DE3342312C2 - Electrophotographic recording material and its use - Google Patents

Abstract

An intermediate photoconductive image carrier is provided for an electrophotographic process in which an electrostatic latent image is formed by the sequential steps of primary corona charge simultaneously with imagewise exposure, secondary corona charge and irradiation with light. A barrier layer made of paraxylylene is created between a conductive support layer and a photoconductive layer in order to suppress the injection of carriers from the conductive support layer into the photoconductive layer and vice versa in the dark.

Description

The invention relates to an electrophotographic recording material according to the preamble of the patent claim 1.

Such Ai ^c drawing material is known from DE-AS 26 55 414. The recording material described therein for the so-called Carlson process is intended to reduce the dark decay and improve the adhesion through a barrier layer of chloroprene rubber and / or nitrile rubber between layers, reducing photosensitivity and residual potential, and preventing uneven dispersion.

In a recording material for the Carlson process, a p-type photoconductive layer is mil positive charge on its surface a barrier layer is required to exclusively allow the entry of to prevent negative charges from the support, while in the case of an n-type photoconductive layer the Entry of exclusively positive charges must be prevented.

From the magazine "Xerox Disclosure Journal", Vol. 3, No. 5, 1978, p. 309, is poly-P-xylylene as a coating material known, but without any statements about the electrical insulation properties of this Materials to be made.

The invention is based on the object of providing a recording material of the generic type, in which the entry of both positive and negative charges is prevented.

According to the invention, this object is achieved in that paraxylylene is provided as the material for the barrier layer is, which preferably has a thickness in the range from 0.1 to 1 μπι and applied by vacuum vapor deposition is.

The electrophotographic recording material according to the invention is suitable for an electrophotographic process with primary and secondary corona charging, in which the barrier layer, because of its good insulating properties with respect to charges of different polarity, exposes high contrast voltages

The invention is explained in more detail below with reference to the drawing

F i g. 1 shows a section through an electrophotographic recording material according to an embodiment the invention,

F i g. Figures 2 (a) to (e) are a series of schematic views to explain the successive steps involved in forming an electrostatic latent image on the recording material according to FIG. 1.

ίο As F i g. 1 shows the recording material a conductive substrate 1, the surface of which is coated with a barrier layer 4, the paraxylylene has and is deposited by vapor deposition in a thickness of 0.1 to 1 μπι on the barrier layer 4 a photoconductive layer 2 and a transparent cover layer 3 are stacked in sequence

The electrophotographic recording material has a larger one because of the barrier layer 4 Freedom in the choice of the material of the layer support 1- In detail, the layer support can be made of metals, such as Aluminum, nickel, molybdenum, gold, silver, platinum, zinc, niobium, tantalum, vanadium, titanium, tellurium, lead, iron or iridium or alloys of the same, such as stainless steel or of other materials, such as glasses, Ceramics or synthetic foils are made which are treated with indium tin oxide to make them electrically conductive close. The conductive substrate 1 can be designed as a drum, belt or flat sheet, depending on the Type of electrophotographic copier in which it is used.

In the embodiment described here, the photoconductive layer 2, a charge transport layer 2a, which is coated on the top of the barrier layer 4 and a charge generation layer 2b is applied to the charge transport layer 2a. Such a photoconductive layer 2 can be made of inorganic photoconductive substances such as cadmium sulfide (CdS), cadmium zinc sulfide (ZnCdS), lead monoxide (PbO), selenium (Se), selenium-tellurium (Se-Te), selenium-arsenic (Se-As), sensitized lead oxide (ZnO) or organic photoconductive substances such as polyvinyl carbazole (PVK) or trinitrofluorenone (TN F).
In the embodiment shown, the photoconductive layer 2 is divided into the charge transport layer 2a and the charge generation layer 2b . However, the use of such a layer structure with separate functions is not essential.
When selenium tellurium heated from a single

So the boat is vapor-deposited to create a selenium-tellurium layer for the photoconductive layer, it shows that the tellurium is distributed in the direction of depth so that the amount of tellurium in the direction of the conductive layer support decreases and increases towards the surface of the photoconductive layer because the vapor pressure of the Tellurium is lower than that of selenium. The distribution of tellurium is similar when heated separately used to have selenium as the charge transport layer and selenium tellurium on top as the charge generation layer knock down. The terms "charge generation layer" and "charge transport layer" are therefore to be understood in the context of the manufacturing technique, although it relates to the structure within the denote photoconductive layer.

The thickness of the photoconductive layer 2 depends on the material or materials used to create it Materials from, but is in a range from 1 to 100 μm, preferably in the range from 5 to 70 μm.

The transparent cover layer 3 is obtained by forming a film made of polyethylene terephthalate, polypropylene, polyvinyl fluoride, polyamide or polyester with increased specific resistance (equal to or greater than 10 ^M Dem), by vapor deposition of paraxylylene or application of a thermoplastic resin such as a copolymer resin of vinyl chloride and vinyl acetate, methacrylic, vinylidene chloride, polyester resin or other thermosetting resins, such as epoxy, alkyd, acrylic, urethane or silicone resin.

The barrier layer: can have a thickness to some Micrometer corresponds to or is thinner and is preferably in a range from 0.1 to 1 μm Thickness than a few micrometers results in very poor carrier injection, which lowers the tension of the kerosene On the other hand, if the layer is too thin, it will lose its effectiveness as a barrier layer.

On the electrophotographic recording material constructed as described above, an electrostatic latent image can be generated by a process which is sequentially described in F i g. 2 (a) through (e)

First of all, a primary corona charge takes place simultaneously with imagewise exposure, as shown in FIG. 2 (a) shows, assuming that the photoconductive layer 2 of the recording material is of the P conductivity type, a corona charger 5 is supplied with a high positive DC voltage from a power source 6 to uniformly charge the surface of the cover layer 3 with positive polarity while it is is simultaneously exposed to a light image 8 by irradiating with light hv through an original 7. In the course of this, positive and negative charges arise in pairs in the photoconductive layer 2 in the bright area of the light image into which the light hv is incident. The positive charge goes through the barrier layer 4 and the conductive substrate 1 to earth, so that an amount of negative charge remains, which is matched to the charge generated by the primary charging on the surface of the photoconductive layer 2, which is the The back of the cover layer 3 is facing, as shown in FIG. 2 (b) shows. In the dark area of the light image into which no light hv is incident, no pair of positive and negative charges is generated in the photoconductive layer 2 so that the high specific resistance is consequently maintained. This induces a degree of negative charging on the surface of the conductive layer carrier 1, which is caused by the primary charging on the surface de. Cover layer 3 generated charge is adapted so

By d <iS the presence of the barrier layer 4 between the conductive substrate 1 and the photoconductive layer 2, the charge carrier migration suppressed between these layers.

Secondary corona charging is then carried out, as shown in FIG. 2 (c). In detail a negative high DC voltage from a voltage source is applied to a corona charger 9 10 applied in order to thereby uniformly charge the surface of the cover layer 3 negatively. In the light area the light image has a negative charge in the cover layer 3 towards the photoconductive layer, so that the charge formed on the surface of the cover layer 3 by the primary charging is not readily can be removed. The surface potential it takes here the Wj: .t of 0 V or a positive one Potential close to this value. Similarly, a positive amount of charge becomes equivalent on the other hand, induces the removed amount of charge in the surface of the conductive substrate 1 becomes in the dark area of the light image as a result of the primary charging on the surface of the cover layer 3 generated charge is easily removed and this surface is charged with negative polarity. Accordingly, an amount of positive charge corresponding to the negative charge of the top layer becomes induced on the surface of the conductive substrate 1

The presence of the barrier layer 4 in the electrophotographic recording material according to FIG The invention reduces the likelihood of leakage under these circumstances of charge carriers between the conductive layer carrier 1 and the photoconductive layer 2 comes

This is followed by irradiation with light hv, as in FIG. 2 (d), positive and negative charges arise in pairs in the photoconductive layer, which lowers its specific resistance Photo-conductive layer 2 has arisen In this way, an electrostatic latent image is generated

In this creation of the latent image, the presence of the barrier layer 4 prevents leakage of charge carriers between the substrate 1 and the photoconductive layer 2, so that a high contrast voltage can be maintained.

Since the barrier layer 4 is provided in order to prevent the migration of charge carriers in the dark in the recording material according to the invention, there is a restriction on the method which can be used to create the electrostatic latent image. If 7. B. a method is provided in which a primary corona charge precedes a corona charge carried out simultaneously with imagewise exposure, as in the so-called new process technique, it is desirable during the primary corona charge a charge of opposite polarity to that of the charge on the free one Surface of the cover layer is opposite to be present at the interface between the cover layer and the photoconductive layer or in a region of the photoconductive layer to the cover layer. When the aforesaid method is applied to the recording material according to the invention, the barrier layer 4 prevents effective injection of carriers into the photoconductive layer, with the result that the contrast voltage obtained is reduced

On the other hand, when a latent image forming method is used, the series after a primary corona charge simultaneously with imagewise exposure, a secondary corona charge and If irradiation is carried out with light, the injection of carriers in the dark should be avoided. And this is effectively achieved with the barrier layer 4, which provides high contrast ;; voltage for Consequence.

A few examples will now be described to illustrate the effects achieved with the recording material to explain.

An aluminum drum with a surface roughness in the order of magnitude is used as the conductive layer support used by 2.0 S. One example is

sis barrier layer is a paraxylylene layer in one thickness of about 0.2 μίτι formed on the drum surface. In a second example, there is no barrier layer. Then a photoconductive layer is in a thickness of about 50 μm by vacuum evaporation of selenium and selenium-tellurium provided in each example. The top layer consists of a polyethylene terephthalate film. Two different recording materials are thus obtained. Another aluminum drum is used as a conductive substrate, which has a mirror-like surface quality with a Has surface roughness of 0.1 S or less. As before, a <* m third example has a barrier layer provided from paraxylylene, which is missing in a fourth example. There is also a photoconductive one in the layer structure Layer provided, which has selenium and selenium tellurium, and a polyethylene terephthalate film as a top layer. There will be two more drawings obtain.

When trying, the surface is in the dark with a corona loading direction to positive and negative Polarity charged and then a sufficiently strong light used for irradiation to make a change determine the surface potential of the recording material.

In the four examples, the recording materials are first charged so that they have a surface potential of -1000 V. They are then irradiated with light from a halogen lamp. In which Example where the aluminum drum has a surface roughness in the order of magnitude of 2.0 S a barrier layer is present, the change in the surface potential of the recording material is 310 V, while the change in surface potential 100 V in the example with a similar one Drum but without a barrier layer according to the prior art.

In the examples in which the aluminum drum has a mirror-like surface quality, so that their Surface roughness is 0.1 S or less, the barrier layer recording material shows a change of the surface potential of 350 V as opposed to a change in the surface potential of 280 V for the recording material without a barrier layer. These experimental results show no Doubt the effectiveness of the barrier.

The recording material with a barrier layer of paraxylylene on the aluminum drum, its surface roughness 0.1S or less is used to show the dependency on the particular for the creation the electrostatic latent image method used. First there is a primary Charge using a scorotron charger with a grid voltage of -2 kV and a Wire voltage of -7 kV to the recording material to charge in the dark. This is followed by an imagewise exposure with simultaneous neutralization an alternating voltage of 6.5 kV. After that, irradiation with light is carried out. The result is a contrast voltage of only 80 V.

When using the recording material of a primary charge by means of a corotron charger exposed to a wire voltage of + 6 kV with simultaneous imagewise exposure and then neutralized by means of a scorotron charger using a grid voltage of - 1.5 kV and then irradiated with light, a contrast voltage becomes in the C-eses set to the above case of 600V received.

In order to determine the aging effect, two conductive layers in the form of drums were produced, in a case with a barrier layer and in a case without a barrier layer. By evaporation in vacuo was a photoconductive layer is provided thereon and a cover layer is provided thereon to cover the recording material to obtain. A method of creating an electrostatic latent image in which a primary corona charge and then a secondary corona charge simultaneously with imagewise exposure and irradiation with light is performed, the recording material was once Done day and once a month after its manufacture. The same parameters were used, Like previously described. The contrast voltages obtained were as follows:

after 1 day after 1 month

without barrier layer 180 V 390 V

with barrier layer 520 V 600 V.

The table shows that with the recording material which has the barrier layer of paraxylylene, possible: st, immediately after its production a To achieve contrast tension, which is practically sufficient.

1 sheet of drawings

Claims (4)

Patent claims: 1. Electrophotographic recording material with an electrically conductive support, a barrier layer, a photoconductive layer and a transparent, electrically insulating cover layer in the specified order, thereby characterized in that the barrier layer (4) is formed from paraxylylene 2. Electrophotographic recording material according to claim 1, characterized in that the barrier layer (4) has a thickness in the range from 0.1 to 1 μΓΠ 3. Electrophotographic recording material according to claim 1, characterized in that the barrier layer (4) is produced by vacuum vapor deposition 4. Contamination of the electrophotographic recording material according to any one of claims 1 to 3 in an electrophotographic process for Production of records.