DE2110553A1 - Electrophotographic imaging process and device for carrying out the process - Google Patents

Description

Patent attorneys Dipl.-Ing. F. Weickmann,

Dipl.-Ing. H. "Weickmann, Dipl.-Phys. Dr. K. Fincke Dipl.-Ing. R A.Weickmann, Dipl.-Chem. B. Huber

8 MUNICH 86, POST BOX 860 820

RANK XEROX LIMITED, möhlstrasse n, phone number «3921/2 ^ Rank Xerox House,
338, Euston Road,
London, NW «1 / England

Electrophotographic imaging method and apparatus for performing of the procedure

The invention relates to an electrophotographic imaging method, in which an electrostatic latent image on an electrically insulating recording medium is used a photoconductive layer is produced, as well as a device for carrying out the method.

Electrophotography usually uses an electrostatic generating a latent image on a recording medium, by electrostatically charging its photoconductive layer and this charge through the action of an imagewise distributed pattern of activating radiation is selectively derived. The electrostatic charge pattern or electrostatic latent image thus formed is usually developed by the deposition of an electroscopic material due to electrostatic attraction, so that a visible image of electroscopic particles, the distribution of which is that of the electrostatic latent Corresponds to the image. In some cases the image thus generated can be transferred to another image carrier.

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In a method of the type described above, a photosensitive layer must be used which has its charge in the dark can save at least up to a lateral point to which the latent image develops or onto another image carrier is transmitted.

The photosensitive photoconductive layer must be electrically insulating in the dark. On the other hand, she has to Radiation exposure to obtain good electrical conductivity. The usual electrophotographic process is So a photosensitive layer is required which can assume mutually opposite properties, i.e. the A good insulator in the dark, a good conductor in the event of radiation. The problem for choosing the for Such a layer of suitable photosensitive materials consists in how far they are their photosensitivity within increase a practically applicable range of insulation properties in the dark.

If, for example, the photosensitive layer is intended to increase the photosensitivity with panchromatic characteristics enable, then at the same time their resistance drops in the dark, because they become thermally free Generates charge carriers that contribute to conductivity. Extending the mean life and increasing the The mobility of the free charge carriers due to the action of radiation also reduces the dark resistance, as it does so likewise the mean life and the mobility of such free charge carriers are increased, which are thermally or otherwise from an electrode or an area made in the dark. As above described, has an increase in the photosensitivity of the photosensitive shoots in the usual electrophotography result in a reduction in the dark resistance,

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as a result, the charge storage capacity also deteriorates in the dark will.

Therefore, if many photoconductors with low insulation properties in the dark and high photoconductivity are used a noticeable increase in photosensitivity in electrophotographic applications is to be expected.

The known electrophotographic process can be used in many modifications to produce the final visible image be performed. For example, the electroscopic powder can be fixed directly on the photosensitive layer. Furthermore, the electroscopic powder can be transferred to another image carrier and fixed thereon. Finally, the electrostatic latent image can also be transferred to another image carrier and there with an electroscopic one Powder to be developed and fixed. However, these types of processes have several disadvantages.

The first type of process is very inefficient because the final image is on the costly photosensitive Recording medium is generated, which can therefore only be used once.

The second type of method requires a complicated cleaning of the recording medium or the removal of the rest electroscopic powder after image transfer. The last type of procedure allows for reuse of a Photosensitive recording medium and unnecessary cleaning, however, has the disadvantage that to achieve a high light sensitivity a high insulating capacity of the layer in the dark, since the electrostatic latent image is formed on the photosensitive layer.

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- ZJ. «-

The object of the invention is to provide an electrophotographic To create imaging method, which the disadvantages of known types of method identified above avoids the properties of high photosensitivity and allows high charge storage capacity to be combined and thus enables the generation of an electrostatic latent image which is stable even when exposed to light. Further it should be possible to use a photosensitive element repeatedly and without cleaning.

An electrophotographic method of the type mentioned at the beginning is such according to the invention to achieve this object designed that both surfaces of the recording medium with mutually opposite polarity electrostatically are charged and that the photoconductive layer is brought into contact with the recording medium and imagewise exposed and at the same time exposed to the action of charge carriers.

A device for carrying out the method according to the invention is characterized in a further development of the inventive concept by an arrangement for electrostatic Charging of the two surfaces of an electrically insulating recording medium with opposite sides Polarities, through an arrangement for bringing the recording medium together with a photoconductive layer and by an arrangement for simultaneous image exposure and the action of charge carriers on those with the recording medium layer in contact *

The latent image produced by the method according to the invention can be developed when the recording medium is in contact with the photosensitive layer. Furthermore, a uniform illumination of the

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photosensitive layer before image development. Finally, there can also be a development of the latent image after the light-sensitive layer has been illuminated and the recording medium has been detached from it.

The invention is described below with reference to the figure, which shows an embodiment of a device for performing the method according to the invention in section.

In the figure, a photosensitive element 1 is shown in the form of a drum, which consists of an electrically conductive Base 2 and a photosensitive layer 3 applied thereon. The drum turns clockwise rotated in the direction of the arrow shown. The conductive base 2 is earthed. From a role 5 becomes a transparent and electrically insulating tape 4 is guided onto a take-up roll 6 in the direction of arrow A shown. The speed of the belt corresponds to the peripheral speed of the drum 1. The relative speed both elements to each other therefore has the value zero at the point of contact. The insulating tape 4, which is from the Roll 5 is removed, is charged with two corona discharge electrodes 7 and 8 electrostatically. The charge polarities on the two faces of the tape are mutually exclusive opposite. In the case shown, charging takes place in a known manner. The top surface of the belt is aligned with the Electrode 7 positive, the lower surface of the strip with electrode 8 charged negatively. That the band is so charged with the surface of the photosensitive layer 3 of the drum 1 in touch. Negative ions, which are generated with an electrode 9, act on the surface of the At the same time a light image to be reproduced is applied to the belt and the drum through the electrode 9 projected.

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The light pattern projected on the photosensitive layer 3 is arranged stationary relative to the surface of the drum.

An electrostatic generated by this method on the belt 4 latent image is developed with a developing device comprising a developing brush 10 and a Includes roll 11. Then, the developed image is fixed with a fixing device including an infrared heater 12 and a belt conveying mechanism 13 includes. This creates a permanent image on the tape. Then the tape out on the take-up roll 6.

The photosensitive drum 1 consists of an electrically conductive base 2 and the photoconductive layer 3 » which is sensitive to light. The pad acts as an electrode for the photoconductive layer.

If the photoconductive layer has sufficient mechanical strength, it is not always necessary to use a support necessary. In this case, however, the reverse side of the photoconductive must be used for the simultaneous charging and image exposure Layer are in contact with an electrically conductive electrode, or an ion source must be placed on it, ) act, for example, a corona discharge. The base can also be transparent when the image is exposed through it should take place through it.

In general, the base is in the form of a cylinder, plate or ribbon and is made of a metal such as aluminum, brass, nickel or stainless steel or from one of the synthetic plastics.

If an electrically non-conductive base made of plastic is used, it must have a conductive surface.

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be seen.

The photoconductive layer preferably has a high photoconductivity, it does not have to be very good insulating in the dark, since the charge storage in the dark does not is required. Preferably, however, is a material with to use higher dark resistance.

Will only be briefly charged and exposed at the same time carried out, a photoconductor with a lower resistance can also be used.

If the duration of the process is, for example, 0.01 second, a photoconductor with a specific Resistance on the order of 10 ohm cm can be used. This shows that in the method according to the invention, too Photoconductors that cannot be used in known xerography can be used.

If the time period of the method according to the invention is shorter than 0.01 seconds, then materials with a resistance lower than 10 ohm cm can also be used. The following elements can be used: Si, Ge, Sn, P, As, Sb, S, Se and Te, also the halide or chalcogenide, in particular the oxide of Gu ₅ Ag, Sr ₁ Ba, Zn, Ge, Cd, Si, Hg, Al, In, Ga, Tl, Sn, Mn, Fe, Ni, Fb _t Ti, As, Sb and Bi as well as compounds with these metals and anionic elements, for example Gd _x , Zn _1-3 S, GdS _y , Se ^ _y , Gd _x Zn _1-35 ., S _y , Se _1- ^ and the intermetallic compounds such as OuAlS ₂ ,, AgInS ₂ , ZnSiAs ₃ , ZnGeP ₂ ,, GdGeP ₂ ,, InSbI ₁ as well as the alloys with the following Elements As, Sb, Pb, S, Se, Te, Tl, Br and I with the crystalline or glassy phase of various organic photoconductors. These substances are used alone or in combination. Is it such

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Substances that do not form a film are used in a binder used in dispersed form, for which purpose organic and / or inorganic polymers can be provided as binders. It a photoconductive binder can also be used. A glassy material such as As-Sb-Se can be used as photoconductive layer also a metallic base produced by vacuum evaporation or pouring from a melt will. Powder particles made of hexagonal cadmium sulfide, which have a high photoconductivity, can be mixed with cadmium chloride fired as fluxes to form a sintered photoconductive layer on a metal plate. The very sensitive, fine cadmium sulfide particles, which are sensitized with dye, are in a synthetic, organic Polymer binder dispersed and applied as a layer on a metal plate so that they form the photoconductive layer. The binder used can also be photoconductive.

The sensitivity spectrum of the photoconductive layer is selected according to the intended use. Preferably a panchromatic sensitivity is applied to the source of visible light. To do this, the photoconductive Layer sensitized by adding a small amount of sensitizing agent or sensitizing dyes will. It is also possible, in addition to visible light, to use ultraviolet light, X-rays, infrared light, etc. to use.

The electrically insulating recording medium (the tape M-) is preferably electrically insulating at least in the dark, since an electrostatic latent image is generated on it. However, it can also be insulating when exposed to light. If the latent image produced on it is developed shortly after the process has been carried out, the recording medium need not have a very high insulation value.

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Bas electrostatic generated on the recording medium latent image can be transferred to another recording medium will. In a departure from the representation in the figure, the image can then be developed on the other recording medium and fixed, or it is transferred to and on another image carrier after development fixed.

If the generated image is fixed directly on the recording medium, the recording medium becomes the final one Image carrier. As a result, some requirements are placed on the recording medium, for example a white color, a glossy surface, opacity and sufficient strength.

Since the recording medium is an essential factor in the invention Procedure, he must meet some minimum requirements. Of course it has to be electric be isolating. Furthermore, it should preferably have a uniform thickness. The value of this strength is preferable such that the recording medium has the same capacity as the photosensitive layer. In general is a thickness in the range of 10 to 100 microns is suitable for this. If the thickness is less than 10 microns, it is very difficult to to generate sufficient contrast potentials that enable the latent image to develop. With a strength of more than 100 microns, the resolution becomes so low that the recording medium is suitable for image formation is no longer suitable for f ^ ut.

The recording medium must also be transparent at least for the light which is used for the image exposure by projection of the image on the photosensitive layer through him is used through it.

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If the recording medium is completely opaque, then so the image can also be projected through the base of the photosensitive layer onto the latter.

The requirements outlined above are met, for example, by the following substances: well-dried Paper, coated paper, plastic wrap, plastic tape, plastic film, and synthetic paper.

As already stated, the recording medium becomes electrostatic on both sides with different polarity charged before the image is created.

This charging is carried out, for example, with a corona double discharge device. The charge polarity is determined by the value f ^ X of the free charge carriers in the photoconductor used, with JU being the mobility and T being the mean life. If the value / j ~ X for the free electron is greater than the corresponding value for the free defect electron, the side of the belt which does not come into contact with the photoconductive layer is positively charged. If there is no correlation between the values, the charge is reversed. The aforementioned charge polarity only applies when the light image is projected through the insulating tape.

If the light image is projected through the substrate of the photosensitive layer, the opposite occurs, i.e. if the value μ, Χ of the free electron is greater than the corresponding value of the defective electron, the mentioned side of the insulating tape is negatively charged if this relationship does not exist so it is positively charged. This choice of charge polarity is not always binding, but it can be used as a general rule. If radiation is used instead of visible light, for example, X-ray

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radiation is used, this rule is not unconditionally valid, the same applies to the use of infrared light.

The charge density generated on the side of the tape facing away from the photosensitive layer should preferably match the Charge density on the other side of the belt match, but this is also not absolutely necessary.

In the second step, the insulating tape comes with the surface of the photoconductive layer on the drum in contact and is exposed to a light image to be reproduced. At the same time it comes under the influence of charge carriers. The exposure or the effect of the charge carriers can begin beforehand and last for different lengths of time. In this second process step, the effect of the charge carriers through a flow on the surface of the insulating The tape is created while the conductive pad on the other side of the photosensitive layer is grounded is. If no conductive base is used, it must Charge carrier flow or a conductive element are brought into contact with the photoconductive layer in order to achieve the to ground the other side of this layer at least during the second process step. Due to the action of the charge carriers On the surface of the electrically insulating tape, an electrical circuit is established between the surface of the belt and the side of the photosensitive layer facing away from it.

. The second, e process step can be carried out in such a way that this circuit occurs when the charge carriers act the tape is closed.

The effect of charge carriers can be, for example, an electron flow, an ion flow or an ion cloud

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in gas, a flow or cloud of charged particles in gas, an ion flow or ion cloud in a liquid or generated by a flow or cloud of charged particles in a liquid. An ion flow or Ion cloud in gas can be generated, for example, by a corona discharge fed with alternating voltage or direct voltage take place.

A light image to be reproduced can also be projected through the support of the photosensitive layer. One of the known methods used in xerography can be used for this purpose. The following procedure is just an example. Here, the light image is generated as shown in the figure, that an original 16 with a light source 15 is illuminated through a slot 17 will. Projecting optics 14 are used to project the reflected light. In the area of image projection an ion cloud is generated on the photosensitive layer with a corona discharge device. The original 16 is arranged stationary, while the projection optics 14, the lighting slit 17 and the light source 15 relative to be moved to the original. The photosensitive layer 3 and the insulating tape 4 are perpendicular to the direction of the light rays generated by the projection moved.

In this second step, an electrostatic latent image is created on the surface of the insulating tape, this is then peeled from the photosensitive layer so that the latent image can be developed. Shortly before the tape is detached, the light-sensitive layer can be illuminated evenly.

In the following examples I to V there are various possibilities for the formation of a photosensitive element described which, for example, on a drum 1 in the

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Figure shown type can be used.

EXAMPLE I

A photosensitive element was made by placing a vitreous layer of arsenic triselenide of approximately 70 microns Starch applied in vacuum in the form of the photosensitive layer 3 to the cleaned surface of an aluminum cylinder which formed the conductive base 2. Thus, a photosensitive member such as it is shown as drum 1 in the figure.

The glassy layer of arsenic triselenide is photoconductive and sensitive to visible light, it was after charged by the usual electrophotographic process.

EXAMPLE II

Another photosensitive element was manufactured as follows: The polished and cleaned surface of an aluminum tube was provided with an approximately 80 micron thick layer of a vitreous alloy consisting of 15% tellurium and 85% selenium. The selenium-tellurium layer was photoconductive in visible light, but its dark resistance was too low to be able to be charged in the dark using the usual electrophotographic process. According to the process according to the invention, however, it could be used as a panchromatic photosensitive layer.

In this layer, the above-described value for the free hole was slightly larger than that for the free electron.

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EXAMPLE III

Another photosensitive member was made as follows produced: A glassy layer of an alloy of 25 parts arsenic, 10 parts antimony and 4-9 parts selenium applied '.

The layer thickness was approx. 4-0 microns. The glassy layer was photoconductive in visible light, its dark resistance was for charging according to the usual electrophotographic Procedure too low. The above-described value for the free hole was also slightly larger than that for the free electron.

EXAMPLE IY

Another photosensitive member was prepared as follows: Specially treated photoconductive particles were dispersed in an insulating synthetic resin binder, and the dispersion was coated on a glass cylinder. The photoconductive particles were formed by firing 18 parts of cadmium iodide and 82 parts of fine particles with cores made of cadmium carbonate and shells made of cadmium sulfide, CdS.1.5CdCo ₅ , for about 20 hours at 200 to 250 ° C and this mixture with 0.1 part of the sensitizing dye malachite green. The photoconductive particles thus prepared were dispersed in 50 parts of a thermosetting acrylic resin varnish using organic solvents to form a photosensitive ink. This was then coated onto the substrate, dried and heated for about 30 minutes at 15O ⁰ C, so that a photoconductive layer of about 50 microns resulted in strength. The base used was a glass cylinder, the outer surface of which was provided with a thin, electrically conductive tin oxide layer. The photosensitive layer showed iOtoconductivity in the visible

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Light, its value liT " for the free electron was slightly larger than that for the free defect electron. When this light-sensitive element was used, a light image could be projected through the glass substrate.

EXAMPLE V

Another photosensitive element was prepared as follows: 100 parts of the photoconductive particles prepared according to Example IV were dispersed in 30 parts of an acrylic resin varnish which dries at room temperature with the aid of organic solvents. The photosensitive paint thus prepared was coated on a base and dried to form the photosensitive element. The thickness of the photoconductive layer was approximately 4-0 microns. The base used was a polyethylene terephthalate film, the surface of which was treated with copper iodide for electrical conductivity. The photosensitive element produced in this way could be exposed through the substrate, since it was transparent. The photosensitive layer was photoconductive in visible light; its ICC value for the free hole was slightly smaller than that for the free electron. The element was flexible so that it could be used as a tape or flexible sheet.

The following Examples A through C relate to the use of a Device of the type shown in the figure in the modification that a drying device for paper sheets before the corona discharge electrodes 7 and 8 is arranged.

EXAMPLE A

An approximately 4-5 micron thick transparent cellulose triacetate film was used as the electrically insulating tape. At the corotron 7 was a direct voltage of -5 kV, to the

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Corotron 8 applied a DC voltage of +6 kV, creating a negative charge on the upper side of the belt A positive charge was generated on the underside. The following amounts of charge resulted: The potential of the upper side was if the underside comes into contact with a conductive and earthed body approx. -1000 volts, the potential of the underside when touching the top with a conductive and earthed body approx. +500 volts.

A photosensitive element was used consisting of a glassy selenium-tellurium layer on an aluminum tube duration. The thickness of the photoconductive layer was approximately 80 microns. The contact of the charged tape with the surface of the photosensitive member was carried out to generate positive charges on the negatively charged surface of the tape with a DC voltage of +8 kV on the corotron 9 "simultaneously" passed through the corotron projects the image to be reproduced. The corotron 9 was constructed in such a way that fluoroscopy was possible. As a project ion process en a scanning process was used in which the belt and the photosensitive element with coincidence Speed were moved and their relative speed to each other had the value zero. The speed was approx. 25 cm / sec. The opening of the corotron 9 had a width of approx. 15 mm, the width of the slot was also 15 mm. The tape was then sensitive to light Surface peeled off one second after charging and exposure. The surface potentials of the electrostatic latent images on the tape were approx. +850 volts in the light areas and approx. -20 volts in the dark ones Surface parts, their measurement was carried out when the back of the tape touched a grounded and conductive body. Thereafter, the latent image was developed with a known type of magnetic brush provided with electroscopic particles.

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During development, the back of the tape was in contact with a grounded roller. Then that was developed Image fixed in the usual way to give a permanent image on the transparent tape. The light sensitive Element was reimaged without any further treatment after it was detached from the tape.

EXAMPLE B

This example used electrically insulating synthetic paper sheets that were white and opaque and made of high density polyethylene with titanium oxide particles.

In the first process step, charges were generated on the two surfaces of the leaves, the surface potentials being approximately -1100 volts on the upper side and + 1500 volts on the lower side, for which purpose a measurement of the type described above was carried out. In the second method step, the 3® ^w piece sheet was brought into contact with a photosensitive member into contact, which consisted of a glassy layer containing an arsenic, antimony and selenium alloy on a NESA glass plate. The light image was then projected onto the photosensitive layer through the NESA glass plate and at the same time the upper side of the sheet was brought into the action area of a positive corona ion source, for which purpose a movable corona discharge device was moved over the upper side of the sheet. It was fed with a DC voltage of 8.5 kV. The light intensity on the photosensitive layer was approx. 5 lux, and the speed of movement of the discharge device was approx. 20 cm / sec. After exposure to the ions, the exposure was terminated, and after a further second the sheet was peeled off. In this process step, the detachment can also take place during the exposure.

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The electrostatic latent image thus formed was developed and fixed. The photosensitive element could can be used repeatedly without further treatment after the leaf has been detached. According to a modification of the procedure the electrostatic latent image could be transferred from the sheet to another image carrier sheet. That with The image developed by electroscopic particles could be transferred onto a normal sheet of paper.

EXAMPLE C

In this example, normal paper sheets were used as the electrically insulating sheets. It was basically that Process shown in the figure carried out. Additionally a drying device was provided for the respective paper sheet just before the corotrons 7 and 8, with which the paper sheets dried prior to electrostatic charging. The surface potential of both surfaces of the respective sheet was approximately 500 volts and was measured as described above. The top of the sheet was positively charged. A NESA glass cylinder was used as the photosensitive element, which is coated with photoconductive particles made of CdS-CdGO which were color sensitized and dispersed in a synthetic resin binder. In the second process step the image exposure was through the NESA glass backing made, the ions were with the corona discharge device applied to the top of the paper sheet »A negative polarity of the corona discharge was used .

After this imaging, the photosensitive element was evenly illuminated, then the sheet of paper was covered by replaced him in order to develop the latent image. According to a variation of the method, the latent image could also be developed while the sheet of paper is in contact with

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the photosensitive element.

The invention is not restricted to the examples described above. It consists of a process in which an electrically high-contrast latent image is generated on the electrically insulating recording medium. It can be a photoconductive material may be used, which is not suitable for ordinary electrophotography. The light sensitive Element can be used repeatedly without any special further treatment, for example without cleaning its surface. For this purpose, the two surfaces of the recording medium During the first process step it is electrostatically charged, then it comes into contact with the surface of the photosensitive Layer brought, after which simultaneously charge carriers and an image-wise distributed radiation on the photosensitive Act on the layer.

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Claims (9)

Patent claims ^ iJ Electrophotographic imaging process in which a electrostatic latent image on an electrically insulating recording medium using a photoconductive Layer is produced, characterized in that both surfaces of the recording medium (4) coincide with one another opposite polarity are electrostatically charged and that the photoconductive layer (3) with the recording medium (4) brought into contact and exposed imagewise and at the same time exposed to the action of charge carriers will. 2. The method according to claim 1, characterized in that the recording medium (4) with the electrostatic generated on it latent image is detached from the photoconductive layer (3) and that the latent image is transferred to another image carrier is transmitted. 3. The method according to claim 1, characterized in that the recording medium (4) with the electrostatic generated on it latent image is detached from the photoconductive layer (3) and that the latent image on it becomes one visible image is developed. 4. The method according to any one of the preceding claims, characterized in that the action of charge carriers with a corotron (9) which is transparent for the image exposure, and that one for the image exposure permeable recording medium (4) is used 5 * Method according to one of claims Λ to 3, characterized in that the image exposure from which the recording 109840/1545 The side of the photoconductive layer (3) facing away from the carrier (4) is carried out. 6. Electrophotographic image made by the process according to one of claims 1 to 5 7. Device for performing the method according to a of claims 1 to 5 »characterized by an arrangement (7 »8) for the electrostatic charging of the two surfaces of an electrically insulating recording medium (4) with mutually opposite polarities, by an arrangement (1, 5 »6) for bringing together the recording medium (4) with a photoconductive layer (3) and an arrangement (9 | 14, 15 »16» 17) for simultaneous image exposure and Effect of charge carriers on the layer (3) in contact with the recording medium (4). 8 · Device according to claim 7 »characterized in that a corotron for generating charge carriers which act on the photoconductive layer (3) during the image exposure (9) is provided, which is transparent for the image exposure. 9. Apparatus according to claim 7 »characterized in that an exposure device on the image exposure the side of the photoconductive layer (3) facing away from the recording medium (4) is arranged. 109840/1545 Lee r side