JPH08179632A - Wet-type image forming device - Google Patents

Abstract

PURPOSE: To achieve satisfactory cleaning with a special cleaning liquid and to prevent a leakage of the liquid out of a cleaning liquid tank, in a wet-type image forming device in which a transfer material is made to face in sequence a plurality of latent image carriers provided with a cleaner, etc. CONSTITUTION: The photoconductor 3 arranged further downstream in the direction where the transfer material is carried than the photoconductor which the transfer material faces first is provided with the cleaning liquid tank 31 for storing the cleaning liquid having the same constituent as the mother liquor of a liquid developer, cleaning liquid circulators 32, 33, and 35 for circulating the cleaning liquid between the tank and the cleaners 17, and liquid supply devices 36 and 49 for supplying the cleaning liquid to a liquid developer tank 44 from the tank. The liquid supply devices may be provided with devices 37 and 38 for removing the developer from the cleaning liquid.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wet image forming apparatus such as a copying machine, a facsimile and a printer, and more specifically, a plurality of latent image carriers and latent images forming latent images on the latent image carriers. Image forming means, a developing device provided corresponding to each latent image carrier to visualize the latent image using a developing solution, and a transfer material are conveyed so as to sequentially face the plurality of latent image carriers. It corresponds to a transfer device that transfers the visible image formed on each latent image carrier to the transfer material, and each latent image carrier that removes the developer remaining on the surface of the latent image carrier after the transfer of the visible image. The present invention relates to prevention of leakage from a cleaning liquid tank for a cleaning device in a wet image forming apparatus having a cleaning device provided therein.

[0002]

2. Description of the Related Art Conventionally, as a wet image forming apparatus of this type, a plurality of latent image carriers are provided, and each latent image carrier corresponds to
It has a latent image forming means, a developing device, and a cleaning device,
Further, there is also known a wet image forming apparatus having a transfer device that conveys the transfer material so as to sequentially face a plurality of latent image carriers to transfer a visible image formed on each latent image carrier to the transfer material. (See, for example, Japanese Patent Laid-Open No. 6-110288).

[0003]

SUMMARY OF THE INVENTION Here, the above-mentioned Japanese Patent Laid-Open No.
In a wet image forming apparatus having a plurality of cleaning devices as disclosed in Japanese Patent Application Laid-Open No. 110288, a cleaning liquid to be used for each cleaning device in order to perform good cleaning using a cleaning liquid dedicated to cleaning. It is conceivable to provide a cleaning liquid tank for storing the cleaning liquid and a cleaning liquid circulating device for circulating the cleaning liquid between the tank and the cleaning device. According to this, even when a foam roller is used in the cleaning device, it is possible to prevent toner accumulation in the roller portion.

However, according to this structure, the following problems may occur. That is, when the transfer material is sequentially conveyed to the plurality of latent image carriers to transfer the visible images formed on each latent image carrier to the transfer material, in the second and subsequent transfers in the transfer order. Since the transfer material on which the visible image has been transferred by the preceding transfer faces the latent image carrier, the developing solution forming the visible image transferred on the transfer material by the prior transfer is transferred to the latent image carrier. There is a risk that the latent image carrier is reversely transferred and adheres to the surface of the latent image carrier and is housed in a cleaning device for the latent image carrier. When the developer from the developing device for such another latent image bearing member is collected by the cleaning device, the amount of the cleaning liquid circulating in the cleaning liquid circulating system for the cleaning device increases by that amount, This leads to liquid leakage from the cleaning liquid tank of the cleaning liquid circulation system. In particular, when a transfer belt is used to convey the transfer material, the exposed portion of the transfer belt surface between the transfer materials comes into contact with the latent image carrier to attach the developer. Then, the adhered developer is reversely transferred to the latent image carrier for the subsequent transfer, so that the liquid leakage from the cleaning liquid tank is more likely to occur.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a plurality of latent image bearing members, and a latent image forming means and a developing device corresponding to each latent image bearing member. ,
Having a cleaning device and a developer tank, the transfer material is conveyed so as to sequentially face a plurality of latent image carriers, and the visible image formed on each latent image carrier is transferred to the transfer material. A wet type image forming apparatus having a transfer device capable of cleaning a latent image bearing member by using a dedicated cleaning liquid and preventing the liquid from leaking from a cleaning liquid tank that stores the cleaning liquid. A wet image forming apparatus is provided.

In JP-A-62-20979, a latent image carrier, a latent image forming means for forming a latent image on the latent image carrier, and the latent image are visualized by using a developing solution. A developing device for forming an image, a transfer device for transferring the visible image formed on the latent image carrier to a transfer material, and a cleaning device for removing the developer remaining on the surface of the latent image carrier after the visible image transfer. A wet image forming apparatus having the following: a cleaning liquid tank for storing a cleaning liquid used in the cleaning device; a cleaning liquid circulating device for circulating the cleaning liquid between the cleaning liquid tank and the cleaning device; There is disclosed one having a toner collecting means for collecting the toner in the cleaning liquid by electrodeposition and discharging the toner into the collecting container. This toner collecting means collects the toner in the cleaning liquid by electrodeposition and discharges it into the collecting container because the toner removed from the latent image carrier by the cleaning device is mixed in the cleaning liquid to increase its concentration. It is said that it is for the purpose of limiting or preventing the movement of the toner and preventing the cleaning failure due to insufficient redispersion of the residual toner on the latent image carrier in the cleaning device by the cleaning liquid. Further, in this publication, there is no suggestion of the above-mentioned problems peculiar to the wet image forming apparatus using a plurality of latent image carriers, which is the premise of the present invention.

[0007]

In order to achieve the above object, a wet image forming apparatus according to a first aspect of the present invention comprises a plurality of latent image bearing members and a latent image forming a latent image on each latent image bearing member. Forming means, a developing device provided corresponding to each latent image carrier to visualize the latent image by using a developing solution, and a transfer material are conveyed so as to sequentially face the plurality of latent image carriers. Corresponding to a transfer device that transfers the visible image formed on each latent image carrier to the transfer material, and each latent image carrier that removes the developer remaining on the surface of the latent image carrier after the visible image transfer. In a wet-type image forming apparatus having a cleaning device provided, the latent image carrier disposed downstream of the latent image carrier facing the first transfer medium by the transfer device in the transfer material conveyance direction is subjected to the development. Developer tank that stores the developer used in the cleaning device and the cleaning tank used in the above cleaning device. A cleaning liquid tank that stores a cleaning liquid, a cleaning liquid circulation device that circulates the cleaning liquid between the cleaning liquid tank and the cleaning device, and a liquid that supplies the cleaning liquid from the cleaning liquid tank to the developing liquid tank. A supply device is provided.

A wet image forming apparatus according to a second aspect is the first aspect.
In the wet image forming apparatus, the removing device for removing the developer from the cleaning liquid supplied to the developing liquid tank by the liquid supplying device is provided.

A wet image forming apparatus according to a third aspect is the second aspect.
In the wet image forming apparatus, the removing device is configured by using an electrode member for adsorbing the charged developer and separating it from the cleaning liquid.

A wet image forming apparatus according to a fourth aspect is the third aspect.
In the wet image forming apparatus, the removing device is provided with a liquid reservoir around the electrode member for temporarily retaining the cleaning liquid supplied from the cleaning liquid tank to the developing liquid tank. .

A wet image forming apparatus according to a fifth aspect is the third aspect.
In the wet image forming apparatus, the removing device is configured to drive the electrode member so that the surface moves along an endless path including a portion released from the cleaning liquid surface in the liquid reservoir, and An electrode cleaning liquid removing device that removes the cleaning liquid carried together with the developer from the surface of the electrode member facing the surface of the electrode member that moves along the endless path portion removed from the cleaning liquid surface; An electrode developer removing device for removing the developer from the surface is provided on the downstream side of the surface moving direction.

A wet image forming apparatus according to a sixth aspect is the fifth aspect.
In the wet image forming apparatus, the electrode cleaning liquid removing member is driven so that the surface of the cleaning liquid removing member moves along an endless path including a portion facing the surface of the electrode member. The apparatus is characterized by comprising a scraper for removing the cleaning liquid from the surface of the cleaning liquid removing member.

A wet image forming apparatus according to a seventh aspect is the fifth aspect.
In the wet image forming apparatus, the electrode cleaning liquid removing device is configured by using an air ejector that blows air onto the surface of the electrode member to remove the cleaning liquid.

A wet image forming apparatus according to an eighth aspect is the second aspect.
In the wet image forming apparatus, the overflow port is formed in the cleaning liquid tank, and the overflow port and the developing solution tank are connected by a liquid path pipe or the like to configure the liquid supply device to supply energy from the outside. A device capable of receiving the developer and performing an operation of removing the developer is used as the removing device, and during a period in which the cleaning liquid may overflow from the overflow port,
The drive control is set so as to operate the removing device.

A wet image forming apparatus according to a ninth aspect is the second aspect.
In the wet image forming apparatus, the overflow port is formed in the cleaning liquid tank, and the overflow port and the developing solution tank are connected by a liquid path pipe or the like to configure the liquid supply device to supply energy from the outside. A device capable of receiving the developer and performing an operation of removing the developer is used as the removing device, and it is detected whether the amount of the cleaning liquid in the cleaning liquid tank has reached the amount overflowing from the overflow port. The liquid amount detecting means and the control means for controlling the operation of the removing device based on the detection result of the liquid amount detecting means are provided.

A wet image forming apparatus according to a tenth aspect of the present invention is the wet image forming apparatus according to the second aspect, in which the developer used for another latent image carrier mixed in the cleaning liquid circulating system by the cleaning liquid circulating device. The mixed developer detecting means for detecting the developer is also provided.

A wet image forming apparatus according to an eleventh aspect of the present invention is the wet image forming apparatus according to the tenth aspect, wherein a device capable of removing the developer by receiving energy supply from the outside is used as the removing device. It is characterized in that a control means for controlling the operation of the removing device is provided based on the detection result of the mixed developer detecting means.

A wet image forming apparatus according to a twelfth aspect of the present invention is the wet image forming apparatus according to the tenth aspect, wherein an overflow port is formed in the cleaning liquid tank, and the overflow port and the developing solution tank are formed by a liquid passage pipe or the like. A device that communicates with the liquid supply device to perform an operation of removing the developer by receiving energy supply from the outside is used as the removing device, and the amount of the cleaning liquid in the cleaning liquid tank is Liquid amount detecting means for detecting whether or not the amount overflowed from the overflow port is reached, and control for controlling the operation of the removing device based on the detection results by the liquid amount detecting means and the mixed developer detecting means. Means and means are provided.

A wet image forming apparatus according to a thirteenth aspect of the present invention is the wet image forming apparatus according to the tenth aspect, in which only the latent image carrier other than the latent image carrier which the transfer material first opposes is in the cleaning liquid circulation system. The mixed developer detecting means for detecting the developer of the developer used for the latent image carrier on the upstream side of the latent image carrier mixed with the latent image carrier, and the removing device are provided. It is characterized by that.

[0020]

In the wet image forming apparatus according to any one of claims 1 to 13, while the transfer material is conveyed by the transfer device to sequentially face the latent image carriers, the visible images formed on the latent image carriers are formed. , Transfer to the transfer material. During this transfer, the latent image carrier arranged on the upstream side in the transfer material conveying direction is arranged on the latent image carrier arranged on the downstream side in the transfer material conveying direction with respect to the latent image carrier which the transfer material first opposes. The transfer material on which the visible image is transferred from the body faces each other, and a part of the developer forming the visible image is attached.
The adhered developer is a developer that forms a visible image formed by a developing device provided corresponding to the latent image carrier and is not transferred to the transfer material, as well as the latent image carrier. Is removed from the surface of the latent image carrier by a cleaning device provided corresponding to. In this way, the developer removed from the surface of the latent image carrier is circulated by the cleaning circulation device between the cleaning device and the cleaning liquid tank for storing the cleaning liquid used in the cleaning device. Taken in,
The amount of liquid stored in the cleaning liquid tank increases. The increased amount of the liquid is supplied by the liquid supply device to the developer tank for storing the developer used in the developing device to prevent the liquid from overflowing from the cleaning tank.

Particularly, in the wet image forming apparatus according to the second aspect, the removing device removes the developer from the cleaning liquid supplied to the developing solution tank by the liquid supplying device. As a result, the developer from the developing device provided corresponding to the latent image carrier arranged on the upstream side in the transfer material conveying direction is prevented from entering the developer tank.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which the present invention is applied to an electrophotographic wet color image forming apparatus which is a wet image forming apparatus will be described below. FIG. 1 is a schematic configuration diagram thereof. First, the outline of the entire apparatus will be described with reference to FIG. This apparatus is provided with photoconductors 1, 2, 3 and 4 as a plurality of latent image carriers that form images of different print colors. The photoconductor 1 is for black (Bk), the photoconductor 2 is for cyan (C), the photoconductor 3 is for magenta (M), and the photoconductor 4 is for yellow (Y). The axes of these photoconductors are arranged in the same plane in the vertical direction. Furthermore,
A transfer belt 7 that is in contact with the outer periphery of the photoconductor is wound around the drive roller 5 and the driven roller 6 that are rotatably held at a predetermined interval in the same plane in the vertical direction. There is. The transfer belt 7 is an endless belt that is formed of a dielectric material such as polyethylene terephthalate, is polarized by the transfer charger 8, and attracts the transfer paper by electrostatic action. A plurality of transfer chargers 8 are provided, and are arranged to face the photoconductor with the transfer belt 7 in between.

On the right side of the photoconductors 1 to 4, there is provided a vertically long exposure device (not shown). As this exposure device, an optical signal corresponding to image information color-separated by a scanner or the like is emitted from a semiconductor laser, and the laser light is scanned on a photosensitive member by a polygon mirror that is rotationally driven. A lens provided with a lens for converging and for correcting the surface tilt of the polygon mirror, a mirror for deflecting laser light, or the like can be used.

Further, on the outer periphery of each of the photoconductors,
A charging charger 15, a wet developing unit 16, a cleaning device 17, and a charge eliminating lamp 18 are provided. If the axis of the photoconductor is taken as the coordinate origin, the charger 1
5, the cleaning device 17 and the charge eliminating lamp 18 are arranged in the first quadrant, and the developing section 16 is arranged in the third and fourth quadrants. As shown in FIG. 2, each developing unit 16 has a casing 19 having an upper surface opening to which a developing solution in which toner is dispersed in a solvent as a carrying solution is supplied, a developing roller 20 provided in the casing 19, and Reverse roller 20a
And a developer tank for storing the developer used in the casing 19. A pump for pumping up the developer into the casing 19 through the developer supply pipe is provided in the developer tank, and the lower end of the casing is for collecting the developer from the casing into the developer tank. Is provided with a developer collecting pipe. This pump,
A developer circulating device is constituted by the developer supply pipe and the developer recovery pipe. The cleaning device including the cleaning device 17 and the cleaning liquid tank for storing the cleaning liquid used in the cleaning device 17, which are the features of the apparatus of this embodiment, will be described in detail later.

Further, below the photoconductor 1 located at the lowest position, a paper feed roller 23 for intermittently pulling out the transfer paper 22 stored in the paper feed cassette 21 one by one, and a paper feed path 24.
A registration roller 25 that sends the transfer paper 22 guided to the transfer belt 7 to the transfer belt 7 is provided. A container 26 to which the cleaning liquid is supplied is provided near the driven roller 6, and the container 26 is provided with a foam roller 27 and a cleaning blade 28 that come into contact with the transfer belt 7. Further, a fixing roller 29 and a press roller 30 are rotatably provided in contact with each other above the driving roller 5, and the transfer paper 22 passing through the fixing roller 29 is transferred.
A paper discharge roller 32 that discharges the paper to the paper discharge tray 31 is provided.

In such a structure, images having different printing colors are formed on the respective photoconductors 1 to 4. Here, the image forming process for the photoconductor 1 located at the lowest position will be described, but the image forming process for the other photoconductors 2, 3 and 4 will not be described because of the same principle. First, the photosensitive member 1 is uniformly charged by the electric charge from the charging charger 15 during rotation. The exposure device is driven based on the image information separated into the black print color,
As a result, an electrostatic latent image is formed on the charged portion of the photoconductor 1. This electrostatic latent image is developed by the developing unit 16. (Hereinafter, margin)

On the other hand, the transfer paper 22 pulled out by the paper feed roller 23 is kept in a standby state with its leading end in contact with the nip portion of the registration roller 25, and rotates in synchronization with the rotational movement of the photoconductor 1. The registration roller 25 and the driving roller 5 convey the recording material to a transfer position facing the photoconductor 1.
Then, the developed image on the photoconductor 1 is transferred to the transfer paper 22. According to the same principle, an image separated into the cyan print color is formed on the photoconductor 2 and transferred to the transfer paper 22, and then an image separated into the magenta print color is formed on the photoconductor 3. The transferred image is transferred onto the transfer paper 22, and then transferred onto the transfer paper 22. Then, the image separated into the print color of yellow is formed on the photoconductor and transferred onto the transfer paper 22. Thus, a color image is obtained. At this time, the transfer voltage to the transfer charger 8 corresponding to each of the photoconductors 1 to 4 is gradually increased according to the order of transfer so that both powder transfer is performed. The transfer paper 22 onto which the images have been transferred is fixed while the transfer image is fixed in the process of being separated from the transfer belt 7 and conveyed by the fixing roller 29 and the press roller 30, and is ejected to the paper ejection tray 31 by the paper ejection roller 32. To be paper. Further, the developer adhered to the transfer belt 7 is removed by the foam roller 27 and the cleaning blade 28 each time the transfer is performed.

Next, the cleaning device in this embodiment will be described. The cleaning device is the photoconductor 1.
4 to 4 facing each other, a cleaning liquid tank 31 for storing the cleaning liquid 42 used in the cleaning device 17, and a circulation of the cleaning liquid 42 between the cleaning liquid tank 31 and the cleaning device 17. And a circulation device. In Figure 1,
Of these, regarding the cleaning liquid tank 31 and the circulation device, only the cleaning device for the magenta photoconductor 3 is shown, but the same applies to the photoconductors 2 and 4 other than the most upstream photoconductor 1 in the transfer material conveyance direction. Is adopted. The cleaning liquid tank 31 and the circulation device for the most upstream photoconductor 1 in the transfer material conveyance direction may adopt a structure different from that for the other photoconductors 2, 3, and 4. This point will be mentioned later.

FIG. 2 is an enlarged view showing the entire cleaning device for the magenta photoconductor 3. The cleaning device 17 includes a casing, a cleaning roller 34 attached to the apparatus main body via a bracket, a cleaning blade 48, a diaphragm roller 46 for the cleaning roller, a cleaning liquid diffusion plate 47, and a cleaning supply nozzle 45. Has become. The cleaning roller 34 is a roller made of an elastic material having a liquid supply property, for example, sponge rubber, and is rotationally driven by a drive mechanism (not shown). The cleaning blade 48 is made of rubber or the like. During the cleaning operation, the blade has its free end pressed against the surface of the photoconductor, and the cleaning roller 34 has its peripheral surface pressed against the surface of the photoconductor to be elastically deformed. The squeezing roller 46 squeezes the cleaning liquid 42 sucked by the cleaning roller 34. A cleaning liquid supply pipe 33 is connected to the cleaning liquid supply nozzle 45. Below the nozzle 45, a diffusion plate 47 for diffusing the cleaning liquid 42 supplied from the nozzle in the longitudinal direction of the cleaning roller 34 is arranged. A recovery port for recovering the cleaning liquid 42 supplied to the casing is provided at the lower end of the casing. One end of a cleaning liquid recovery pipe 35, the other end of which is positioned above the cleaning liquid tank 31, is connected to the recovery port.

The cleaning liquid tank 31 stores a cleaning liquid 42 having the same composition as the solvent as the carrier liquid. The tank 31 is provided with a pumping pump 32, and the lower end of the cleaning liquid supply pipe 33 is connected to the pump 32. This pump 3
2, the cleaning liquid supply pipe 33, and the cleaning liquid recovery pipe 35 constitute a cleaning liquid circulation device.

In this cleaning device, the cleaning liquid tank 31 is provided with an overflow port 31a, and the overflow port 31a and the developing solution tank 4 are provided.
4 has been contacted. Specifically, one end of an overflow pipe 36 having an electromagnetic valve 36a is connected to the overflow port 31a. On the other end side of this pipe, a gutter-shaped portion is formed which forms a liquid storage portion 49 for temporarily retaining the cleaning liquid 42 from the overflow port 31a, and the end portion of the gutter-shaped portion is located above the developer tank 44. And the cleaning liquid 42 falling from the end is supplied into the developer tank 44. In the liquid reservoir 49, the cleaning liquid 4 temporarily stored here
An electrode roller 37 is provided so that the top is exposed from the liquid surface of No. 2, and is driven to rotate counterclockwise by a driving unit (not shown). Also, the electrode roller 3
A power source 38 for applying a voltage for adsorbing the toner collected from the photoconductor by the cleaning device 17 and taken into the cleaning liquid is connected to the device 7. A toner collecting blade (scraper) 37 is provided so as to come into contact with the top surface of the electrode roller 37, and the toner electrodeposited on the electrode roller 37 is scraped off by the blade. A collection container 40 for receiving the scraped toner is provided. The liquid reservoir 49 is formed so as to increase the contact time between the overflowing cleaning liquid 42 and the electrode roller 37 to enhance the electrodeposition effect.

In the configuration of the above cleaning device,
When the cleaning operation is not performed, the pumping pump 32 in the cleaning liquid tank 31 is stopped, and the cleaning liquid level in the cleaning liquid tank 31 in this state is completely cleaned by the cleaning liquid 42 in the cleaning liquid circulation system. It is the highest liquid level (hereinafter, referred to as “stopped liquid level”) A concentrated in the liquid tank 31. When the pumping pump 32 is started to start the cleaning operation, the cleaning liquid 42 in the cleaning liquid tank 31 is pumped up to the cleaning device 17 side, and the liquid level in the tank is lowered. After that, the cleaning liquid 42 starts to return from the cleaning device 17 side into the cleaning liquid tank 31, the amount of liquid existing in the cleaning device 17 and each liquid pipe becomes stable, and the liquid returning from the cleaning device 17 side into the cleaning liquid tank 31. The stable cleaning liquid 42 at the time when the amount becomes the same as the amount of liquid taken out from the tank 31 by the pumping pump 32 (the liquid level at this time is shown as liquid level C in the figure).
The circulation of is started. After the stable circulation of the cleaning liquid, if the total amount of the cleaning liquid 42 in the circulation system does not change, this liquid level (hereinafter, referred to as the minimum liquid level) C is maintained during the stable liquid circulation. .

The lower end of the overflow port 31a of the cleaning liquid tank 31 has the lowest liquid level C.
Is formed so as to substantially coincide with the above (in the example shown, the liquid level B is slightly higher than the lowest liquid level C). Therefore, the carver flow does not occur during stable liquid circulation without changing the total amount of the cleaning liquid 42 in the circulation system. Since the position of the overflow port 31a is set as described above, the electromagnetic valve 36a is provided in the overflow pipe 36, the pumping pump 32 is stopped, and the cleaning liquid tank 31 is supplied from the start of the pump driving. When the electromagnetic valve 36a is in the closed state for a period until it becomes lower than the lower end position of the carver flow port due to the lowering of the liquid level, then the liquid level becomes lower than the lower end position of the carver flow port. From the solenoid valve 36a until the drive of the pump is stopped.
The solenoid valve 36a is controlled by a control unit (not shown) so that the solenoid valve 36a is opened.

As described above, the overflow pipe 3
6, the solenoid valve 36a is opened to allow the liquid to flow out of the cleaning liquid tank 31 through the overflow port 31a, while the pumping pump 32 is driven to circulate the cleaning liquid 42 in a stable manner. 17
To clean the photoconductor. This cleaning device 1
In FIG. 7, the untransferred toner remaining on the surface of the photoconductor after transfer is scraped from the surface of the photoconductor by the cleaning blade 48 after the adhesion position is disturbed by the cleaning roller 34. The developer containing the scraped toner is cleaned together with the cleaning liquid 42 and the cleaning roller 3
4 is absorbed and carried away from the surface of the photoconductor. The cleaning liquid 42 containing the toner absorbed by the cleaning roller 34 is squeezed by the squeeze roller 46,
It is returned to the cleaning liquid tank 31 through the recovery port of the casing and the cleaning liquid recovery pipe 35.

As described above, the total amount of the liquid in the cleaning liquid circulation system is increased by the amount of the developer (toner solids and solvent) containing the toner collected from the photoconductor by the cleaning device 17, so that the liquid in the cleaning liquid tank 31 is increased. The position rises and the overflow from the overflow port 31a starts. In particular, as in this embodiment, a plurality of photoconductors 1, 2,
When the transfer paper is conveyed so as to sequentially face 3 and 4, the toner from the developing device provided corresponding to the photoconductor on the upstream side in the transfer paper conveyance direction is also collected by the cleaning device as described above. The rise of the liquid level in the cleaning liquid tank 31 is remarkable. The cleaning liquid 42 containing the overflowed toner passes through the liquid pool portion and the developing liquid tank 4
4 is supplied by dropping. In this liquid reservoir, the power source 38
Thus, the toner in the cleaning liquid is adsorbed by the electrode roller 37 that is driven to rotate while a voltage is applied so that the toner can be attracted, and is collected from the electrode roller 37 by the toner collecting blade 39 into the collecting container 40. Therefore, only the solvent component after the toner is removed is supplied to the developer tank 44. The voltage application to the electrode roller 37 and the rotational drive thereof are controlled by a control unit (not shown) in conjunction with the opening and closing of the solenoid valve 36a so as to be performed during a period in which an overflow may occur via the overflow port 31a. Instead of interlocking with the opening and closing of the electromagnetic valve 36a as described above, the electrode roller 37 may be always operated during the operation of the cleaning device or the operation of the device.

According to the above embodiment, the cleaning liquid tank 31 is provided with the overflow port 31a, and the cleaning liquid 42 overflowing from the overflow port 31a is collected.
4, the leakage of the cleaning liquid 42 from the cleaning liquid tank 31 can be prevented without providing a special container for accommodating the overflowing cleaning liquid 42. Further, since the toner is removed from the cleaning liquid supplied to the developing solution tank 44 by the electrode roller 37 provided in the liquid path between the overflow port 31a and the developing solution tank 44, as described above. Even if toner of another color on the transfer belt 7 or the other photoconductor adhered to the transfer paper is mixed in the cleaning liquid tank 31, it is not mixed in the developing liquid tank 44. Therefore, it is possible to prevent the color shift of the image due to the color mixture in the developer tank 44.

In the apparatus of the above embodiment, the solenoid valve 3 is operated so that the voltage application and the rotational drive to the electrode roller 37 are operated during the period when there is a possibility of overflow.
6a is interlocked with the opening and closing of 6a, but instead of this, as shown in FIG. 2, a liquid level sensor for detecting whether or not the liquid level in the cleaning liquid tank 31 has risen to the position facing the lower end of the overflow port 31a. 41 may be provided to detect whether or not the electrode actually overflows, and only when the electrode overflows, the electrode roller 37 may be operated.
Further, the opening / closing of the solenoid valve 36a may be controlled using a signal from the sensor. Further, a sensor is provided in the overflow path to detect whether or not the overflow has actually occurred, and the signal from the sensor is used to detect the electrode roller 37.
The operation of may be controlled. According to these, the electrode roller 37 can be operated only when it is really needed, so that it is possible to avoid shortening the service life of components such as the electrode roller 37 and wasteful consumption of energy due to unnecessary operation.

Further, the electrode roller 37 is not operated during the period in which the overflow may occur or the carver flow is performed, and the electrode roller 37 is operated only when toner of another color is mixed. You may make it operate. To this end, for example, as shown in FIG. 2, a sensor 43 is provided in the cleaning liquid tank 31 to detect whether or not toner of another color is mixed, and the sensor 43 is used for a signal from now on. The electrode roller 37 is controlled so as to operate only when the level is equal to or higher than a predetermined level (for example, the level at which the color difference of the image starts to be influenced by the color mixture in the developer tank 44). As such a sensor 43, an optical sensor mainly having sensitivity to toners of other colors can be used. Such an electrode roller 3
In the operation control of No. 7, as shown in FIG. 3, for example, the relationship between the sensor output and the color mixing level (color mixing rate on the vertical axis) is previously obtained by an experiment, and the sensor output a corresponding to the predetermined color mixing level A is obtained. Can be used as a comparison value or the like. When the electrode roller 37 is operated only when the toner of another color is mixed as described above, the toner of its own color is supplied to the developer tank 44 while being contained in the cleaning liquid 42. However, since the developer tank 44 originally contains the toner of its own color, there is no particular problem with respect to entry into the developer tank 44.

Further, the sensor 43 for detecting the degree of mixing of the toner and the sensor for detecting whether or not the overflowing liquid amount has been reached are used together, and the carver flow can actually occur, and The electrode roller 37 may be operated only when the mixing degree of the toner is equal to or higher than a predetermined level.

With respect to the cleaning device for the photoconductor 1 which the transfer paper 22 first opposes, since the photoconductor 1 is the first opposition partner of the transfer paper 22, the toner of the other color is transferred via the transfer paper. There is no fear of color mixing. Moreover, in the apparatus of the above-described embodiment, the surface portion of the transfer belt 7 after the transfer paper is separated is covered with the foam roller 27 and the cleaning blade 28.
Since the cleaning is performed by, there is no fear that other color toners may be mixed in via the transfer belt 7. Therefore, this photoconductor 1
In order to prevent the color mixture of toners of other colors, the cleaning device of FIG.
It is not necessary to form 9 or provide the electrode roller 37. Therefore, it is not necessary to control the operation of the electrode roller 37 using the sensor 43 or the like that detects the degree of toner mixing.

On the other hand, in the cleaning device for the photoconductors 2 to 4 for the second and subsequent transfers, toner from the photoconductor for the preceding transfer may be mixed in via the transfer paper 22 and the transfer belt 7. Therefore, it is desirable to configure the sensor 43 that detects the mixing degree of the toner so that all of the toner from the preceding photoconductor can be detected. Specifically, for the cleaning device for the second photoconductor 2, black toner is used for the cleaning device for the third photoconductor 3, black toner and cyan toner for the cleaning device for the third photoconductor 3, and black toner for the cleaning device for the fourth photoconductor 4.
The cyan toner and the magenta toner are respectively configured to be detected. Here, for the third and subsequent cleaning devices that need to detect mixed color toners of two or more colors, a single sensor that can detect mixed color toners of two or more colors may be used, or a dedicated sensor for each color may be used. Two or more may be provided. According to the research conducted by the present inventors, unlike the apparatus of the above-described embodiment, the transfer order of each color is set to yellow, magenta,
It was found that the detection accuracy of the above-described color mixture is improved when cyan and black are sequentially arranged. Therefore, it is desirable to set such a transfer order.

In the apparatus of the above embodiment, the electrode roller 37 which is driven to rotate is used to remove the toner from the overflowing cleaning liquid 42.
Instead of this, for example, an electrode belt 50 that is rotationally driven as shown in FIG. 4 may be used. According to this, by setting the shape of the liquid pool and the surface movement path of the electrode belt 50,
The contact time between the cleaning liquid 42 and the electrode surface can be lengthened relatively easily. Further, it is possible to increase the degree of freedom in selecting the installation location of the toner recovery blade 39 and the like.

The electrode roller 37 and the electrode belt 5 are also provided.
Since not only the solid content of the toner but also the solvent content adheres to the surface of No. 0, the liquid adhering to the surface of the roller or the like that has been removed from the liquid in the liquid pool by the rotation of the roller or the like is directly used for the toner recovery blade. Collection container 40 by scraping with 39
When it is recovered, the solvent component is also recovered. This leads to an increase in maintenance load on the recovery container 40 and wasteful consumption of the solvent. In order to avoid such a problem, for example, as shown in FIG. 5A or 5B, the solvent content is removed from the surface upstream of the toner collecting blade 39 in the surface moving direction of the electrode roller 37. A mechanism is provided. Here, the solvent content removing device in FIG. 5A is a squeeze roller used as a device for removing excess developer on the photoconductor in a wet developing device, and the electrode roller 37 and the squeeze roller 51 are approximately the same. 30 to 100
They are opposed to each other with a gap of about μm, preferably about 50 μm, and are rotationally driven so that the surfaces move oppositely at the opposed parts (the rotation speed is preferably higher than that of the electrode roller 37). Further, in order to scrape off the solvent component from the surface of the squeeze roller 51, a blade 52 that comes into contact with the surface is also provided. Further, FIG. 5 (b) shows a case in which an air knife known as an excessive developing solution removing device in a wet developing device is diverted, and the solvent content on the surface of the electrode roller 37 is removed by the air from the air knife 53. You can By providing such a solvent removal device, the amount of solvent recovered in the recovery container 40 by the toner recovery blade 39 can be significantly reduced.

Further, FIGS. 6A and 6B show an example in which the solvent removal device having the squeeze roller 51 is provided on the electrode belt 50, and FIG. FIG. 1B is a partial plan view of the electrode belt 50. In this example, holes 50a are formed at both ends in the width direction of the electrode belt 50 so as to be arranged at a predetermined interval.
A protrusion for driving transmission that enters the hole is formed on the peripheral surface of the belt driving roller. This is to enable the belt to be stably driven even when the toner wraps around to the back surface of the electrode belt 50 and the solid content of the toner sticks to the back surface of the belt and the belt driving load increases.

[0045]

According to the wet image forming apparatus of the first to thirteenth aspects of the invention, the transfer material corresponds to the latent image carrier disposed on the downstream side in the transfer material transport direction with respect to the latent image carrier which first opposes. The increased amount of liquid stored in the cleaning liquid tank that stores the cleaning liquid used in the cleaning device installed in the cleaning device is supplied by the liquid supply device to the developing liquid tank that stores the developing liquid used in the developing device. Therefore, there is an excellent effect that the liquid can be prevented from overflowing from the cleaning liquid tank.

In particular, in the wet image forming apparatus of the second aspect, since the removing device removes the developer from the cleaning liquid supplied to the developing solution tank by the liquid supplying device, it is located upstream in the transfer material conveying direction. It is possible to prevent the developer from the developing device provided corresponding to the arranged latent image carrier from entering the developer tank. Therefore, even when a color image forming apparatus is configured by using developers having different colors as the developers used in the developing devices provided corresponding to the respective latent image carriers, due to the color mixture in the developer tank, Image color shift can be prevented.

Further, according to the wet image forming apparatus of the third aspect, since the charged developer is adsorbed and separated from the cleaning liquid by using the electrode member, the developer can be efficiently separated from the cleaning liquid. .

According to the wet type image forming apparatus of the fourth aspect, the cleaning liquid supplied from the cleaning liquid tank to the developing liquid tank can be temporarily retained in the liquid reservoir provided around the electrode member. Therefore, the contact time of the cleaning liquid with the electrode member can be made relatively long, and the separability of the developer by electrodeposition can be improved.

Further, according to the wet image forming apparatus of the fifth to seventh aspects, the electrodeposited developer on the surface of the electrode member is removed by the electrode developer removing apparatus prior to the electrodeposition. Since the cleaning liquid carried on the surface together with the developed developer is removed by the electrode cleaning liquid removing device from the surface portion of the electrode member that has escaped from the cleaning liquid surface in the liquid reservoir, It is possible to reduce the amount of the cleaning liquid removed from the surface by the electrode developer removing device together with the electrodeposited developer. Therefore, useless consumption of the cleaning liquid can be reduced.

According to the wet type image forming apparatus of the eighth aspect, the cleaning liquid may overflow from the overflow port of the cleaning liquid tank constituting the liquid supply device together with the liquid passage pipe communicating with the developing liquid tank. During a certain period, since the removing device is driven and controlled so as to operate the removing device which is a device capable of removing the developer by receiving energy supply from the outside, it overflows from the cleaning liquid tank. The developer can be reliably separated from the cleaning liquid supplied to the developer tank.

According to the ninth aspect of the wet image forming apparatus, the amount of the cleaning liquid in the cleaning liquid tank is the same as that of the cleaning liquid tank constituting the liquid supply device together with the liquid passage pipe communicating with the developing liquid tank. The liquid amount detecting means detects whether or not the amount of overflow from the overflow port is reached, and when the amount of liquid reaches the amount of overflow from the overflow port, the removal device is controlled so as to operate. The removal device can be activated only when the cleaning liquid actually overflows from the overflow port. Therefore, it is possible to prevent deterioration of constituent parts of the removing device and wasteful consumption of energy due to useless operation of the removing device.

According to the wet image forming apparatus of the tenth aspect,
Whether the developer of the developer used for the other latent image carrier is mixed in the cleaning liquid circulation system by the cleaning liquid circulation device by the mixed developer detecting means, or the mixing degree of the developer. Therefore, based on the detection result, it is possible to control the removal device to operate, for example, only when there is a possibility that a problem may occur due to the mixing of the developer. Therefore,
For example, it is possible to prevent deterioration of the components of the removing device and unnecessary consumption of energy due to useless operation of the removing device.

According to the wet type image forming apparatus of claim 11,
Based on the detection result by the mixed developer detecting means, the operation of the removing device, which is a device capable of removing the developer by receiving energy supply from the outside, is controlled. It is possible to prevent deterioration of constituent parts of the removing device and wasteful consumption of energy due to operation.

According to the wet type image forming apparatus of claim 12,
Based on the detection result of the liquid amount detection means for detecting whether or not the amount overflowed from the overflow port is reached and the detection result by the mixed developer detection means, the developer is supplied with energy from the outside. Since the operation of the removing device, which is composed of a device that can perform the operation of removing the cleaning liquid, is controlled, the cleaning liquid actually overflows from the overflow port, and only when there is a possibility that a trouble due to mixing of the developer may occur The removal device can be activated. Therefore, it is possible to better prevent deterioration of the components of the removing device and waste of energy due to useless operation of the removing device.

According to the wet image forming apparatus of the thirteenth aspect,
There is no risk that the developer of the developer used for the other latent image carrier will be mixed, only for the latent image carrier other than the latent image carrier that the transfer material first opposes, the mixed developer detecting means, Since the removing device is provided, compared to the case where the mixed developer detecting means and the removing device are provided so as to correspond to the latent image carrier which the transfer material first faces. Miniaturization and increase in the number of equipment can be suppressed.

[Brief description of drawings]

FIG. 1 is a front view showing a schematic configuration of a wet image forming apparatus according to an embodiment.

FIG. 2 is an explanatory diagram of a cleaning device having the same image forming phase value.

FIG. 3 is a characteristic diagram of a sensor provided in the cleaning device.

FIG. 4 is an explanatory diagram of a cleaning device according to a modified example.

5A and 5B are explanatory views of a part of a cleaning device according to a modified example.

6A and 6B are explanatory views of a part of a cleaning device according to another modification.

[Explanation of symbols]

 17 Cleaning Device 19 Developing Device 31 Cleaning Liquid Tank 31a Overflow Port 32 Pumping Pump 33 Supply Pipe 35 Recovery Pipe 37 Electrode Roller 36a Electromagnetic Valve 38 Power Supply 39 Recovery Blade 40 Recovery Container 41 Liquid Level Sensor 43 Color Mixing Sensor 44 Developer Tank 49 Liquid Pool Department

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display location G03G 21/00 328 334

Claims (13)

[Claims] 1. A plurality of latent image carriers, latent image forming means for forming a latent image on each latent image carrier, and latent images formed by using a developing solution corresponding to each latent image carrier. Developing device that visualizes
A transfer device that conveys a transfer material so as to sequentially face a plurality of latent image carriers and transfers the visible images formed on the latent image carriers to the transfer material, and a latent image carrier after the transfer of the visible images. In a wet image forming apparatus having a cleaning device provided corresponding to each latent image bearing member for removing the developer remaining on the surface, the transfer material is more than the latent image bearing member which the transfer material first opposes by the transfer device. For the latent image carrier disposed on the downstream side in the transfer material transport direction, a developer tank for storing the developer used in the developing device, and a cleaning liquid used in the cleaning device and having the same components as the mother liquid of the developer. A cleaning liquid tank for storing the cleaning liquid, a cleaning liquid circulating device for circulating the cleaning liquid between the cleaning liquid tank and the cleaning device, and a cleaning liquid tank from the cleaning liquid tank to the developing liquid tank. A wet image forming apparatus comprising: a liquid supply device that supplies a cleaning liquid. 2. The wet image forming apparatus according to claim 1, further comprising a removing device for removing the developer from the cleaning liquid supplied to the developing liquid tank by the liquid supplying device. . 3. The wet image forming apparatus according to claim 2, wherein the removing device is configured by using an electrode member for adsorbing the charged developer and separating it from the cleaning liquid. apparatus. 4. The wet image forming apparatus according to claim 3, wherein the removing device is provided with a liquid reservoir around the electrode member for temporarily retaining the cleaning liquid supplied from the cleaning liquid tank to the developing liquid tank. A wet image forming apparatus characterized by the above. 5. The wet image forming apparatus according to claim 3, wherein the electrode member is removed so as to drive the electrode member so that the surface moves along an endless path including a portion removed from the cleaning liquid surface in the liquid reservoir. Electrode cleaning liquid removal that configures the apparatus and that removes the cleaning liquid carried together with the developer from the surface of the electrode member facing the surface of the electrode member that moves along the endless path part that has departed from the liquid surface of the cleaning liquid. A wet image forming apparatus comprising: an apparatus; and an electrode developer removing apparatus that removes a developer from the surface downstream of the removing apparatus in the surface moving direction. 6. The wet image forming apparatus according to claim 5, wherein the cleaning liquid removing member is moved so that the surface of the cleaning liquid removing member moves along an endless path including a portion facing the surface of the electrode member. A wet image forming apparatus comprising the electrode cleaning liquid removing device configured to be driven, and a scraper for removing the cleaning liquid from the surface of the cleaning liquid removing member. 7. The wet image forming apparatus according to claim 5, wherein the electrode cleaning liquid removing device is configured by using an air ejector that blows air onto the surface of the electrode member to remove the cleaning liquid. Wet image forming apparatus. 8. The wet image forming apparatus according to claim 2, wherein an overflow port is formed in the cleaning liquid tank, and the overflow port and the developing solution tank are connected by a liquid path pipe or the like to connect the liquid supply device. A device configured to perform an operation of removing the developer by receiving energy supply from the outside is used as the removing device, and the removing device is provided during a period in which the cleaning liquid may overflow from the overflow port. Wet image forming apparatus, characterized in that drive control is set so as to operate. 9. The wet image forming apparatus according to claim 2, wherein an overflow port is formed in the cleaning liquid tank, and the overflow port and the developing solution tank are connected to each other by a liquid path pipe to connect the liquid supply device. A device that is configured to perform an operation of removing the developer by receiving energy supply from the outside is used as the removing device, and the amount of the cleaning liquid in the cleaning liquid tank overflows from the overflow port. A wet image forming apparatus comprising: a liquid amount detecting means for detecting whether or not it has reached; and a control means for controlling an operation of the removing device based on a detection result by the liquid amount detecting means. 10. The wet image forming apparatus according to claim 2, wherein a mixed developer for detecting a developer of a developer used for another latent image carrier mixed in the cleaning liquid circulation system by the cleaning liquid circulation device. A wet image forming apparatus, characterized in that an agent detecting means is provided. 11. The wet image forming apparatus according to claim 10, wherein a device capable of removing the developer by receiving energy supply from the outside is used as the removing device, and the detection result by the mixed developer detecting means is obtained. A wet image forming apparatus comprising a control means for controlling the operation of the removing device based on the above. 12. The wet image forming apparatus according to claim 10, wherein an overflow port is formed in the cleaning liquid tank, and the overflow port and the developing solution tank are connected by a liquid path pipe or the like to connect the liquid supply device. A device that is configured to perform an operation of removing the developer by receiving energy supply from the outside is used as the removing device, and the amount of the cleaning liquid in the cleaning liquid tank overflows from the overflow port. A liquid amount detecting means for detecting whether or not it has reached, and a control means for controlling the operation of the removing device based on the detection results by the liquid amount detecting means and the mixed developer detecting means are provided. Wet image forming apparatus. 13. The wet image forming apparatus according to claim 10, wherein only the latent image carrier other than the latent image carrier which the transfer material first opposes is mixed in the cleaning liquid circulation system. Wet image comprising the above-mentioned mixed developer detecting means for detecting the developer of the developer used for the latent image carrier on the upstream side in the transfer material conveying direction with respect to the body, and the removing device. Forming equipment.