the applying roller 1001 and abutting member 2009 using silicon rubber.
Now, with reference to
According to the second embodiment, the applying member that applies the applying liquid to the applying medium is composed of the applying roller 1001, the counter roller 1002, and the intermediate roller 1006. The abutting member 2009 of the liquid holding member 2001 configured as in the case of the first embodiment is abutted against the applying roller 1001 under the pressing force of the spring member 2006. A liquid holding space S is thus formed between the intermediate roller 1006 and the applying member.
In this case, the applying roller 1001 and the counter roller 1002 are composed of a material similar to that used in the first embodiment. The intermediate roller 1006 is composed of the same material as that of the applying roller 1001 and has the same diameter as that of the roller 1001. Further, the intermediate roller 1006 rotates in synchronism with the applying roller 1001 at the same rotation speed. The intermediate roller 1006 can be rotated using the driving force of the roller driving motor 1004 (see
In the second embodiment configured as described above, the applying liquid from a liquid supplying channel 3000 (see
During an applying operation, the applying roller 1001 and the intermediate roller 1006 start to rotate in synchronism in opposite directions as shown by arrows in
Thus, the applying liquid supplied to the applying roller 1001 is divided at the abutting position between the intermediate roller 1006 and the applying roller 1001. This makes it possible to limit the amount of applying liquid supplied to the applying roller 1001. In other words, it is possible to supply a reduced amount of applying liquid to the applying medium P compared to the direct applying, from the liquid holding space S, of the applying liquid to be applied to the applying roller 1001. Therefore, the present embodiment is effective if a small amount of applying liquid is to be supplied to the applying medium.
Now, with reference to
In the above description of the first and second embodiments, by way of example, the applying roller 1001 constitutes the applying member that applies the liquid to the applying medium. According to the third embodiment, the applying member is constructed by extending an endless belt 1009 around two rollers 1007 and 1008 instead of the applying roller 1001 and disposing a counter roller 1010 that sandwiches the belt 1009 between itself and the roller 1008.
On the other hand, the liquid holding member 2001 is configured as shown in the above embodiments. The abutting member 2009 of the liquid holding member 2001 abuts against the roller 1007 under the pressing force of the spring member 2006 at a position where it is opposite the roller 1007. An outer surface of the endless belt 1009 desirably has surface energy higher than that of the counter roller 1010. Additionally, for example, the liquid channel through which the applying liquid is supplied to the liquid holding space S is similar to that of the above embodiments.
In the third embodiment, while the belt 1009 is at a stop, the liquid holding space S maintains a liquid-tight state between the abutting member 2009 and the endless belt 1009. This prevents the liquid from leaking from the liquid holding space S. Further, during a liquid applying operation, the roller 1008 is rotated by the driving force of the motor or the like to circulate the endless belt 1009 in a direction shown by an arrow in the figure. The circulatory movement of the belt 1009 causes the applying liquid in the applying liquid holding space S to flow slipperily across the abutting position between the endless belt 1009 and the abutting member 2009. The applying liquid then adheres, in layers, to the endless belt having passed through the liquid holding space S.
The applying liquid adhering to the endless belt 1009 reaches the abutting position between the endless belt 1009 and the counter roller 1010. The applying liquid is then applied to one surface of the applying medium P fed downward in the figure to the abutting position. When the endless belt 1009 is separated from the applying medium P, an amount of applying liquid remains on the endless belt 1009. This applying liquid is returned to the applying space S through between the endless belt 1009 and the lower edge 2011 of the abutting member 2009.
As described above, according to the third embodiment, the belt 1009 is used to apply the applying liquid to the applying medium P. The third embodiment is thus effective if for example, it is necessary to set a large distance or spacing between the liquid holding member 2001 and a position where the applying member applies the liquid to the applying medium P. In other words, whatever distance or spacing there is between the liquid holding member 2001 and the path through which the applying medium is moved, the liquid can basically be applied using three members including the two rollers 1007 and 1008 and the endless belt 1009. In addition to the two rollers, one or more idler rollers may be contacted with the endless belt 1009 so that its position is adjustable. Thus, even if the distance or spacing between the two rollers is set at various values, a constant tension can always be applied to the endless belt by adjusting the positions of the idlers rollers.
Now, with reference to
In the description of the first embodiment, by way of example, the liquid holding member 2001, cooperating with the applying roller 1001 in forming the liquid holding space S, is constructed by fastening the abutting member 2009 to the space forming base material 2002 using an adhesive or the like, the abutting member 2009 being separate from the base material 2002. In contrast, the elements of a liquid holding member 2020 according to the fourth embodiment are integrally formed of the same member.
Specifically, the liquid holding member 2020 is shaped by using a resin such as acrylic to integrally mold a space forming base material 2021 formed like a plate and having a rectangular front shape and an abutting portion 2022 formed like a rectangular ring and projecting along a peripheral portion of the space forming base material 2021 as shown in
Moreover, a liquid supplying port 2028 and a liquid recovering port 2029 are formed near opposite ends of a concave portion 2023 in the space forming base material 2021. Cylindrical connecting portions 2028 and 2029 are projected from the liquid supplying port 2028 and liquid recovering port 2029 for connection to the liquid channel. These connecting portions are integrally formed similarly to the other portions. The upper edge 2024, the lower edge 2025, and the left and right side edges 2026 and 2027 have their abutting surfaces roughened using file No. 500 so that the applying liquid permeates appropriately through the abutting surfaces.
On the other hand, desirably, the material and hardness of the applying roller 1001 are properly determined in accordance with the material of the liquid holding member 2020. For example, if the liquid holding member 2020 is formed of acrylic, the applying roller 2001 may be formed of aluminum, while the counter roller 3001 may be formed of EPDM. Further, the EPDM has a rubber hardness of 50°.
By abutting the liquid holding member 2020 configured as described above, against the outer peripheral surface of the applying roller 1001 using the spring member 2006 as in the case of the first embodiment, it is possible to reliably prevent the liquid from leaking from the liquid holding space S as a result of the abutment between the applying roller 1001 and the abutting member 2009 while the applying roller 1001 is at a stop. On the other hand, while the applying roller 1001 is rotating, the applying liquid can be supplied to the peripheral surface of the applying roller 1001 in layers against the pressing force of the abutting member 2020 exerted on the applying roller 1001 as in the case of the first embodiment. Furthermore, in the fourth embodiment, the liquid holding member 2020 is integrally molded of the single member. Consequently, the fourth embodiment is expected to produce a liquid leakage prevention effect superior to that produced in the case of the sticking of the separate member. Further, manufacturing costs can be sharply reduced.
Description will be given below of a preprocess liquid supplying means according to the fourth embodiment of the present invention.
The liquid holding mechanism 2030 will be described with reference to
In
This configuration allows the liquid holding member 2031, the stopper 2032, and the pedestal 2033 to operate integrally. The liquid holding member 2031, the stopper 2032, and the pedestal 2033 can be guided to guide holes 20352 formed in the right and left guides 2034 and in a positioning portion 20351 of the pedestal 2035. The liquid holding member 2031, the stopper 2032, and the pedestal 2033 can then be slid in the normal direction of the applying roller 1001. Reference numeral 2036 denotes a spring member mounted on the pedestal 2035 to urge the holding member 2033 from its rear surface to bring the holding member 2031 into pressure contact with the applying roller 1001.
With the applying liquid holding mechanism 2030 according to the present embodiment, the liquid holding member 2031 abuts tightly against the outer peripheral surface of the applying roller along the upper edges 20311 of ribs of the liquid holding member 2031. As a result, the liquid holding member 2031 forms an elongate liquid holding space S extending all over an area to which the applying liquid is applied by the applying roller 1001. The applying liquid from the liquid supplying path, described later, is supplied to the interior of the liquid holding space S via the liquid holding member 2030.
According to the present embodiment, the applying roller 1001 is formed of silicon and has a surface roughness Ra of 1.8 and a diameter of 23.169 mm. The liquid holding member 2031 is formed of EPDM having a rubber hardness of 50°. Further, according to the present embodiment, for the two projecting portions 20311 of the liquid holding member 2031, the abutting surface located downstream of the applying roller 1001 is below the one located upstream of the applying roller 1001. Furthermore, the applying roller 1001 and the liquid holding member 2031 are arranged at positions such that the midpoint between the two projecting portions of the liquid holding member 2031 lies on a straight line inclined at 45° from a horizontal line passing through the rotational center of the applying member.
When the liquid holding member 2031 according to the present embodiment was used and the pressing force exerted by the spring member 2036 on the liquid holding member was set at 2,000 gf, about 0.15 g of applying liquid was able to be applied to A4-sized ordinary paper.
In the above embodiments, the amount of liquid to be applied to the applying medium can be changed by changing the pressing force of the liquid holding member exerted on the coating roller, the pressing force changed by changing the magnitude of the elastic force of the spring member.
Moreover, the amount of liquid to be applied can be changed by changing the hardness of the liquid holding member and of the applying roller or a roller supporting the endless belt.
Further, in the above embodiments, the use of the coil spring serving as a spring member is shown as pressing means for pressing the liquid holding member against the applying roller. However, another spring, for example, a plate spring, can also be used. Moreover, an elastic member such as rubber can be used in place of the spring member.
According to the present invention, the positions where the liquid supplying port and the liquid collecting port are formed in the liquid holding member as well as the numbers of liquid supplying and collecting ports are not limited to those in the above embodiments. For example, it is possible to arrange the liquid supplying ports at the opposite ends of the liquid holding space, while forming one or more liquid collecting ports between these liquid supplying ports. Conversely, it is possible to arrange the liquid collecting ports at the opposite ends of the liquid holding space, while forming one or more liquid supplying ports between these liquid supplying ports. In short, the liquid held in the liquid supplying member has only to be able to flow through the liquid holding space.
In the above embodiments, the counter roller is provided opposite the applying roller or endless belt. However, a support member such as a plate material may be provided in place of the counter roller so that the applying member is sandwiched between the plate material and the applying roller. Then, the moving force of the applying roller or endless belt may be transmitted to the applying medium. In this case, a surface of the support member which contacts with the applying medium must have a small coefficient of friction and a low surface energy.
The ink jet printing apparatus 1 is provided with a feeding tray 2 on which a plurality of print media P are stacked. A semicircular separating roller 3 separates each print medium P from the others stacked on the feeding tray and then feeds it to a conveying path. The applying roller 1001 and the counter roller 1002 are arranged in the conveying path; the applying roller 1001 and the counter roller 1002 constitute liquid applying means of the liquid applying mechanism. The print medium P fed by the feeding tray 2 is then fed to between the rollers 1001 and 1002. The applying roller 1001 is rotated clockwise in
As this ink jet printing apparatus, what is called a full line type can be constructed in which an elongate print head having nozzles from which inks are ejected and which are disposed over the maximum width of the print medium is used to perform a printing operation.
The application liquid used in the present embodiment is a treatment liquid that facilitates the coagulation of pigments when inks composed of the pigments as color materials are used for printing.
In the present embodiment, the treatment liquid is used as an application liquid to react with the pigments, which are the color materials of the inks ejected to the print medium to which the treatment liquid has been applied. This facilitates the coagulation of the pigments. The facilitation of the coagulation of the pigments improves the printing density. Moreover, it is possible to suppress or prevent bleeding. The application liquid used in the ink jet printing apparatus is not limited to the above example.
In accordance with a program of a process procedure described later in
As shown in
After this applying step, a printing operation is performed on a print medium having the application liquid applied to desired parts of the medium (step S106). That is, the print head 7 is scanned over the print medium P conveyed by the conveying roller 4 by a predetermined amount at a time. During the scan, inks are ejected from the nozzles in accordance with print data so as to adhere to the print medium to form dots. The adhering inks react with the application liquid, thus improving the concentration and preventing bleeding. The conveyance of the print medium and the scanning of the print head are repeated to print the print medium P. The finished print medium is discharged onto the sheet discharging tray 10. When the apparatus determines in step S107 that the printing has been finished, the processing in step S108 and the subsequent steps is executed to finish the present process.
In the present embodiment, as the liquid is applied to the print medium, printing is sequentially executed on parts of the print medium to which the liquid has already been applied. That is, the conveying path from the conveying roller to the print head is shorter than the print medium, and when a part of the print medium to which the liquid has already been applied reaches the scan area of the print head, the applying mechanism applies the liquid to another part of the print medium. Every time the print medium is conveyed by a predetermined amount, liquid application and printing are sequentially executed on different parts of the print medium. However, in an alternative form of application of the present invention, printing may be carried out after one print medium has been completely applied the application liquid to as described in Japanese Patent Application Laid-open No. 2002-096452.
In the above embodiments, by way of example, the liquid is applied in the ink jet printing-based printing apparatus. However, the present invention is applicable to printing apparatuses based on other systems. For example, the degree of whiteness of the medium can be improved by using a liquid containing a fluorescent whitening agent as an application liquid. A liquid containing components to restrain a curl (phenomenon in which a medium becomes curve shape) of the application medium may be used. The printing means after the liquid application is not limited to the ink jet printing system. Effects can be produced using a printing system such as a thermal transfer system or an electrophotographic system. In a silver salt-based printing apparatus, a photosensitive agent as the application liquid may be applied before printing.
The present invention has been described in detail with respect to preferred embodiments, and it will now be apparent from the foregoing to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspect, and it is the intention, therefore, in the apparent claims to cover all such changes and modifications as fall within the true spirit of the invention.
This application claims priority from Japanese Patent Application Nos. 2004-035800 filed Feb. 12, 2004 and 2005-006773 filed Jan. 13, 2005, which are hereby incorporated by reference herein.
Number | Date | Country | Kind |
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2004-035800 | Feb 2004 | JP | national |
2005-006773 | Jan 2005 | JP | national |
Number | Date | Country | |
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Parent | 11052062 | Feb 2005 | US |
Child | 12124744 | US |