DE2161194A1 - Method of processing electrophotographic material after development - Google Patents

Description

received

DR.E. WIEGAND DIPL-ING. W. NIEMANN 2161194

DR. M. KÖHLER DIPL-ING. C. GERNHARDT

MDNCHEN HAMBURG TELEPHONE: 395314 2000 HAMB U RG 50, ' TELEGRAMS: CARPATENT KON IGSTRASSE 28

W.25042 / 71 12 / Sch / bl

Fuji Photo Film Co., Ltd. Ashigara-Kamigun, Kanagawa (Japan)

Method of processing electrophotographic material after development. '

The invention relates to a method of treating electrophotographic material according to the Developing with the aim of stabilizing the image developed with the liquid developer.

In the method described below, liquid developers are usually used. A electrophotographic material having a photographic latent image formed thereon is first used in an insulating liquid containing no toner is immersed and moistened on both sides. this will referred to as the pre-bath process. The purpose of the pre-bath is to create a thin film to prevent that the toner suspended in the liquid developer adheres to the electrophotographic material adheres.

Kerosene, cyclohexane, pentane, decalin and many others are used as the pre-bath liquid during development non-polar hydrocarbons and halogenated hydrocarbons used.

The electographic material that the Has gone through the pre-bath process, then in the development

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Winder immersed. The developer is made up of an insulating liquid called the carrier liquid and fine, chargeable particles - known as toner - that are contained in the liquid are suspended »

In the carrier liquid there is a charge control agent which is intended to control the charge of the toner to control, or a dispersion stabilizer, which is designed to control the dispersion of the toner to stabilize, contain, either in suspension or in solution. As a charge control agent or or dispersion stabilizers are resin, varnish or a non-drying oil, which is in the carrier liquid is detachable, or or resin, varnish or the like, which are not dissolvable in the carrier liquid, is used,

The carrier liquid is usually the same liquid used for the pre-bath process will. When the charge of the toner has the same sign as that of the electrostatic latent image, gives an accumulation (dep; osit) of the toner on the uncharged or slightly charged area of the latent Image, which is referred to as reversal development or repulsion development. If contrary to this the charge of the toner has one sign and the charge of the latent image has a different sign the toner adheres to the charged area of the latent image, which is called normal development or attraction development

The particles of the toner, which are colorless or colored inorganic or organic pigments, are in suspended in the carrier liquid, either by itself or in such a way that resin or lacquer is absorbed on their surfaces will. Development is completed when there is sufficient toner on the surface of the latent image is deposited, after which a flushing device

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gang or squeezing process takes place.

A flushing process is performed by inserting either the developed electrophotographic material into the Dipping detergent or by spraying the detergent over the developed electrophotographic material will. A quick-drying insulating liquid with low solubility is used as a washing-up liquid used. Of many available liquids or detergents are Difluorotetrachlorathane, Trifluorotrichloroethane and Isopar-E (trade name of a product of the ESSO-Standard Oil Company) are recommended. Of the The purpose of flushing is to remove the developer deposited on the surface of the electrophotographic material to remove and improve the adhesiveness of the image developed by means of the toner. The reason why the adhesiveness of the means of the Toner developed image is improved, is that the resin and / or varnish, or deijan is absorbed by the toner particles, is fixed without that resolution results.

The electrophotographic material that has been rinsed is passed through squeeze rollers, whereby S3 a surface is freed from the developer deposited on it and largely dried. if the electrophotographic material immediately after development and without prior rinsing by the nip rollers goes through, difficulties often arise in that the developed by means of the toner Image is transferred to the squeeze rollers or squeezed together so that it passes. Self When flushing, fast working or poor detergent selection can lead to the aforementioned Cause difficulties .. '

These difficulties are particularly noticeable when electrophotographic material, which one

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Has been subjected to reversal development, is squeezed out » With so-called normal development, these difficulties hardly arise.

The invention aims to eliminate the aforementioned disadvantages and difficulties.

The invention is explained below with reference to the drawing, for example.

Pig. Fig. 1 shows a model showing the difference in resistance of the toner image should be shown when squeezing in normal development and reversal development -Fig. Fig. 2 is a view similar to Fig. 1 showing the principle of the present invention is explained.

Fig. 3 is a sectional view of a practical one Equipment necessary for carrying out the

To be used in the invention, electrophotographic material 10 consists of a light conducting insulating layer 11 and one conductive base 12. A mixture of photoconductive powder and insulating resin or an organic one Photoconductive compound is used to form the photoconductive insulating layer 11. As a senior The basis is a plastic film with a conductive Polymer is coated, or paper on which metal is deposited by means of vacuum, or which is metal-plated and impregnated with conductive polymer, e.g. metallized paper. Referring to Fig. 1, it is assumed that the light-conducting insulating layer 11 is an η-semiconductor. More accurate said, for example, a layer is used as an n-semiconductor, which is made with a mixture of zinc oxide powder and coated with an insulating resin. The latent image is formed by means of negative charge 13. The charge 14 is a positive counter charge,

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that of the negative charge I3 is almost equivalent or is equivalent to that at the boundary between the light guiding insulating layer 11 and the base 12 is concentrated. The negative charge I5 is largely present on the surface of the light-conducting insulating layer 11.

When the latent image is developed when the toner has a positive charge, the toner is attached to the 4 charged or charged area of the latent image is attracted and deposited thereon. At 15 he is from the Charge I3 of the latent image denotes "toner attracted and deposited thereon. The adhesiveness of the Toner I5 hangs on the surface of the latent image mainly of that generated between the charge I3 and the toner 15 according to Coulomb's law Force off.

On the other hand, when developing in reverse, if the If toner carries a negative charge, the toner is attached to the uncharged area of the latent image. With 16 denotes the negatively charged toner deposited as described above.

The adhesiveness of the toner 16 to the latent Image presumably depends on the recoil from charge 15 and the force according to Coulomb's law between the positive charge that leads to the interface between the light-guiding insulating layer 11 and the base 12 is generated as a result of the attachment of the toner 16

These adhesive forces acting on the toner 16 are very small. The Coulomb's force is small because the distance between the toner 16 and the charge I5, or between the toner 16 and the positive charge at the underlying interface is large. In contrast in addition, in the case of non-inverse expansion, the Coulomb's see Attraction between the toner 15 and the charge

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very large because the distance between the toner 15 and the charge 13 is very small.

On the basis of the concept described above was attempted according to the present invention, the To improve the adhesion of the toner image to the latent image surface. .

As a result, the squeezing resistance of the toner image was improved considerably.

In Fig. 2, the principle of the present invention is explained.

The device 20 shown in this figure is a known and available corona charging device comprising a corona electrode 21 and a shield case 22. With 23 an energy source of high direct voltage is designated, which is used to apply positive high voltage to the Gorona electrode 21. Positive corona ions resulting from corona discharge are deposited on the toner 16 as shown in FIG. 1, thereby changing the negative polarity of the charge on the toner 16 to positive polarity. Reference numeral 24 denotes the toner 16, the polarity of which is changed so that it bears a positive charge. Simultaneously with the deposition of positive corona ions on the toner 16, the equivalent negative charge 25 is transferred from the conductive layer 12 to the light-conductive insulating layer 11 with a thickness of 1 to 100 μ , whereby it comes very close to the toner 16.

It is important for a negatively charged toner that the insulating layer 11 is an η-semiconductor, so that the electrons are free to move. That is, an η-light-guiding insulating layer to which a negative latent image is formed, is developed with negatively charged toner, after which the image bearing layer is exposed to positive corona ions.

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Rome v e ^- "η Sun: * - on c. I " Ls-I \. ■ έ · wire e ^ .n with posii will

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S = λ active corona ions on the toner 16 anget w * By applying negative high voltage to the Co, the insulating 3 equivalent positive charge earths the Coulomb's force is reduced lien the distance between the negative positive charge of the toner 16 ^It is like slenium or polyvinylcarbazole, it forms a latent image on it and develops the same toner. In this case it is used which is formed by resins, pigments and preferably heavy metal salts of organic acids in the carrier liquid, as described in US Pat. No. 5,257,322 or British Pat. No. 1,065,795. Then negative high voltage is applied to the corona electrode21 so that the developed layer is exposed to negative corona ions. If the light insulating layer 11 is an n-layer, the layer must be positively charged after development, and if this layer is not a p-type, it must be negatively charged.

In Fig. 3 is a practical sectional view Equipment to be used for the invention.

Rollers 30 and 31 are two feed rollers used to feed the developed electrophotographic material 10 held therebetween. The roller 30 is flanged at both ends to prevent its surface from contacting the toner image and the electrophotographic material is fed by being between the flanges of the wai a ^ '-0 üi.,: I der Roller 31 is held »Nozzles 32 and 33 are used to supply rinsing liquid

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on the top surface and the bottom surface of the electrophotographic Spray Materials 10. Rollers J4 and 35 are two feed rollers corresponding to rollers 30 and 31 are similar. The roller 34 is flanged at both ends With 36 and 37 are an ooron conductor or corona wire respectively; referred to as a shielding plate. Rollers 38 and 39 are two squeeze rollers. At least one the rollers 38 and 39 is made of elastic soft material such as rubber material, sponge material, etc. coated. The rollers 30, 31, 34, 35 and 38 are made made of hard material such as metal or plastic.

The electrophotographic material 10 is coated with the rinsing agent between the roller pairs 30 »31 and 34, 35 washed · Behind the surface carrying the toner image is exposed to the corona discharge, and thereafter is squeezed out for drying. If the toner layer is highly conductive, the method is the present one Invention not effective. In general, the invention can be practiced so long as the a light-conducting layer deposited toner layer

10
Shows surface resistance of 10 ohms per area or higher.

From developers who have good charging characteristics

only those who have a layer of toner create a layer of toner

10 a surface resistance of less than 10 ohms per surface, composed mainly of carbon and are of low resin content, essentially all others that are organic or inorganic Pigment are composed, meet the above requirements. Thus, a person skilled in the art can Usefulness of a developer simply by resistance study easy to determine

Carbon black based developers can easily meet the above requirements under the Requirement for the choice of resin material.

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The invention is explained in more detail below with the aid of examples.

example 1

A sheet of art paper was coated with a mixture obtained by 100 Parts by weight of light-conducting zinc oxide powder with 20 parts by weight of styrenated alkyd resin (Styresol 4400 from Nippon Reichhold Co.) so that the dried thickness was approximately 7 microns.

The art paper used was previously with quaternary Ammonium salt polymer, a conductive polymer (Calgon Conductive Polymer 261 from Calgon, USA) coated such that the dried coating was present in an amount of 1.5 g / m2.

The electrophotographic material was charged to a surface potential of -180 V, namely by negative gorona discharge in the darkroom, after which it was exposed to the light of the picture, thereby affecting it a negative latent image has been formed. The material was then immersed in the developer, containing the negative charge toner, and developing was carried out for one minute.

The developer was made as follows:

A liquid dispersion which was composed of:

Nitrocellulose J 4 parts by weight of carbon black. 1 part by weight

Acetone 50 parts by weight,

was dried to a fine powder. Then, 10 parts by weight of this fine powder were placed in a ball mill dispersed for 50 hours together with:

Alkyd resin modified with safflower oil 200 parts by weight (Super Beckosol J-537 from Nippon Reichhold Co.)

Isopar H 100 parts by weight

(from ESSO-Standard Oil Co., isoparaffines Solvent).

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The paste obtained was diluted and dispersed in Isopar H in a volume of Isopar which Was 30 times the size to create the developer.

After developing by using this developer, the electrophotographic material was made with Isopar E ^ an isoparaffin solvent from ESSO much higher evaporation rate than Isopar H, purged and using the equipment shown in Fig * 3 squeezed out. Rolls 31 »35 and 38 had 16 mm in diameter and made of stainless steel. Rollers 30 and 34 also had one 16mm in diameter but 18mm in diameter on the flanges, and they passed too made of stainless steel. The roller 39 had an outer diameter of 16 mm and was made of 4 mm thick rubber overdrawn. A corona wire or stainless steel corona conductor 0.1 mm in diameter was used .

A positive voltage of 8 kV was applied to the corona conductor.

The corona conductor was located approximately 10 mm from the electrophotographic material. The electrophotographic Material was fed at a speed of 20 mm per second, but it survived Toner image squeezing. In a case in which there was no corona discharge and to the corona conductor or negative voltage was applied to corona wires, the squeezing destroyed the toner image.

Example 2

Electrophotographic paper with a polyvinyl carbazole layer of a thickness of 10 ^ <, which is a p-light- is conductor, became evenly through positive corona discharge charged and image exposed. The developer was prepared by dispersing 40 parts by weight in the carrier liquid, which is a mixture of

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1 Weight .Part 20th Weight .Parts 19th Weight .Parts.

- 11 -

980 parts by weight of Isopar H and 20 parts by weight of cottonseed oil duration. The 40 parts by weight sat down as follows:

Carbon black 0.4 part by weight

Phthalocyanine Blue 0.05 part by weight Ethyl cellulose

Ethyl acetate

Toluene.

In this developer, the pigments were coated by the ethyl cellulose, and their polarity as Toner was positive.

The latent image bearing paper was developed in this developer for 20 seconds. To the development, the electrophotographic paper in Isopar G (trade name of Esso Standard Oil Co., an isoparaffinic solvent, the rate of evaporation of which is much faster than that of Isopar H) rinsed and exposed to negative ooronaions when wet. The corona discharge electrode made of molybdenum wire a diameter of 30 / * was at a distance held by 15mm from the paper and it became a voltage of -7 kV is applied. Thereafter, Isopar G adhering to the paper was removed by the squeezing rollers removed. An excellent negative original image was obtained.

According to the present invention, the application of the corona ions after the development after rinsing according to described above or immediately after development, with rinsing omitted will. However, the rinsing is about quick drying of the paper and about preventing of fog on the image is advantageous.

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Claims (2)

Received on patent claims 1. A method of treating electrophotographic material after developing, in which the electrophotographic Material is rinsed and squeezed out after developing, characterized in that on the surface of the light-conducting insulating layer that has already been developed by liquid development processes is, corona ions of the same polarity as those of the minority carriers of this light-conducting insulating Layer are applied, and that subsequently the detergent residue adhering to the insulating layer is removed by means of squeezing rollers. 2. The method according to claim 1, characterized in that the application of the corona ions by means of one or more corona conductors or corona wires running near the surface of the squeezing rollers fed electrophotographic material are arranged. 3 · Method according to claim 2, characterized in that conductors or wires as corona conductors a diameter of about 0.01 to 0.3 mm may be used, spaced up to about 20 mm from the electrophotographic material fed to the nip rollers. 4. The method according to claim 2 or 3 »characterized in that that a positive voltage of 8 kV is fed to the corona conductors. 5. Method according to one of claims 1 to 4-, characterized in that the corona ions or the corona discharge at the electrophotographic Material between the station at which detergent is applied to the electrophotographic material is, and the squeezing rollers are applied or applied - or. will. 209 827/0909 6. Device, in particular for carrying out the method according to one or more of claims 1 to 5 »with at least one arranged in a rinsing zone Roller pair and a downstream roller pair for squeezing the between the roller pairs conveyed electrophotographic material, characterized in that between the first-mentioned rollers- pair (5 ^, 55) and the latter pair of rollers (58 » 59) a Gorona discharge device (56, 57) is arranged, which has a corona conductor (56) τ ^ er in one Distance of about 10 to 15 mm from the conveyed Electrophotographic material (10) is arranged and has a shielding device (57) behind the corona conductor (56) is arranged. 7. The method according to claim 1, 'characterized that the reverse developed insulating layer is rinsed with isoparaffinic solvent and then is exposed to the coronaions. 8. The method according to claim 1, characterized in that that the reverse developed insulating layer is exposed to the corona ions without prior rinsing will. 2 0 9 8 2 7/0909 Blank page