DE2106720A1 - Electrophotographic process - Google Patents

Description

PATE NTANWXlTE

DR.E. WIEGAND DIPL-ING. W. NIEMANN 2106720

DR. M. KOHLER DIPL.-ING; C GERNHARDT

MÖNCHEN HAMBURG

TELEPHONE: 55 54 76 8000 MÖNCHEN 15,

TELEGRAMS: KARPATENT NUSSBAUM3TRASSE 10

February 12, 1971

¥. 4-0358 / 71 -

Photo Film Co. Ltd., Ashigara-Kamigun, Kanagawa, Japan

Electrophotographic process

Electrophotographic coatings are common susceptible to mechanical damage in the course of manufacture, storage and handling.

According to the invention reduces this vulnerability by providing a protective top coat is applied over the photoconductive _coating} which can be removed by dissolution in the insulating liquid of the liquid before or during development.

The invention is concerned with an electrophotographic Process, particularly an electrophotographic process using liquid development.

The electrophotographic sensitive materia lien with which the invention is concerned, are by

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Drawing up a photoconductive, insulating layer, which consists of a mixture of a resinous binder and a photoconductive substance is made on a flexible basis. Although the flexibility is based brings numerous advantages and these sensitive materials of this type now predominantly for copying Used by documents, the flexible, delicate materials show the flaws that the surface for mechanical damage due to the extremely high volume content · of the photoconductive substance in the delicate layer is very delicate.

These deficiencies do not result in any serious disadvantages, if these materials are used to copy documents. If, however, photographic images of continuous tint are to be reproduced on the electrophotographic paper, this error results very serious problems. If these delicate papers are handled in the course of manufacture or storage, so that the sensitive layers are rubbed against or brought into contact with other objects can be caused by pressure or external forces that affect the surfaces of these sensitive layers suffer physical damage and exhibit deterioration in properties. In suspension a corona discharge, for example, these attacked surfaces can have a lower initial potential than the other parts of the surface or when suspending of light, the potential in these surfaces can be accelerated or decelerated by the light than to be weakened in the unaffected areas. In case the delicate paper with these Defects are subjected to the development of liquid, whereby a toner deposition is exactly the same

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the charge distribution of the latent, electrostatic Image is made, these areas are unsatisfactory as spots or scratches in the continuously toned Image.

The object of the invention is therefore to see an el ektrophotographi method in which these errors hardly occur.

The electrophotographic method of the present invention is that an electrostatic latent image is seen on an electrophotographic, photosensitive Material is formed, which by attaching ■ a photoconductive, insulating layer on a flexible support and further formation of an insulating Protective layer, which consists mainly of resin, was obtained, and this protective layer before or during the stage of the development process using a liquid developer which is dispersed produced by electrically charged particles in an insulating liquid, is dissolved.

Since the above insulating protective layer serves to achieve mechanical protection for the sensitive layer, it is applied to the sensitive layer following the formation of the sensitive layer on the basis or, if a special coating process is used, simultaneously with the formation of the sensitive layer on the Base raised. For practical reasons, the thickness of this layer should be more than 0.2 µ but not more than 5 A. The only requirement for the resins used in this layer is that they are in the carrier liquid used for the liquid developer or in an insulating prebath that is mixed with the sensitive material before the liquid development stage.

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Wandt is and a suitable degree of electrical insulation "must possess, are soluble. Practical examples are styrene-modified alkyd resins, with a non-drying oil-modified alkyd resins" epoxy ester of long-oil type "Polybtttylmethacrylat, homopolymers of Älkylestern of acrylic acid or methacrylic acid ait not more than 3 carbon atoms in the Alkyl group and copolymers consisting mainly of styrene-batyl methacrylate copolymers, styrene-batadiene copolymers, silicone resins and compatible combinations thereof. Since treatment baths generally consist mainly of liquids that are non-polar and have a low resolution, the in The resins to be used in the protective layer are of course limited to those of the non-polar type.

Although all commonly known, photoconductive, insulating layers (sensitive layers) Can be used within the scope of the invention, it is necessary that they are in the treatment bath, which is used for dissolution the protective layer is used are insoluble. Therefore it has to be used in the sensitive layer Binder of the type that does not have a very strong polarity or which is hardened so .that it is at most slightly soluble in the treatment bath.

Examples of binders for use in the sensitive layer are alkyd resins with isocyanate compounds are hardened, epoxy ester resins, vinyl chloride-vinyl acetate copolymers, Polyvinyl acetate and ethyl acrylate-methyl methacrylate copolymers. In the context of the invention, no approaches that use diffusion can be used of the curing catalyst or the curing agent into the protective layer after the peeling step and thereby allow hardening of the protective layer.

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In general, the coatings of the protective layer are successful without affecting the sensitive layer achieved by a resin solution for the protective layer a solvent with the same or similar composition as the bath is used, which is later used for Dissolution of the protective layer is used.

The process of the invention can be varied in numerous ways, some of which are given below are:

a) The sensitive layer with the protective layer applied to it becomes a corona charge and image wise subjected to suspension. Then the sensitive 'material is in a pre-bath, which is used to dissolve the protective layer is suitable to be brought immediately prior to the development process. The one applied by the corona discharge electrostatic charge penetrates through the thin protective layer and reaches the upper surface of the photoconductive layer so that a sufficient image is obtained when the latent image is an ordinary one Undergoes fluid development after this treatment.

b) Before the electrostatic charge, the protective layer is removed by an insulating treatment bath and the sensitive material, which is still in the moist state, is exposed imagewise and then developed.

It has been found that an extremely high quality image can be obtained here provided that the Treatment bath shows a sufficiently high electrical insulation.

c) The sensitive material is electrically charged by an ordinary method, and then one subjected to imagewise development with a liquid developer containing electrically charged particles in a Contains carrier liquid which is capable of dissolving the protective layer.

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- O -

In this case, the resin which forms the protective layer dissolves in the carrier liquid. Consequently the electrophoretic properties are gradually influenced by the dissolved resin and the viscosity of the developer increases in particular.

This modified method can be carried out within a range in which the viscosity of the Liquid is suitable for the treatment.

If one of the above methods is used, the presence of the protective layer is used for the distinctive Reduction of changes in the sensitive layer due to direct damage from the outside Powers. As a result, there is a considerable risk that the image that is finally obtained will show errors be reduced.

As a supplementary explanation of methods a) and b), the resin, which forms the component of the protective layer, is gradually dissolved and taken over as an impurity in the bath used for dissolution. As a result, the viscosity of the bath increases and the electrical insulation is affected. If the electrical resistance of the bath is badly damaged, the latent image in the case of a) is destroyed or quickly weakened and a sufficiently high potential cannot be achieved in the subsequent charge. Therefore, the resin used in the protective layer must be such that, when dissolved in the bath, it does not lower the resistance of the treatment member. Of the alkyd resins, those having a long oil length are preferred in view of this. Since a small part of the resin of the protective layer results in contamination of the liquid developer via the dissolving bath, the resin favorably has the property that it does not exert any adverse effects on the developing agent.

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The resins listed above meet all of these requirements.

It follows from the invention that the invention also applies to all electrophotographic processes using electrostatic latent images in addition to the Carlson method is applicable, for example based on the Kalman method, method the photovoltaic effect and thermoxerographic processes.

The following examples serve as a preferred export ungs forms to further explain the invention. j

example 1

With an appropriate amount of butyl acetate, 100 parts of photoconductive zinc oxide, 20 parts of a styrene-modified alkyd resin paint (non-volatile content 50%) and 14 parts of a polyisocyanate compound (non-volatile content 75 %) were mixed. The mixture was spread to a dry strength of 7 J * on art paper which had been treated to achieve suitable electrical conductivity. This sensitive material was left to stand overnight in a thermostatic drying vessel at 50 ° C. Then the surface of the material was coated with a toluene solution of polybutyl methacrylate to form the protective layer. The amount drawn up was 1.2 g / m 2 on a dry basis.

The sensitive paper produced in this way was subjected to dark adaptation. An arch this Sensitive paper has been negatively charged and exposed to light from an optically positive image and in a Liquid developer that disperses black toner particles of positive polarity in kerosene as a carrier

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contained liquid, immersed. The file was the polybutyl methacrylate dissolved on the surface in the liquid developing agent and a clear, positive image obtain.

Another sheet of the same paper was treated in the following order: The sensitive paper was first in cyclohexane to remove the polybutyl methacrylate layer immersed by dissolution. This treatment can be done by manual operation or under Application of an automatic device with means for directing a strong flow of liquid is equipped against the surface of the sensitive paper and for squeezing the liquid.

After the polybutyl methacrylate layer had been removed, the excess liquid was squeezed off. then the sensitive paper was electrically charged by exposure to a negative corona discharge, to light from exposed and developed to an image in the same manner as above. It became a again get clear picture.

Example 2

With toluene, 100 parts of photoconductive zinc oxide, 40 parts of a paint composed of the epoxy ester of dehydrated castor oil fatty acids (non-volatile component 50 %) and 0.1 part of cobalt naphthenate were mixed. The mixture was spread to a dry thickness of 10 ti on a sheet of bound paper that had been treated with an electroconductive polymer. The resulting paper sheets were kept in a thermostat for curing at 40 ° C. for 15 hours.

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On the surface of the same was PIiοlite S-7 (styrene-butadiene copolymer from Goodyear Tire & Rubber Co., USA) drawn up in different coating weights j the coating weights are in the following table specified. Before the electrostatic charge, the sensitive paper was coated with kerosene on the surface Swelling of the surface layer moistened. It became immediately electrical by exposure to negative corona loaded. After the subsequent, imagewise exposure of the paper, the development took place in one ', Liquid developer using kerosene as the carrier liquid. Better results were on the ones with Pliolite obtained from surfaces coated with a smaller film thickness. In the areas with the greatest film thickness of Pliolite, the saturation density was low and the edge effect was continuous when reproducing images Tint observed. The surface of the sensitive paper was moistened with kerosene, then negatively charged and then subjected to a surface potential determination. The results are in the Table I listed.

According to this example it was found that a excessive thickness of the surface layer is unfavorable J and that satisfactory results with protective coatings thinner than 1 u can be obtained.

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Strength of
surfaces
layer - 10 - 2106720 I. 0.6 /!
0.8 / ι Tabel Remaining potential
ratio after 1 min.
Dark waste No. 1.5 / ι At first
potential 73%
70 % 1 ,
2 / 260 V
220 V 42 % 3 110 V . Example 3

The procedure of Example 2 was repeated, but using polybutyl methacrylate instead of Pliolite S-7 used. In this pail, high-density images became free from the edge effect even when a delicate one was applied Received paper with a protective layer with a thickness of up to 1.5 / ι.

The same experiment as in Example 2 was carried out. It was found that the increase in the strength of the smile does not noticeably change the Properties revealed.

Strength of
surfaces
layer Table II Remaining potential
Ratio after 1 min.
Dark waste No. 0.6 / i
0.8 / 1
1.5 / 1 At first
potential 86 %
83 %
81 % 4th
5
6th 280 V
310 Ύ
320 V

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Example 4-

The process according to Example 1 was repeated, but the material of the protective layer was a styrene-modified one Alkyd resin used. Satisfactory results were obtained in the same way as in Example 1 obtain.

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Claims (1)

Patent claims [Λ.j An electrophotographic process, characterized in that an electrostatic latent image is formed on an electrophotographic, sensitive material, which consists of a flexible support with a photoconductive, insulating layer thereon and an insulating protective layer thereover, which consists mainly of resin, is built up, is formed and the protective layer is dissolved before or during the step of developing the latent image using a liquid developer consisting of an electrically insulating carrier liquid and an electrically charged toner dispersed in the carrier liquid. 2. Electrophotographic process according to claim 1, characterized in that an insulating protective layer which is soluble in the insulating liquid is used. 5. An electrophotographic process according to claim 1 or 2, characterized in that an insulating Protective layer is used, mainly made of styrene-modified alkyd resin, with non-drying oil modified alkyd resin, epoxy ester resins of the long oil type, Polybutyl methacrylate, homopolymers of alkyl esters of acrylic acid or methacrylic acid with more than 5 carbon atoms in the alkyl group and copolymers mainly from such esters, styrene-butyl methacrylate copolymers, Styrene-butadiene copolymers or silicone resins. 4-. Electrophotographic process according to claim 1 to 3 »characterized in that an insulating protective layer is used with a thickness of 0.2 to 5 Ά . 1 09835/14 88