DE2409667C3 - Process for generating a charge image on the insulating layer of a recording material - Google Patents

Description

The invention relates to ^ in method of im The preamble of the claim referred to in Art.

This method known from DE-OS 15 22 567 can be modified according to one embodiment in such a way that the photoconductive layer is totally exposed at the same time as the first uniform charging of the P: "tte. In this Au ^c Guide e "sForm of the known method but the electrically conductive substrate of the recording material is characterized by ^e. Ne second insulating layer replaced Preferably, corona discharge devices used opposite polarity at the first uniformly charging two, wherein the corona Entladungseinrichturig over the insulating Cover layer and the other corona discharge device are passed over the other insulating layer. According to a modification of this known embodiment, however, one of the corona charging devices can also be replaced by a grounded and electrically conductive base plate on which the recording material is placed In this embodiment of the known method, the two insulating layers are charged to different polarities. The simultaneous and uniform exposure of the photoconductive layer is carried out to increase the polarizing charge However, it was found that when charging and uniform exposure are carried out at the same time, even in the case of high-intensity exposure, the charge on the surface of the recording material does not become Nu I but still retains a finite residual value. However, this remaining residual value of a potential leads to a loss of contrast in the subsequent generation of a charge image. This rejection of an electrophotographic recording material applies to uniform charging to both a positive and a negative potential,

From DE-AS 14 97 164 and DE-OS 17 97 243 and 19 63 615 are known methods that a recording material from an electrically conductive Support, a photoconductive layer and an insulating cover layer on the photoconductive layer use. These known methods have in common that, while a constant electric field is effective, in the photoconductive layer sufficient conductivity is generated at its interface to insulating cover layer to accumulate sufficient charge within the photoconductive layer.

The object of the invention is to develop a method of the type mentioned in the preamble of the claim so that that the contrast tension of one on the

ίο recording material still generated charge image is bigger

In a method of the type mentioned, this object is achieved by the invention specified in the claim solved

Experiments have shown that the additional specified in the claim A process step of total exposure before the imagewise exposure resulted in an increase in the contrast voltage compared to the method known from DE-OS 15 22 567, for example, is particularly large when a photoconductive material is used with the composition specified in the claim.

Value χ

0.95 0.9

Contrast tension a 210 250

Contrast tension b 300 350

In this table, the contrast voltage a denotes the maximum potential difference between the image areas and the background areas of the charge image in the method known from DE-OS 15 22 567, while the contrast voltage b indicates this same potential difference in the method according to the invention. From these values verified by the tests, it also follows that with the composition of the photoconductive layer specified in the patent claim, the contrast voltage achieved by the additional process step is particularly high. Through the simultaneous application of the additional process step as, for the particular composition of the photoconductive layer, a synergetic effect is achieved with regard to the maximum achievable contrast voltage of the charge image.

4 ") Preferred embodiments of the invention are explained on the basis of the drawing. It shows

Fig. 1 is a section of an embodiment of the recording material used in the method according to the invention,

■) 0 Fig. 2 shows a section of a second embodiment of the recording material used.

3 shows a section of a third exemplary embodiment of the recording material used, and FIG
4 to 7 the first to fourth method steps

«In connection with the first embodiment of the Recording material.

In Fig. 1, an insulating cover layer 1 is made of an insulating organic material in the form of a film applied to a photoconductive layer 2, the

ho dispersed in an organic resin binder Contains cadmium sulfide particles. The photoconductive layer 2 carrying the insulating cover layer 1 is on an electrically conductive one! Layer carrier 3, e.g. B. one Metal foil or plate applied. Since a photoconductive material is to be used in the method according to the invention, which is not noticeably permanent shows internal polarization, zinc sulfide and phosphorus are not to be used here. If, in the case of the

If zinc sulfide in solid solution is used with cadmium sulfide, this is the ratio range between the two substances is limited to 1> x> 0.7, the solid solution being defined by the expression (De, ΖΠ (ΐ -,)) S is given.

A second exemplary embodiment of the recording material used is shown in FIG. 2 shown where two photoconductive intermediate layers 5 and 6 between an insulating cover layer 4 and an electrically conductive substrate 7 are arranged. The insulating cover layer 4 and the electrically conductive layer carrier 7 can consist of the same material as that in FIG. 1 illustrated first embodiment. The intermediate photoconductive layers 5 and 6 are similar to the photoconductive layer 2 of the first Embodiment, however, they differ in terms of the properties of the binder contained photoconductor and with regard to the properties of the binder.

A third embodiment of the recording material used is shown in FIG. 3 shown in the an insulating layer ok between zsvei foiüieitbaren Intermediate layers 9 and 11, which are similar to those in the second embodiment shown in FIG are used, is arranged. On a photoconductive layer 9 is an insulating cover layer 8 is applied and an electrically conductive layer substrate 12 is applied to the other photoconductive layer 11 applied, similar to those as in the exemplary embodiments shown in FIGS are used. Both the electrically conductive substrate 12 and the first and second Embodiments used layer carriers 3 and 7 serve as an electrode. Since that According to the method of the invention, recording material used no permanent internal polarization is used, the photoconductive layer can be formed from two layers of different properties. In addition, an insulating layer can be placed between the two photoconductive layers. Finally, it is not necessary to have an insulating barrier between the electrode and the photoconductive one Provide a layer to prevent the injection of electrons between the two.

The method according to the invention for generating a charge image comprises four method steps, namely uniform charging, total exposure, imagewise exposure with simultaneous uniform charging and another total exposure.

In Fig. 4 becomes the recording material described above by means of a corona charging device 13, which is applied over the surface of the recording material is moved away, a direct current corona discharge is maxed out. The electrically conductive substrate 3 is grounded. During this uniform charging, the recording material becomes in the dark held. The polarity of the charge applied to the surface during this uniform charge can be negative or positive, but it should preferably be positive when the The photoconductor used is an n-type semiconductor. In a procedure that is permanent If internal polarization is used, the polarity of the first charge must necessarily be positive. at The process according to the invention, on the other hand, can be used The polarity of the charge can also be negative, since the effect of the permanent internal polarization is here is not used. The purpose of uniform charging in this process step is to to increase the contrast of the charge image, the surface potentials of the black and white

To bring image areas to the desired potential values in order to transfer the image and the To facilitate cleaning of the toner image remaining on the recording material and around the Movement of the resulting total exposure

ίο generated free electrons by generating a To facilitate internal electric field in the photoconductive layer.

In Fig. 5 the recording material is completely exposed. This total exposure is particularly necessary in a photoconductor with trapping energy levels to produce permanent internal polarization. Through this total exposure, the trapping energy level is filled and the potential is photoconductive Layer is essentially reduced to zero. That way, you stay with the first Process step generated polarized charges back only in the insulating cover layer. Therefore will the internal electric field of the photoconductive layer eliminated and the original state of the photoconductive Layer is restored when the signature material is subjected to the following process step. That in the invention Method used recording material has an insulating cover layer on its surface as it is exposed to a total exposure in the second process step. This would namely reduce the effect of the Eliminate uniform charging during the first process step if the insulating cover layer would not be provided. Even if this insulating cover layer is provided, a However, a charge image cannot be generated unless a charge is carried out simultaneously with the imagewise charge Exposure would take place. This is based on the fact that in the method according to the invention a photokitable Layer is used in which there is no permanent internal polarization to generate the charge image is used.

In this second process step, in which the surface is totally exposed, the light source should preferably not emit infrared radiation. This makes the photoconductive layer highly sensitive made by filling the trapping energy levels with charge carriers. When the photoconductive Layer would be exposed to infrared radiation, the charge carriers jump out in the trapping energy levels these levels out and the levels would be emptied, resulting in reducing the photosensitivity of the photoconductive layer would lead. This procedural step cannot be omitted even if if the charging in the first step is carried out with light, because the photoconductive layer is exposed to an electric field in the first process step and accordingly the polarized charges are also present in the layer if the photoconductive shoe is uniform during the first Charge is exposed. Due to the presence of the polarized charges in the photoconductive p. Layer, it is very difficult to bring the potential of the photoconductive layer to the value zero.

This means that the influence of the low trapping energy level (Ui) in the photoconductor is not eliminated especially when the amount of light is controlled during exposure or when the

Charging time in the first process step is not long enough.

In FIG. 6, the recording material is exposed imagewise and, at the same time, is uniformly charged. In this process step, the uniform charging can take place either by means of a direct current or alternating current corona discharge. The recording material should preferably be exposed to a direct current corona discharge with negative polarity; when the photoconductor is an η-type semiconductor. As a result of the simultaneous imagewise exposure and charging, a charge image is generated in the insulating cover layer and in the photoconductive layer. In Fig. In 6, reference numeral 14 denotes a direct current corona charger, and reference numeral 15 denotes a negative film and the like for generating the imagewise exposure, the transparent part i5s transmitting the light and the impermeable part 15b blocking the light. The photoconductive layer 2 becomes electrically conductive and the potential of the layer is made zero in the area in which it receives light. In the area in which the photoconductive layer does not receive any light, polarized charges are generated and a potential difference arises between the exposed area and the unexposed area of the recording material, whereby a charge image is generated in this way.

In FIG. 7 is totally exposed as the recording material bearing the charge image. Because of the total exposure the contrast of the charge image is increased. The light source used in this process step should infrared radiation, which has the effect of forcing electrons out of the trapping energy levels, and visible light radiation which has the effect of increasing photoconductivity. at In this process step, the polarized charges in the photoconductive layer become fast neutralized and eliminated This fourth process step of total exposure is then not necessary, if, for example, the development or the image transfer following the formation of the charge image is carried out in the light. In addition, when developing or transferring images after a Duration of more than 60 seconds after the generation of the charge image is carried out, the fourth process step of total exposure is not required, since the polarized charges through the Dark waste in the photoconductor can be neutralized.

The uniform charging of the first step has been found to be effective Increase in the contrast of the charge image. Experiments have also shown that the The longer the charging time, the greater the contrast of the charge image. In addition, the charge image therefore generated by imagewise exposure and simultaneous charging on the insulating cover layer the insulating cover layer does not need to be in contact with a grounded, electrically conductive electrode to be brought so that the charge image cannot be erased.

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

example 1

35 g of a commercially available cadmium sulfide Foioieiters were applied in polyvinyl butyral, diluted in a thinner, then dispersed in the form of a layer on a polyester film with a thickness of 25 μm and a size of 1000 cm ² and then dried. An aluminum laminate paper for producing an electrophotographic recording material was stuck thereon. The recording material was first exposed to a DC electric field by means of positive corona charging and charged uniformly and then totally exposed to bluish-white luminescent light. The plate was then exposed imagewise for 2 lux seconds and exposed to an electrical direct current field of negative polarity by means of negative corona charging. A paper impregnated with a synthetic resin was pressed onto the recording material by means of a roller. A visible toner image was obtained on the paper by applying negatively charged toner to the paper impregnated with the synthetic resin.

Example 2

18 g of a photoconductor of the chemical formula (0.3 Zn, 0.7 Cd) -S: Cu, Cl were dispersed in a polyvinyl acetate diluted in a butyl acetate, then on a polyester film with a thickness of 6 μm and a size of 1000 cm ² applied in the form of a layer and dried. A polyester film with a thickness of 6 μπί was applied to the surface in contact with it In the form of a layer avf the polyester film applied to the other polyester film is applied. Thereafter, an aluminum laminate paper was attached to it as an electrically conductive support, which served as an electrode, as shown in FIG. 3 is shown. After a direct current field had been applied to the recording material by means of a negative corona discharge, it was totally exposed to bluish-white luminescent light. The recording material was then exposed imagewise for 4 lux seconds and at the same time exposed to a negative polarity by means of a negative corona charging device. The recording material was then totally exposed by means of an incandescent lamp. A visible image was obtained on the surface of the recording material by applying a negatively charged toner.

Example 3

It became the recording material used in Example 2 and a direct current field by means of a positive corona charger exposed After performing the same process steps as in Example 2, a visible Image was obtained which reproduced the light image with which it was exposed.

Example 4

15 g of a photoconductor of the chemical formula (0.1 Zn, 03 Cd) -S: Cu, Cl, were dispersed in a polyvinyl acetate diluted in a butyl acetate and in the form of a layer on a polyester film with a thickness of 6 μm and a size of 1000 cm ² applied. Then, 20 g of a commercially available cadmium sulfide film was dispersed in an epoxy resin diluted in a thinner and placed in the form of a layer on an aluminum laminate paper with a size of 1000 cm ²

applied and dried at room temperature. The above-prepared two films were as shown in Figure 2, miteinener connected by being dried for 30 minutes at 15O ⁰ C. The recording material produced in this way was exposed to a direct current field with a positive corona charging device and then totally exposed to the light from a bluish-white luminescent light source. Then it was totally exposed to a bluish-white luminescent light. A colored visible image was obtained using a colored developer. The density of the developed image was substantially uniform.

Example 5

22 g of a photoconductor of the chemical formula (0.05 Zn, 035 Cd) -S: Cu, Cl were dispersed in an epoxy resin diluted in a thinner and in the form of a layer on a polyester film with a thickness of 6μπι and a size of 1000 cm ² applied for 5 hours and then dried at 5O ⁰ C. In addition, a photoconductor of the formula CdS: Cu ₁ Cl with a large dependence of the dark current on the applied voltage, dispersed in a polyvinyl acetate diluted in a butyl acetate, was applied in a layer as in FIG. As shown in Fig. 2, an aluminum plate was attached thereto as a substrate or electrode to form the recording material. This was positively charged using a positive corona charger. Then it was totally exposed to bluish-white luminescent light. It was then exposed to a color film with different color sections from blue to red and at the same time negatively charged by means of a negative corona charger. Then, the recording material was totally exposed to the light of an incandescent lamp. When a colored developer was applied, a visible colored image having a substantially uniform density was obtained.

Example 6

The procedure described in Example 1 was carried out using the same recording material performed repeatedly. During the repetitions, images of the the same quality as the image created at the beginning.

Example 7

In the method described in Examples 2 to 5, the developed image was by means of a Fur brush extinguished and all procedural steps, starting with positive charging, were carried out lä repeated. The repetitions were each on images of the same quality can be obtained from the same recording material.

Example 8

18 g of a photoconductor of the chemical formula (0.3 Zn, 0.7 Cd) -S: Cu, Cl were dispersed in a polyvinyl acetate diluted in a butyl acetate, then in the form of a layer on a polyester film with a thickness of 6 μm and a size applied from 1000 cm ² and dried. A polyester film with a thickness of 6 μm was applied to the surface in contact with it. Then 18 g of a photoconductor of the formula CdS: Cu, Cl with a slight dependence of the dark current on the applied voltage were dispersed in a polyvinyl acetate diluted in a butyl acetate and applied in the form of a polyester film. Thereafter, as shown in FIG. 3, an aluminum laminate paper, which served as an electrode, is attached as an electrically conductive support.

After applying a direct current field to the recording material by means of a negative corona discharge this was totally exposed with bluish white luminescent light Lux seconds exposed imagewise and at the same time

• to one by means of a corona charging device Then the recording material was exposed to an alternating current corona discharge field Incandescent lamp totally exposed by applying a negatively charged toner to the surface Obtain a visible image of the recording material.

For this purpose 2 sheets of drawings

Claims (1)

Claim: Process for generating a charge image on the insulating layer of a recording material from an electrically conductive layer support, a photoconductive layer and an insulating layer Cover layer on the photoconductive layer, the photoconductive layer of which is mainly made up of copper activated cadmium sulfide and a binder, in which the top layer is uniform with charged with a first polarity, then with simultaneous imagewise exposure of a corona discharge with opposite polarity to the first charge and then the photoconductive one Layer is totally exposed, characterized in that a recording material with a photoconductive layer of the composition (Cdi, Zn (I-X)) S, with l> x> 0.7 and the photoconductive layer after the primary charge, before the imagewise exposure, totally exposed will.