Liquid material supply device that maintains viscosity of the liquid at a fixed level

Information

  • Patent Grant
  • 6453141
  • Patent Number
    6,453,141
  • Date Filed
    Thursday, January 4, 2001
    23 years ago
  • Date Issued
    Tuesday, September 17, 2002
    21 years ago
Abstract
An ink supply device that has a roller a part of which is submerged in ink and supplies ink from an ink container based on the rotation of the roller, wherein an object thereof is to prevent the solvent, the main ingredient of the ink, from evaporating and escaping from the container, and to supply ink in a stable fashion. To that end, the relationship (A/B) between the opening area A (the area of the opening 28 of the container) and the ink surface area B (the sum of the area of the ink surface other than the part thereof in which the roller is submerged and the area of the ink surface carried on the roller above the ink surface) is set to be smaller than 1 (<1) when an ink supply mode is present. When an ink non-supply mode is present, the relationship (A/B) between the opening area A (the area of the opening of the container from which the area of the part thereof taken up by the roller is subtracted) and the ink surface area B (the area of the ink surface other than the part thereof in which the roller is submerged) is set to be smaller than 1 (<1).
Description




This application is based on application No. JP 2000-000793 filed in Japan, the contents of which is hereby incorporated by reference.




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention pertains to an improved liquid material supply device that causes a liquid material (such as ink, for example) to be carried on the continuous outer circumferential surface (liquid material carrying surface) of a continuous carrier (such as a roller or a belt, for example), as well as to an image forming apparatus incorporating such liquid material supply device.




2. Description of the Related Art




Among various types of liquid ink supply devices are those that use a blade to cause the ink adhering to the outer circumferential surface of a rotating roller to become a thin uniform-thickness layer, and transfer this thin layer of ink to an image (comprising convex areas, or a latent image) carried on a plate, image carrier, etc.




In an ink supply device of this type, a prescribed pressure is applied to the blade such that it is in pressure contact with the outer circumferential surface of the rotating roller. The excess ink adhering to the roller is removed by the blade when the ink passes through the area of contact between the blade and the roller. As a result, a uniform thin layer of ink is formed. In addition, the thickness of the ink layer may be varied by adjusting the pressure applied to the blade that is in contact with the roller.





FIG. 11

shows a conventional ink supply device


1


using a blade as described above. This ink supply device


1


includes a container (developer container)


2


. An ink cartridge


4


is located in the housing of the container


2


such that it may be removed. Ink


6


is supplied from the cartridge


4


to the container


2


such that the depth of the ink


6


is maintained at a prescribed level in the container


2


. A roller (developing roller)


10


, which has a shaft


8


that runs parallel to the surface of the ink


6


and extends in the direction perpendicular to the sheet, is located in the upper area of the container


2


such that the bottom of the roller is below the ink surface. The shaft


8


is connected to a motor


12


, so that the roller


10


rotates in the direction of an arrow


13


in the drawing as the motor


12


rotates. A regulating blade


16


, which comprises a plate-shaped elastic member supported by a pressing member


14


, is located downstream from the area of the roller submerged in the ink


6


in terms of the roller rotational direction


13


. This regulating blade


16


protrudes essentially tangentially to the roller


10


and in the downstream direction of the rotation of the roller


10


, such that it is in contact with the roller


10


under a prescribed pressure. In addition, an image carrier (image carrying roller)


22


, which has a shaft


20


that is parallel to the surface of the ink


6


and extends in the direction perpendicular to the sheet, and carries a latent image in accordance with image information, is located above and near the roller


10


. The shaft


20


is connected to a motor


24


, and the image carrier


22


rotates in the direction of the arrow


25


of the drawings as the motor


24


rotates.




The operation of the ink supply device


1


will be explained below with reference to FIG.


11


. When the roller


10


rotates via the motor


12


, the ink


6


adhering to the surface of the roller


10


reaches the regulating blade


16


as it is carried on the roller


10


as the roller


10


rotates. Here, excess ink


6


is removed by the regulating blade


16


through the receipt of a prescribed pressure therefrom. A uniform thin layer of ink


6


having a desired thickness (several μm to several tens of μm) is formed on the surface of the roller


10


in accordance with the pressure from the regulating blade. The thin layer of ink


6


is then transferred to the image carrier


22


in the transfer area


26


. For the method by which to transfer the ink


6


to the image carrier


22


from the roller


10


, either a contact method or a non-contact method may be used.




In the ink supply device


1


described above, where the opening


28


(the area indicated by dotted lines in the drawing) through which the interior of the container


2


is exposed to the outside atmosphere is large, the amount of solvent (i.e., water in the case of a water-based ink) of the ink


6


in the container


2


that evaporates and escapes through the opening


28


is large, and consequently, the viscosity of the ink


6


increases. If the container


2


were completely closed off, the water component of the ink


6


would be maintained in equilibrium between the ink


6


housed in the container


2


and the remaining space in the container


2


, and therefore the viscosity of the ink


6


would change very little. However, in actuality, the container


2


is never completely closed during development due to the mechanical construction of the device. When the viscosity of the ink increases, an ink layer that is thicker than the desired thickness is formed on the roller


10


. Such an increase in the ink layer thickness increases the amount of ink transferred to the image carrier


22


, and in turn, image failure when an image is formed on the sheet using this ink (such as the so-called cockling in which the sheet warps as a result of shrinking due to absorbed ink, resulting in a wavy sheet surface, for example) as well as ink bleed-through. (In this application, ‘the outside atmosphere’ refers to the atmosphere that exists outside the opening


28


of the container


2


, and is distinguished from the gas that exists inside the opening


28


of the container


2


).




OBJECTS AND SUMMARY




The present invention was created in view of the situation described above, and the object thereof is to provide an improved ink supply device. In other words, an object of the present invention is to provide an ink supply device that can supply ink under stable conditions. More particularly, an object of the present invention is to provide an ink supply device that prevents the solvent, which is the main ingredient of the ink inside the developer container, from evaporating and escaping from the container, in order to maintain the ink viscosity at an essentially fixed level, and that consequently forms a layer of ink having an essentially uniform thickness on the surface of a liquid carrier such as a roller


10


.




In order to attain this and other objects, the liquid material (ink) supply device according to one aspect of the present invention has a rotational shaft; a liquid material carrier having a continuous liquid material carrying surface around the rotational shaft; a motor that causes the liquid material carrier to rotate in a prescribed direction around the rotational shaft; and a container that houses a liquid material such that a part of the liquid material carrying surface may be submerged in the liquid material, so that the liquid material may be supplied onto the liquid material carrying surface, and the top part of which is open, wherein the liquid material supplied onto the liquid material carrying surface is conveyed to the transfer area through the rotation of the liquid material carrier that occurs based on the rotation of the motor, and is supplied to the liquid material receiving member in the transfer area. The liquid material supply device further has a liquid material supply mode in which the liquid material is supplied from the liquid material carrier to the liquid material receiving member, and a liquid material non-supply mode in which the liquid material is essentially removed from the liquid material carrier.




In this liquid material supply device, according to one aspect of the present invention, a part of the liquid material carrier is located outside the opening of the container, and the liquid material is supplied from the liquid material carrier to the liquid material receiving member using one area of the above part of the liquid material carrier, and the opening area A and the liquid material surface area B defined below satisfy the relationship (A/B)<1 when the liquid material supply mode or the liquid material non-supply mode is present.




(1) When Liquid Material Supply Mode is Present




Opening area A: The area of the opening of the container




Liquid material surface area B: The sum of the area of the liquid surface other than the part thereof in which the liquid material carrier is submerged, and the area of the liquid material surface carried on the liquid material carrier above the liquid surface.




(2) When Liquid Material Non-Supply Mode is Present




Opening area A: The area of the opening of the container from which the area of the part thereof taken up by the liquid material carrier is subtracted.




Liquid material surface area B: The area of the liquid surface other than the part thereof in which the liquid material carrier is submerged.




According to another aspect of the present invention, the liquid material carrier is located inside the container while the liquid material receiving member is located outside the container, the liquid material is supplied to the liquid material receiving member from the liquid material carrier via the opening of the container, and the opening area A and the liquid material surface area B defined below satisfy the relationship (A/B)<1 when the liquid material supply mode or liquid material non-supply mode is present.




(1) When Liquid Material Supply Mode is Present




Opening area A: The area of the opening of the container




Liquid material surface area B: The sum of the area of the liquid surface other than the part thereof in which the liquid material carrier is submerged, and the area of the liquid material surface carried on the liquid material carrier above the liquid surface.




(2) When Liquid Material Non-Supply Mode is Present




Opening area A: The area of the opening of the container




Liquid material surface area B: The area of the liquid surface other than the part thereof in which the liquid material carrier is submerged.




Furthermore, according to yet another aspect of the present invention, the liquid material carrier is located inside the container while a part of the liquid material receiving member is located inside the opening of the container, the liquid material is supplied to the liquid material receiving member from the liquid material carrier using an area of the above part of the liquid material receiving member, and the opening area A and the liquid material surface area B defined below satisfy the relationship (A/B)<0.3 when the liquid material supply mode or the liquid material non-supply mode is present.




(1) When Liquid Material Supply Mode is Present




Opening area A: The area of the opening of the container from which the area of the part thereof taken up by the liquid material receiving member is subtracted.




Liquid material surface area B: The sum of the area of the liquid surface other than the part thereof in which the liquid material carrier is submerged, and the area of the liquid material surface carried on the liquid material carrier above the liquid surface.




(2) When Liquid Material Non-Supply Mode is Present




Opening area A: The area of the opening of the container from which the area of the part thereof taken up by the liquid material receiving member is subtracted.




Liquid material surface area B: The area of the liquid surface other than the part thereof in which the liquid material carrier is submerged.











BRIEF DESCRIPTION OF THE DRAWINGS




These and other objects and features of the present invention will become apparent from the following description of preferred embodiments thereof taken in conjunction with the accompanying drawings, in which:





FIG. 1

is a drawing showing an ink supply device pertaining to the present invention;




FIG.


2


(


a


) is a perspective view showing the positional relationship between the developer container and the developing roller shown in FIG.


1


. FIG.


2


(


b


) is a basic drawing showing the state of the ink during development in the ink supply device shown in FIG.


1


. FIG.


2


(


c


) is a basic drawing showing the state of the ink when development is not taking place in the ink supply device shown in FIG.


1


.





FIG. 3

is a drawing showing another ink supply device pertaining to the present invention.




FIG.


4


(


a


) is a basic drawing showing the state of the ink during development in the ink supply device shown in FIG.


3


. FIG.


4


(


b


) is a basic drawing showing the state of the ink when development is not taking place in the ink supply device shown in FIG.


3


.





FIG. 5

is a drawing showing yet another ink supply device pertaining to the present invention.




FIG.


6


(


a


) is a basic drawing showing the state of the ink during development in the ink supply device shown in FIG.


5


. FIG.


6


(


b


) is a basic drawing showing the state of the ink when development is not taking place in the ink supply device shown in FIG.


5


.





FIG. 7

is a drawing showing a first embodiment of the image forming apparatus using an ink supply device pertaining to the present invention.





FIG. 8

is a drawing showing a second embodiment of the image forming apparatus using an ink supply device pertaining to the present invention.





FIG. 9

is a drawing showing a third embodiment of the image forming apparatus using an ink supply device pertaining to the present invention.




FIGS.


10


(A) through


10


(F) are a process drawing showing the method of image formation by the image forming apparatus shown in FIG.


9


.





FIG. 11

is a drawing showing a conventional ink supply device.











In the following description, like parts are designated by like reference numbers throughout the several drawing.




DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




The embodiments of the present invention are explained below with reference to the accompanying drawings. The explanation below will be provided with regard to the following three types of devices depending on the locations of the developing roller and the image carrier relative to the developer container.




Type I: A part of the developing roller is located outside the developer container (the image carrier is also located outside the developer container).




Type II: The entire developing roller is located inside the developer container, and the image carrier is located outside the developer container.




Type III: The entire developing roller is located inside the developer container, and a part of the image carrier is located inside the developer container.




Type I





FIG. 1

shows an ink supply device


1


′ of type I. This device resembles the ink supply device


1


shown in FIG.


11


. Therefore, the same numbers are used for identical parts and members, and only the features and parts that differ from or were not explained in detail with reference to

FIG. 11

will be described here.




An ink cartridge


4


is installed such that it faces the side wall


2




a


of the container


2


. An opening


28


is formed in the top wall


2




b


of the container


2


, and the roller


10


is located such that its top part is located above the opening


28


. The roller


10


rotates with the shaft


8


working as the rotational axis, and may rotate not only in the direction of the arrow


13


but also in the reverse direction


30


. The cleaning blade


32


to remove the residual ink that was not transferred in the transfer area


26


is located between the transfer area


26


and the part of the roller submerged in the ink


6


in terms of the rotational direction


13


of the roller


10


, as well as near the surface of the ink


6


. This cleaning blade


32


protrudes essentially tangentially to the roller


10


and in the downstream direction in terms of the rotation of the roller


10


, and is in contact with the roller


10


under a prescribed pressure. Through this construction, the cleaning blade


32


removes from the outer circumferential surface of the roller


10


the ink


6


that is lifted from the container


2


with the roller


10


when the roller


10


rotates in the direction


30


, which is the opposite direction from the direction of the arrow


13


.




Moreover, in the present invention, in order to prevent the liquid solvent from evaporating from the ink


6


in the developer container


2


and escaping from the container


2


, the opening area A that comprises the area of the region through which the gas inside the container


2


is exposed to the outside atmosphere, and the ink surface area B that comprises the area of the border surface between the ink and the gas, both of which are defined in detail below, are set such that the value of the A/B ratio is smaller than a prescribed value.




Opening Area A




The opening area A is defined as the area of the opening


28


of the container


2


during ink supply (during development) during which an ink layer is formed on the roller


10


. For example, where the opening


28


comprises a rectangle having a length and width of a


1


and a


2


as shown in FIG.


2


(


a


), A=a


1


×a


2


.




On the other hand, during non-supply of ink or non-development during which the ink supply device


1


′ is not used for a prescribed period of time (as described below, there is no residual ink


6


on the roller


10


), because the roller


10


has the function to close off a part of the opening


28


, the opening area A is defined as the area of the opening


28


of the container


2


from which the area thereof taken up by the roller


10


is subtracted. For example, where the roller


10


is placed as shown in FIG.


2


(


c


), A=(a


3


+a


4


)×a


2


.




Ink Surface Area B




Ink surface area B is defined, during development, as the total of the area C of the ink surface other than the part thereof in which the roller


10


is submerged and the area D of the ink layer surface on the roller


10


(which is above the ink surface). For example, in the case of FIG.


2


(


b


), the ink surface area B is the sum of the area C corresponding to b


1


and b


2


and the area D corresponding to b


3


.




On the other hand, when development is not taking place, i.e., when the ink supply device


1


′ is not used for a prescribed period of time, the ink surface area B is defined as the area C of the ink surface other than the part thereof in which the roller


10


is submerged.




The ink supply operation of the ink supply device


1


′ of this embodiment is identical to the ink supply device


1


shown in FIG.


11


. Where the ink supply device


1


′ is not used for a prescribed period of time, the roller


10


is cleaned in the following manner after the completion of ink supply. That is, the roller


10


is rotated in the reverse direction indicated by the arrow


30


for a prescribed distance (at least until the part of the roller that is in contact with the cleaning blade


32


immediately after the commencement of the cleaning reaches the ink surface via the rotation in the direction of the arrow


30


), and is thereafter stopped. In this embodiment, because the roller


10


and the cleaning blade


32


are in contact with each other close to and upstream from the ink surface in terms of the rotational direction


30


of the roller


10


, in the cleaning operation, the ink


6


that adheres to the roller surface in the container


2


is removed by the cleaning blade


32


immediately after it is lifted out from the ink surface. As a result, when the ink supply device


1


is not being used, the part of the roller not submerged in the ink has no ink


6


adhering to it (see FIG.


2


(


c


)).




Type II





FIG. 3

shows an ink supply device


1


″ of type II. In this type, the entire developing roller


10


is located inside the developer container


2


while the image carrier


22


is located outside it, and therefore the opening area A is defined as the area of the opening


28


both during development and when development was not taking place. The definition of the ink surface area B is the same definition used in connection with a type I device (see FIG.


4


). In the situation of a type II device, a non-contact method is used for the transfer of ink


6


from the roller


10


to the image carrier


22


.




Type III





FIG. 5

shows an ink supply device


1


″′ of type III. In this type, the image carrier


22


closes off a part of the opening


28


, and therefore the opening area A is defined as the area of the opening


28


from which the area of the part thereof taken up by the image carrier


22


is subtracted both during development and when development was not taking place. For example, where the image carrier


22


is placed as shown in

FIG. 6

, the opening area A comprises the areas corresponding to a


5


and a


6


. The definition of the ink surface area B is the same definition used in connection with a type I device.




Experiment




Using ink supply devices of types I, II and III, the inventors of the present invention formed ink layers on the rollers using the following ink while changing the value of the opening area A/ink surface area B ratio, and measured the thickness of these thin ink layers using a Keyence LS-5000 laser-based measuring device. The ink layers were formed in ten hours after the ink was prepared and mounted in each ink supply device.




Printing Conditions




Developing roller: 3 cm diameter, 30 cm length




Image carrier (image carrying roller): 10 cm diameter, 30 cm length




Ink Composition




Distilled water: 80% by weight




Pigment: Cabot-300 (Cabot pigment dispersing agent was used), 5.0% by weight




Polyethylene glycol resin (molecular weight 20,000): 15% by weight




The mixture comprising the above ingredients was mixed and churned for 40 minutes using a stirrer, and the result was used as the ink (ink viscosity μ: 30 cps).




Experiment Example 1 and Results Thereof




Ink supply device: Type I




Opening area A: 48 cm


2


during development, 16 cm


2


when development was not taking place




Ink surface area B: 280 cm


2


during development (ink surface 75 cm


2


, ink layer on the roller 205 cm


2


), 75 cm


2


when development was not taking place (ink surface 75 cm


2


)




Therefore, A/B=48/280=0.17 (<1) during development, A/B=16/75=0.21 (<1) when development was not taking place.




In the above experiment, while the change in ink viscosity was 20% or less and the average thickness of the ink layer was 30 μm, the unevenness of the ink layer was ±3 μm. In other words, in the above experiment, because the gas exchange between the interior of the developer container and the outside atmosphere was reduced such that the humidity inside the developer container could be maintained at a high level, the loss of the solvent (drying of the ink) could be reduced, and consequently, the change in the ink viscosity could be reduced. It was confirmed by the inventors that in order to obtain desired images with little unevenness in darkness based on an essentially uniform transfer of the ink layer on the developing roller to the image carrier, unevenness in the ink layer thickness should be kept within 20% of the average thickness. Therefore, in the above experiment example, appropriate image darkness without unevenness may be obtained. In addition, because the increase in the ink viscosity is small, bleed-through and cockling do not occur.




Experiment Example 2 and Results Thereof




Ink supply device: Type II




Opening area A: 32 cm


2


both during development and when development was not taking place




Ink surface area B: 280 cm


2


during development (ink surface 75 cm


2


, ink layer on the roller 205 cm


2


), 75 cm


2


when development was not taking place (ink surface 75 cm


2


)




Therefore, A/B=32/280=0.11 (<1) during development, A/B=32/75=0.43 (<1) when development was not taking place.




In this case as well as in the experiment example 1, gas exchange between the gas inside the developer container and the outside atmosphere was reduced and the humidity inside the developer container could be maintained at a high level, and therefore the loss of solvent (drying of the ink) could be reduced, and consequently the change in the ink viscosity could be reduced accordingly.




Comparison Example 1 and Results Thereof




Ink supply device: Type II




Opening area A: 160 cm


2


both during development and when development was not taking place




Ink surface area B: 280 cm


2


during development (ink surface 75 cm


2


, ink layer on the roller 205 cm


2


), 75 cm


2


when development was not taking place (ink surface 75 cm


2


)




Therefore, A/B=160/280=0.57 (<1) during development, A/B=160/75=2.1 (>1) when development was not taking place.




In the above comparison example, when development was not taking place (A/B>1), gas exchange between the gas inside the developer container and the outside atmosphere occurred frequently, resulting in a significant loss of ink solvent and a 20% or larger change in the ink viscosity. Consequently, when an ink layer was formed on the roller using this ink in ten hours, while the average thickness of the layer was 30 μm, the unevenness in thickness was ±8 μm. This unevenness in the ink layer thickness appears as an unevenness in the ink amount transferred to the image carrier and further as an unevenness in the image formed by this ink. In addition, because the ink viscosity increased, bleed-through and cockling occurred.




Summary of Type I and Type II Experiment Results




With type I and type II configurations in which the image carrier is located outside the developer container, when the opening area A/ink surface area B ratio is smaller than 1, the change in the ink viscosity following a prescribed non-use period may be kept within a desired range, and as a result, an ink layer having a desired thickness may be stably formed on the developing roller. The preferred range for the A/B ratio is shown in the following table.



















A/B




Image quality













0.5 or less




Very good image without unevenness







0.5-1.0




Good image







1.0 or more




Image unevenness occurs















Experiment Example 3 and Results Thereof




Ink supply device: Type III




Opening area A: 16 cm


2


both during development and when development was not taking place




Ink surface area B: 280 cm


2


during development (ink surface 75 cm


2


, ink layer on the roller 205 cm


2


), 75 cm


2


when development was not taking place (ink surface 75 cm


2


)




Therefore, A/B=16/280=0.057 (<0.3) during development, A/B=16/75=0.21 (<0.3) when development was not taking place.




In the above experiment, while the change in ink viscosity was 20% or less and the average thickness of the ink layer was 30 μm, the unevenness of the ink layer was ±3 μm. In other words, because gas exchange between the gas inside the developer container and the outside atmosphere was reduced such that the humidity inside the developer container could be maintained at a high level, and the solvent of the ink inside the developer container (particularly, the ink on the developing roller) could be reduced, a change in ink viscosity in the developer container could be reduced accordingly.




In addition, in this experiment example, the surface of the image carrier inside the opening of the developer container is maintained in the high-humidity gas inside the developer container, and therefore, the drying of the developing ink adhering to the image carrier may also be reduced. As a result, a film of dried ink does not form on the image carrier surface and the viscosity of the ink transferred to the image carrier does not change due to the dried ink. Therefore, the ink layer on the image carrier is also formed in a stable manner, and appropriate image darkness without unevenness may be obtained.




Comparison Example 2 and Results Thereof




Ink supply device: Type III




Opening area A: 62 cm


2


both during development and when development was not taking place




Ink surface area B: 280 cm


2


during development (ink surface 75 cm


2


, ink layer on the roller 205 cm


2


), 75 cm


2


when development was not taking place (ink surface 75 cm


2


)




Therefore, A/B=62/280=0.22 (<0.3) during development, A/B=62/75=0.83 (>0.3) when development was not taking place.




In the above comparison example, when development was not taking place (A/B>0.3), dried ink film was formed on the image carrier and the viscosity of the ink transferred to the image carrier changed due to this dried ink, and during development ten hours later, there was insufficient fusing of the ink from the image carrier to the sheet, resulting in image failure such as blurriness.




Summary of Type III Experiment Results




With a type III configuration in which a part of the image carrier was located inside the developer container, when the opening area A/ink surface area B ratio was smaller than 0.3, the formation of ink film on the image carrier was prevented, and therefore desired images could be obtained. The preferred range for the A/B ratio is shown in the following table.



















A/B




Image quality













0.2 or less




Quite good image







0.2-0.3




Good image







0.3 or more




Image failure such as blurriness occurs















While ink supply devices pertaining to the present invention were explained above, the present invention may be modified in various ways. For example, while a roller


10


and image carrier


22


were used as the members to form an ink layer and the member to form an image, respectively, any other members (belt-shaped or flat members, for example) may be used so long as the construction is such that the regulating blade


16


or the cleaning blade


32


forms an ink layer on the member or removes the residual ink that was not transferred while it is in contact with the member surface and moves relative to the member. Examples of flat members include flat plates having a certain thickness and rigidity, such as printing plates, or film (such as plastic film, for example) wrapped around a drum and cut into a sheet-shaped piece for each printing. In the case of the latter, an ink layer is formed on the sheet-shaped piece which is wrapped on an image carrier or placed on a flat plate.




In addition, the opening


28


of the developer container


2


is not limited to the rectangular shape shown in FIG.


2


(


a


), and may have any other shape.




Furthermore, the cleaning blade may be placed between the part of the roller submerged in the ink


6


and the regulating blade


16


in terms of the rotational direction


13


of the roller


10


and near the surface of the ink


6


, such that it may move between a position separate from the roller


10


and a position at which it is in contact with the roller


10


and eliminates the ink


6


on the roller


10


. Where the ink supply device is not used for a prescribed period of time, cleaning is performed for a prescribed period of time (the time until at least the part of the roller that is in contact with the cleaning blade immediately after the commencement of cleaning re-enters the ink due to the rotation in the direction of the arrow


13


) after the cleaning blade


32


moves to the contact position and starts cleaning after the completion of ink supply, and the roller


10


is then stopped. As a result, after the roller is stopped, no ink


6


remains on the outer circumferential surface of the roller above the ink surface.




First Embodiment of Image Forming Apparatus





FIG. 7

shows an example in which the ink supply device


1


′ pertaining to the present invention is applied in an image forming apparatus


43


that uses a wet latent image. The image carrier


22


comprises a base, a photoisomerization layer (a layer that can reversibly change from hydrophilic to hydrophobic when irradiated with light, i.e., a layer having a material which reversibly changes the wettability of the image carrier) formed on the outer circumference of the base, and an overcoat layer formed on the outer circumference of the above layer for protection. Around the image carrier


22


is located an exposure device


45


, which is positioned upstream from the roller (developer roller)


10


in terms of the rotational direction


25


of the image carrier


22


, and which selectively irradiates the image carrier


22


with ultraviolet light


44


in accordance with image information and thereby forms a latent image on the image carrier


22


(the photoisomerization layer). Furthermore, downstream from the developer roller


10


in terms of the rotational direction


25


of the image carrier


22


are located, in the following order, a transfer roller


48


that transfers to the recording medium


46


the ink


6


that adhered to the image carrier


22


in the contact area


26


between the image carrier


22


and the developer roller


10


, a cleaning device (such as a cleaning blade, for example)


50


that removes the ink


6


remaining on the image carrier


22


after transfer, and a latent image eliminating device (such as an eraser lamp, for example)


52


that eliminates the latent image on the image carrier


22


by irradiating the image carrier


22


with visible light (erasing light) after transfer.




The transfer roller


48


also conveys the recording medium


46


in the direction of the arrow


54


by rotating in the direction of the arrow while holding the recording medium


46


, which has been supplied from a paper tray not shown in the drawing, between itself and the image carrier


22


. The recording medium


46


and the ink


6


adhering thereto are conveyed to a fusing means not shown in the drawing, through which the ink is dried and fused onto the recording medium


46


, and the recording medium


46


is then ejected onto an eject tray not shown in the drawing. The fusing means may be omitted if the ink


6


adheres sufficiently to the recording medium


46


.




The image forming operation of the image forming apparatus


43


having the above construction will now be explained. First, based on image information, the exposure device


45


selectively irradiates the image carrier


22


that is being rotated in the direction of the arrow


25


with light


44


. As a result, a latent image is formed on the image carrier


22


(the latent image areas are hydrophilic, while the other areas are hydrophobic). Subsequently, ink


6


selectively adheres to the latent image in the contact area


26


between the image carrier


22


and the developing roller


10


, whereupon an ink image is formed. This ink image moves to the area at which the image carrier


22


faces the transfer roller


48


as the image carrier


22


rotates, and is transferred onto the recording medium


46


.




The residual ink


6


that was not transferred to the recording medium


46


in the area at which the image carrier


22


faces the transfer roller


48


is removed by the cleaning device


50


. The latent image areas on the photoisomerization layer of the image carrier


22


are erased by the erasing light irradiated from the latent image eliminating device


52


(i.e., the entire photoisomerization layer returns to being hydrophobic).




Second Embodiment of Image Forming Apparatus





FIG. 8

shows an example in which the ink supply device


1


′ pertaining to the present invention is applied in an image forming apparatus


55


that uses a static latent image. This image forming apparatus


55


is very similar to the above image forming apparatus


43


, and only the differences will be explained below. The image carrier


22


′ of the image forming apparatus


55


is a photoconductive drum comprising a base, a charge generating layer and a charge transporting layer formed on the outer circumference of the base, and an overcoat layer (such as a 1-2 μm insulating film, for example) formed on the outer circumference of the charge generating and transporting layers in order to protect the lower layers and the escape of the latent image charge. Between the latent image eliminating device


52


and the exposure device


45


in terms of the rotational direction


25


of the image carrier


22


′ is located a corona charger device


56


to uniformly charge the surface of the image carrier


22


′.




The image forming operation of the image forming apparatus


55


having the above construction will now be explained. First, discharge by the corona charger device


56


is carried toward the image carrier


22


′, which is being rotated in the direction of the arrow


25


, in order to charge the surface of the image carrier


22


′. Light


44


is then selectively irradiated from the exposure device


45


based on image information. As a result, a latent image is formed on the image carrier


22


′. Ink


6


then selectively adheres to the latent image areas in the contact area


26


between the image carrier


22


′ and the developing roller


10


, whereupon an ink image is formed. This ink image moves to the area at which the image carrier


22


′ faces the transfer roller


48


as the image carrier


22


′ rotates, and is transferred onto the recording medium


46


.




The residual ink


6


that was not transferred to the recording medium


46


in the area at which the image carrier


22


′ faces the transfer roller


48


is removed by the cleaning device


50


. The latent image areas of the image carrier


22


′ are erased by the erasing light irradiated from the latent image eliminating device


52


.




Third Embodiment of Image Forming Apparatus





FIG. 9

shows an example in which the ink supply device


1


′ pertaining to the present invention is applied in another image forming apparatus


58


that uses a static latent image. This image forming apparatus


58


is very similar to the above image forming apparatus


43


, and only the differences will be explained below. The image carrier


22


″ comprises a roller-shaped or cylindrical (cylindrical in the drawing) base


57




a


made of metal such as aluminum, a ferroelectric layer


57




b


(such as PLZT, for example) formed on the outer circumference of the base, and an overcoat layer


57




c


(made of a fluoride material (PVDF/TeEF), for example) formed on the outer circumference of the ferroelectric layer. Between the latent image eliminating device


52


and the exposure device


45


in terms of the rotational direction


25


of the image carrier


22


″ is located a voltage applying device


60


that uniformly polarizes the ferroelectric layer


57




b


of the image carrier


22


″ (this process is called polling hereinbelow). In this embodiment, a heat lamp that eliminates the latent image in the ferroelectric layer


57




b


through heating is used as the latent image eliminating device


52


.




The voltage applying device


60


has a conductive roller


62


that rotates in the direction of the arrow as the image carrier


22


″ rotates while being in contact with the image carrier


22


″, and a bias power supply


64


. The bias power supply


64


applies a prescribed bias voltage (a voltage having a positive polarity in this embodiment) to the image carrier


22


″ via the conductive roller


62


. Although the base


57




a


of the image carrier


22


″ is grounded here, a bias voltage may be applied under other conditions as well. When a bias voltage is applied, the difference between the voltage from the bias power supply


64


and the voltage applied to the base


57




a


is applied to the ferroelectric layer


57




b


of the image carrier


22


″.




The image forming operation of the image forming apparatus


58


having the above construction will now be explained with reference to

FIGS. 9 and 10

. Polling of the ferroelectric layer


57




b


of the image carrier


22


″ that is being rotated in the direction of the arrow


25


is first performed via the voltage applying device


60


(FIG.


10


(A)). (In

FIG. 10

, the arrows in the ferroelectric layer


57




b


indicate that polarization is taking place in the areas corresponding to these arrows.) Subsequently, based on image information, the exposure device


45


selectively irradiates the ferroelectric layer


57




b


with light


44


(FIG.


10


(B)). The latent image areas irradiated by the light are heated beyond the Curie point and the polarization thereof is cancelled out (FIG.


10


(C)). In the transfer area


26


, ink


6


selectively adheres to the latent image areas (having a positive polarity) from which polarization was not eliminated, due to the gravitational force between the latent image and the oxygen atoms of the water molecules, whereupon an ink image is formed (FIG.


10


(D)). This ink image moves to the area at which the image carrier


22


″ faces the transfer roller


48


as the image carrier


22


″ rotates, and is transferred onto the recording medium


46


(FIG.


10


(E)).




The residual ink


6


that was not transferred onto the recording medium


46


in the area at which the image carrier


22


″ faces the transfer roller


48


is eliminated by the cleaning device


50


. The latent image area in the ferroelectric layer


57




b


of the image carrier


22


″ is heated beyond the Curie point by the latent image eliminating device


52


, and the polarization thereof is eliminated (FIG.


10


(F)).




As is well known to vendors knowledgeable in the art, various methods are available other than that used in the above embodiment in order to form a latent image in the ferroelectric layer. One example would be the method in which a voltage is applied to the ferroelectric layer after polling so that a latent image may be formed by reversing the polarization in some areas of the above layer.




As the ferroelectric material used in the ferroelectric layer


57




b


, either inorganic or organic materials may be used. Specifically, such inorganic materials as PLZT, SrBi


2


Ta


2


O


9


, PZT, BaTiO


3


, LiNbO


3


, PbTiO


3


, KNbO


3


, KTaO


3


, PbNb


2


O


6


, SrTiO


3


, LiTaO


3


, Sr


1-x


Ba


x


Nb


2


O


6


, Pb


1-x


La


x


Nb


2


O


6


, and BiNaTiO


6


, and such organic materials as co-polymer of vinylidene fluoride and tetrafluoroethylene, vinylidene polycyanade, co-polymer of vinylidene cyanade and vinyl acetate, polyvinylidene fluoride, and co-polymer of vinylidene fluoride and trifluoroethylene, may be used. It is also acceptable if a composite material comprising both an inorganic ferroelectric material and an organic ferroelectric material is used.




The overcoat layer


57




c


is used to control the durability and the ink wettability of the image carrier


22


″. For the material thereof, a material is preferred that has a desired insulating property that will increase the ability of the ferroelectric layer


57




b


to maintain polarization, as well as a high surface tension that brings about high ink wettability and friction resistance. For example, resins having these properties include epoxy resin, polyurethane resin, polyamide resin and polycarbonate resin, ceramics having these properties include Al


2


O


3


, SiC, and BaTiO


3


, and glass substances having these properties include element glass, hydrogen bond glass, chloride glass and fluoride glass.




The above ink supply devices and image forming apparatuses pertaining to the present invention may be used as the image forming unit in a copying machine (such as the Minolta EP-6000, for example) and/or a printer (such as Minolta ColorPagePro L, for example) that uses the electrophotographic method.




Using an ink supply device pertaining to the present invention, because gas exchange between the gas inside the developer container and the outside atmosphere is reduced, drying of the ink (i.e., loss of the liquid solvent) may be reduced. As a result, the thickness of the ink layer formed on the roller surface via the regulating blade, as well as the amount of ink transferred to the image carrier, become essentially uniform, so that high quality images that do not include unevenness in darkness or image failure may be obtained, and bleed-through may be prevented.




Although the present invention has been fully described by way of examples with reference to the accompanying drawings, it is to be noted that various changes and modifications will be apparent to those skilled in the art. Therefore, unless such changes and modification depart from the scope of the present invention, they should be construed as being included therein.



Claims
  • 1. A liquid supply device comprising:a container, the top part of which is open, for accommodating liquid therein; and a carrier arranged in the container so that a part of said carrier is submerged in the liquid accommodated in said container, said carrier having a continuous surface around a rotational axis and conveying the liquid to the open top part of the container by rotating around the rotational axis, wherein a part of said carrier is located outside the opening of the container, and wherein the following conditions are satisfied: A/(B+C)<1 D/B<1 whereA is the area of the opening of the container, B is the area of the liquid surface other than the part thereof in which the carrier is submerged, C is the area of the carrier surface above the liquid surface, and D is the area of the opening of the container from which the area of the part thereof taken up by the carrier is subtracted.
  • 2. A liquid supply device as claimed in claim 1, further comprising:a receiver for receiving the liquid from the carrier, wherein the liquid is supplied from the carrier to the receiver using one area of the above part of the carrier.
  • 3. A liquid supply device as claimed in claim 1, further comprising:a regulator for forming a uniform thin layer of liquid on the surface of the carrier, said regulator is located downstream from the part of the carrier submerged in the liquid in terms of the carrier rotational direction and is in contact with the carrier under a prescribed pressure.
  • 4. A liquid supply device as claimed in claim 1,wherein said liquid supply device is used in an image forming apparatus.
  • 5. A liquid supply device comprising:a container, the top part of which is open, for accommodating liquid therein; and a carrier arranged in the container so that a part of said carrier is submerged in the liquid accommodated in said container, said carrier having a continuous surface around a rotational axis and conveying the liquid to the open top part of the container by rotating around the rotational axis, wherein said carrier is located inside the container, and wherein the following condition is satisfied: A/B<1 whereA is the area of the opening of the container, and B is the area of the liquid surface other than the part thereof in which the carrier is submerged.
  • 6. A liquid supply device as claimed in claim 5, further comprising:a receiver for receiving the liquid from the carrier, wherein the receiver is located outside the container and the liquid material is supplied to the receiver from the carrier via the opening of the container.
  • 7. A liquid supply device as claimed in claim 5, further comprising:a regulator for forming a uniform thin layer of liquid on the surface of the carrier, said regulator is located downstream from the part of the carrier submerged in the liquid in terms of the carrier rotational direction and is in contact with the carrier under a prescribed pressure.
  • 8. A liquid supply device as claimed in claim 5,wherein said liquid supply device is used in an image forming apparatus.
  • 9. A liquid supply device comprising:a container, the top part of which is open, for accommodating liquid therein; a carrier arranged in the container so that a part of said carrier is submerged in the liquid accommodated in said container, said carrier having a continuous surface around a rotational axis and conveying the liquid to the open top part of the container by rotating around the rotational axis; and a receiver for receiving the liquid from the carrier, wherein the carrier is located inside the container while a part of the receiver is located inside the opening of the container, the liquid is supplied to the receiver from the carrier using an area of the above part of the receiver, and wherein the following condition is satisfied: D/B<0.3 whereD is the area of the opening of the container from which the area of the part thereof taken up by the receiver is subtracted, and B is the area of the liquid surface other than the part thereof in which the carrier is submerged.
  • 10. A liquid supply device as claimed in claim 9, further comprising:a regulator for forming a uniform thin layer of liquid on the surface of the carrier, said regulator is located downstream from the part of the carrier submerged in the liquid in terms of the carrier rotational direction and is in contact with the carrier under a prescribed pressure.
  • 11. A liquid supply device as claimed in claim 9,wherein said liquid supply device is used in an image forming apparatus.
Priority Claims (1)
Number Date Country Kind
2000-000793 Jan 2000 JP
US Referenced Citations (1)
Number Name Date Kind
4299902 Soma et al. Nov 1981 A
Foreign Referenced Citations (4)
Number Date Country
55-17161 Feb 1980 JP
10-24663 Jan 1998 JP
10-129102 May 1998 JP
10-235262 Sep 1998 JP