JPH07311503A - Film formation roll of wet electrophotograph - Google Patents

Abstract

PURPOSE: To provide a soft film forming roller for improving the completion degree of image concerning the electrophotographic apparatus and method of liquid toner. CONSTITUTION: A comparatively soft film forming roller FR is a conductor electrically biased in contact with the surface of a photoconductor on the downstream side of a developing mechanism from the point of view of operation on the surface of the photoconductor. The film forming roller FR is heated from the inside and exerts upon the photoconductor surface with the pressure of about 89.29g for every 1cm of tangent at the surface temperature of about 40 deg.C. The film forming roller FR performs operation for drying a latent image by evaporating the liquid toner of carrier medium and increasing the temperature of toner film. By combining the charging, heat and pressure of the film forming roller FR, when the latent image pass through this roller FR, the film formation of latent image is accelerated. It is preferable for the film forming roller FR to be used for the laser printer of liquid toner having an intermediate indirect image transfer system.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION This invention relates generally to image transfer technology, and more particularly to electrophotography. The present invention is
Liquid toner electrophotographic apparatus and soft film forming roller for improving image perfection in a method.

[0002]

In electrophotography, the surface area of an insulating photoconductor is selectively exposed to produce a latent image on the surface. There is a difference in electrostatic density between exposed and unexposed surface areas. In liquid toner systems, the visible image is developed with an electrostatic toner containing a pigment component that diffuses into an insulating carrier liquid. Depending on the relative relationship of the photoconductor surface, the development electrode, and the electrostatic charge of the toner, the toner is selectively attracted to either the exposed or unexposed portions of the photoconductor surface. . The photoconductor may be either positively or negatively charged and the toner system may also contain particles either negatively or positively charged. The preferred embodiment for laser printers is that the photoconductor and toner have the same polarity but their charge levels are different.

The paper, or intermediate transfer medium, is provided with an electrostatic charge opposite the charge of the toner, which is still an image pattern developed from the photoconductor surface, from the photoconductor surface to the paper, or the intermediate. As it attracts toner onto the media, it passes just past the photoconductor surface. When an intermediate transfer medium is used, a set of fusing rollers melts and fixes the toner in the paper following direct transfer or indirect transfer to create a print image.

There is a demand for multicolor images in the laser printer industry. To meet this demand, designers have relied on liquid toners having a pigment component and a thermoplastic component dispersed in a liquid carrier medium, which is typically an aliphatic hydrocarbon-based liquid. The liquid toner preferably contains a charge receiving component, a latex-like component, or a "film forming" component, and is also adapted to be electrically biased. Liquid toners can be used to sequentially apply the basic print colors, namely yellow, magenta, cyan, and black, to the photoconductor surface and to the paper or intermediate media from that surface to create a multicolor image. I know that. Many types of film-forming toners can be used with the present invention.

However, with liquid toners, it is necessary to remove the liquid carrier medium from the photoconductor surface after the toner has been applied to the photoconductor surface. Thus, the photoconductor surface can prevent liquid carriers from being transferred to paper or an intermediate medium during the image transfer step. or,
Thus, the liquid carrier can be recycled and reused in the development system for reuse, providing economics for print supplies and the environmental and health concerns of disposal of excess liquid carrier media. Can be eliminated.

According to US Pat. No. 3,955,533 (Smith et al.) About 50 microns (about 0.0050) from the surface of the photoconductor.
(8 cm) spaced reverse rollers to remove carrier liquid and excess pigment particles in the area outside the outer edge of the image, leaving a relatively clean background on the surface of the photoconductor. It is known to leave an area.

Also, (Yamada et al.) US Pat. No. 3,957,
No. 016 in a system with negatively charged toner,
It is also known to use a reverse roller biased to a positive charge, held at a voltage intermediate between the image voltage and the background voltage, to clean the background on the photoconductor surface and to help compose the image. .

Also, (Landa et al.) US Pat. No. 4,286,0
No. 39, it is also known to use a reverse roller followed by a negatively biased squeegee roller in a system with positively charged toner. The squeegee roller forms a latent image and removes excess carrier liquid.

US Pat. No. 4,325,627 (Swidler et al.)
U.S. Pat. No. 5,837,049 discloses an arcuate electric field electrode disposed between a squeegee roller and a transfer mechanism where a newly developed image is transferred to a carrier sheet. The field electrode is biased to a potential of opposite sign to the toner particle charge.

US Pat. No. 4,974,027 (Landa et al.)
No. 4,999,677, and 5,028,964 are all squeegees.
Disclosed is a positively biased reverse roller, separated from the cure roller, in front of the negatively biased cure roller, followed by a roller, after curing, with excess carrier liquid. Is used to remove from the image. If the charge on the toner is reversed, the charge on these rollers can be reversed. In these patents, the intermediate transfer drum is downstream of a curing roller for receiving the toner image from the photoconductor surface and transferring the image to the paper.

[0011]

Accordingly, in the electrophotographic industry of liquid toner, there is a need to more effectively transfer a semi-dry image to a transfer medium. It is also necessary to accelerate film formation of the latent image on the photoconductor prior to the image transfer step.

Also, by evaporating the liquid toner of the carrier medium and raising the temperature of the toner film,
It is also necessary to dry the semi-dry image. In addition, in the indirect transfer electrophotographic system, for the first transfer roller,
It is also necessary to efficiently transfer the latent image from there to a printing medium such as paper or a transparent sheet with the help of the second transfer roller. The present invention has been made to meet these needs.

[0013]

In view of the operation of the photoconductor surface in an electrophotographic apparatus, the present invention is comparatively arranged so as to make rotational contact with the photoconductor surface downstream of the developing mechanism. It is a soft film forming roller.
Depending on the type of toner used, the film forming roller may be a conductor. The film forming roller of the preferred embodiment is a conductor and is electrically biased between about 500-1000 (+) volts when used with a positively charged photoconductor. The film forming roller is heated from the inside to a surface temperature of about 40 ° C, and about 89.29 grams (1/2 lb./linear inch.) Per 1 cm tangent to the photoconductor surface.
It works under the pressure of. The film forming roller acts to dry the latent image by evaporating the liquid toner of the carrier medium and raising the temperature of the toner film. The combination of charging, heat, and pressure on the film-forming roller accelerates film formation of the latent image as it passes through the roller.

The film forming roller is preferably utilized in a liquid toner laser printer having an intermediate indirect image transfer system.

[0015]

DETAILED DESCRIPTION Referring to the drawings, there is shown a liquid electrophotographic apparatus constructed in a conventional manner around a photoconductor drum. In this case, the photoconductor is an organic photoconductor (OPC) that rotates clockwise as indicated by the arrow.

The OPC in the preferred embodiment is of the positively charged type, around which the following components or subsystems are arranged in clockwise order. a. Erase lamp at about 2 o'clock position to restore the electrostatic state of OPC to the initial state; b. Roller charged to positive charge at about 3 o'clock position,
Or a corotron; c. A laser scanner at approximately 4 o'clock; d. A liquid toner development device at approximately 6 o'clock.

Furthermore, according to the present invention, the OPC has a special film forming roller (FR) installed so as to come into contact with the OPC by rotation at a position of approximately 8 o'clock. Also OP
C has an optional indirect transfer system with first and second transfer rollers, labeled T1 and T2, respectively, at approximately the 12 o'clock position.

The operation of the erase lamp, charging device, and laser exposure device are conventional and therefore not described in detail herein. The developer unit may be of conventional construction, but in order to provide a thin film of toner to the photoconductor surface, the upper surface of the developer unit is open and in close proximity to the outer bottom of the OPC surface (about 50 -75 microns, or 0.00508-0.007
62 cm) liquid toner container is preferred. The toner container is preferably charged to an intermediate level of the same sign, between the charge area level and the discharge area level of the photoconductor surface.

Just downstream (in the direction of movement of the OPC surface) of the liquid toner container is a positively charged developing roller whose outer surface is also in close proximity to the outer bottom of the OPC surface. (About 50-75 microns, or 0.00508
-0.00762 cm). The developing roller rotates so that its outer surface moves in the opposite direction of movement of the OPC surface. Downstream of the developer roller, relatively close to the developer roller, the curing squeegee roller is in contact with the outer bottom of the OPC surface. The curing squeegee roller is also electrically biased and can rotate so that its outer surface moves in the same direction and at the same speed as the OPC surface. Therefore, there is no relative movement between the squeegee roller and the OPC surface. In this way, the curing squeegee roller removes residual toner liquid from the OPC surface, resulting in a drier image.

The latent image is already formed on the OPC surface while it is in the liquid development mechanism. However, at this point the image is semi-dry with a grain content of about 60-75% and no film has yet been formed. Such images must first be further dried and filmed to improve image perfection before they can be effectively transferred. There are two ways to accelerate the film forming event. The first is to dry the image by evaporating the toner solvent or carrier material.
The first is to increase the temperature of the toner film. A special film forming roller (FR) according to the present invention, located at approximately the 8 o'clock position on the OPC drum, accelerates film formation in both ways.

The film forming roller (FR) has a relatively soft or slightly hard structure, and the durometer index is about 40 in Shore hardness A. The film forming roller is a conductor here and has an electrical resistivity of about 1.0x10 ⁶ Ωcm, and when used with a positively charged photoconductor and a positively charged liquid toner, about 500-1000. Note that although electrically biased between the (+) volts, the conductivity of the film-forming roller and the electrical bias are related to the type of toner used and may or may not be necessary. is there. The film forming roller is heated from the inside, the surface temperature becomes about 40 ° C, and the tangent to the photoconductor surface is 1 cm.
It works at a pressure of about 89.29 grams per. The combination of charging, heat, and pressure of the film-forming roller accelerates film formation of the latent image on the photoconductor surface as the latent image passes through the roller.

The film forming roller (FR) is preferably utilized in a liquid toner laser printer having an intermediate indirect image transfer system. After the latent image is fixed on the photoconductor surface by the film forming roller, the latent image is transferred to the first transfer roller (T1) which is in contact with the photoconductor surface downstream of the film forming roller. The first transfer roller has a two-layer structure, and the inner layer is made of flexible silicone.
It is a rubber and the outer layer is a fluorosilicone material. A preferred fluorosilicone material is DC93004 available from Dow Chemical Company. The fluorosilicone material has a durometer index of between about 40-70 and has a higher adhesion to the toner film than the adhesion between the toner and the photoconductor surface. The first transfer roller is internally heated and the surface temperature is between about 45-80 ℃, preferably about 50 ℃.
And a pressure of about 1785.80 grams (10 lb./linear inch.) Per cm tangent to the photoconductor surface. When the toner on the photoconductor surface passes the first transfer roller, the toner is removed by the roller. Optionally, one or both of the transfer rollers T1, T2 can also be electrically charged to further enhance image perfection.

The first transfer roller (T1) is the second transfer roller (T1).
2) is also in contact. The second transfer roller (T2) is a hard roller made of steel or aluminum. If the second transfer roller is internally heated and a high rotational speed is desired, the surface temperature is between about 100-150 ° C, preferably about 150 ° C.
℃, about 26 cm per tangent to the surface of the first transfer roller
Operates at a pressure of 78.70-3571.60 grams (15-20 lb./linear inch.). A print medium, such as paper or a transparent material, is conveyed between the first and second transfer rollers. The image transferred on the first transfer roller is the second image on the first transfer roller.
When rotated to a position in contact with the transfer roller, the image is pressed against the paper passing through the roller. As a result of the second transfer roller conducting the high temperature to the paper, the shared boundary between the paper and the first transfer roller rises to about 80 ° C. At such a high temperature, the adhesive force between the toner and the first transfer roller decreases, and the toner peels off from the surface of the first transfer roller and adheres to the paper, thus completing the image transfer process. A heat source, such as a heating lamp, can be used between the development mechanism and the indirect transfer system to further accelerate the film forming process.

While the preferred embodiment of the invention has been shown and described, it is clearly understood that the invention is not limited to the embodiment and that various implementations can be made within the scope of the appended claims. It should be.

The embodiments of the present invention are listed below.

1. A photoconductor surface adapted to receive an electrostatic latent image, and a member (OPC) provided with a developing system adapted to supply a liquid developer to said photoconductor surface in a developing mechanism, and said photoconductor surface Has a means for passing through the developing mechanism, in an electrophotographic apparatus, a film forming roller (FR), at a position spaced from the developing mechanism, the film for rotating motion in contact with the photoconductor surface. Including means to mount the forming roller (FR),
The film forming roller (FR) is relatively soft as compared with the photoconductor surface, is heated to a temperature higher than the temperature of the liquid developer, and is pressed to contact the photoconductor surface. The device.

2. The device according to item 1, wherein the film forming roller is a conductor.

3. The film forming roller is about 1.0x10
Item 2 characterized by having an electrical resistivity of ⁶ Ωcm
The device according to.

4. The film forming roller is about 500-10
Item 3. The device according to item 2, wherein the device is electrically biased between 00 (+) volts.

5. The apparatus according to any one of items 1, 2, 3 and 4, wherein the film forming roller (FR) has a durometer index of about 40 in Shore hardness A.

6. The apparatus according to any one of items 1, 2, 3 and 4, wherein the film forming roller (FR) is internally heated to have a surface temperature of about 40 ° C.

7. Apparatus according to any of paragraphs 1, 2, 3 or 4, characterized in that the film forming roller (FR) acts on the photoconductor (OPC) at a pressure of about 89.29 grams per cm tangent.

8. The apparatus according to any one of Item Nos. 1, 2, 3 and 4, which also includes an intermediate indirect transfer system (T1, T2).

9. The indirect transcription system (T1, T2)
A first transfer roller (T1) that contacts the surface of the photoconductor downstream of the film forming roller (FR), and the first transfer roller (T1) is also in contact with the second transfer roller (T2); The device according to item 8, which is characterized in that

[0035]

The present invention more effectively transfers a semi-dry image to a transfer medium in liquid toner electrophotography and accelerates film formation of the latent image on the photoconductor prior to the image transfer step. be able to.

[Brief description of drawings]

FIG. 1 is a schematic side view of one embodiment of the present invention showing a film forming roller and an optional indirect transfer system in a liquid electrophotographic system.

[Explanation of symbols] OPC Organic photoconductor FR film forming roller T1 1st transfer roller T2 2nd transfer roller

Claims (1)

[Claims] 1. A photoconductor surface adapted to receive an electrostatic latent image, and a member (OPC) provided with a development system adapted to supply a liquid developer to the photoconductor surface in a developing mechanism. In the electrophotographic apparatus, wherein the photoconductor surface has a means for passing through the developing mechanism, a film forming roller (FR), at a position spaced from the developing mechanism, in contact with the photoconductor surface for rotational movement. A means for mounting the film forming roller (FR) for causing the film forming roller (FR) to be relatively soft as compared with the photoconductor surface and to be heated to a temperature higher than the temperature of the liquid developer. , The device being contacted with the photoconductor surface under pressure.