DE2034239C3 - Electrophotographic device for producing a charge image - Google Patents

Description

ejector. of about. 600 elements per rf. de ^ ge ^ r, ~

2. Device according to claim 1, thereby the point electrodes without additional insulating material

indicates that the Punkielektroden from copper free from the converter layer protrude D, it ermog-

fer with rhodium vapor-deposited on it. 20 light e.ne simplified production and allows the

^{& Y} accommodation of a sufficient number of

Point electrodes per unit area, so that the

dunusbüder with a high resolution

and good contrast can be recorded,
as if the point electrodes made of copper with on it

The invention relates to an electrophotographic vapor-deposited rhodium, the Einrich-

Device for the production of a charge formation device against repeated use more permanent

made by biidiform charging of an insulating Auf-.

The invention is described below on the basis of an in

tendon, on a transparent electrically conductive 30 of the drawing shown exemplary embodiment

Layer support arranged photoconductive layer explained in more detail. It shows

as a charging electrode and a counter electrode, between F i g. 1 is a schematic representation of the

see which the recording material to arrange the invention applied Arboispiinzips and

is. Fig. 2 is a schematic representation of an electrical

From the German Offnlegungssehrifi 1472 916 35 trophotographic device according to the invention

it is known to create an insulating layer by means of opto-dung.

electronic transducer elements, which consist of charge-transferring elements. 40 Jen layer 3. A photoconductor ßigen exposure is applied to layer 3. of the photoconductive elements of the vapor deposited, for example Se, ZnO, CdS, ZnS or matrix. The disadvantages of such a projection screen-N-polyvinylcarbazole or a mixture of these lers lie in a very complicated and practical materials with a manufacturing method consisting of synthetic resin which cannot be carried out. In a binder. It is also possible to make such materials. Plate made of insulating material must be made transversely to the plate or a mixture of these must be drilled in a solvent, and the solution should be removed to the electrically conductive number of that required for the image conversion. Layer to apply in this way a photo-desired grid is dependent. In order to achieve a conductive layer 4 to be produced on which a sufficiently large image sharpness is to be arranged, approximately lftOOnumber of separate point electrodes 5. gen / cm ^{2 to be} provided. Furthermore, it is disadvantageous that 50 To produce the point electrodes 5, a mesh is first used for these bores with chemical analyzes from one side with a light (photoconductive material and from the other side th mesh size of about 0.15 mm (1600 mesh A proportionately equal per cm ² ) attached to the photoconductive layer 4 filling the holes and the production of the contact and a conductive metal, e.g. copper, in a vataktes between the photoconductive material and the vacuum of about 10 "Torr through the mesh surface electrode on the one hand and pin electrons on the one hand. However, the point electrodes 5 on the other hand can also cause considerable difficulties

From the German Auslegeschrift 1 271 548, layer 4 is a uniform metal layer.

a method known to vaporize in image-wise distribution and this then by photoetching in

To apply charges to an insulating surface. 60 the points is divided. These point electrodes 5

In this case, a layer arranged on a layer support can be drawn in suitable outlines, for example

photoconductive layer with simultaneous application spherical or cylindrical, produce while

exposed imagewise to a voltage. In doing so, their distances are made by the

one can determine the low conductivity of photoconductive required grid conditions.

Use layers in the direction of their surface plane. 65 The height of the point electrodes S should be as high as possible

The invention has for its object to be a uniform.

Electrophotographic Apparatus for Manufacture Referring to Fig. 1, a recorder has a Charge pattern corresponding to the above-mentioned unit, an insulating layer on a counterelectrical

trade 7, the point electrodes 5 of the photoconductor electrode 26. The wound paper 28 is with a

capable layer, which forms the charging electrode, provided against an insulating layer. At position 29 a

overrides. The conductive layer 3 and the Gegenelek- forming object or a template shown, ües-

trode7 are connected to a voltage source 9 image from a projection lens onto the photo-

sen, over which a high potential is applied 5 conductive layer is focused,

can. The polarity of the potential is determined un- A peeled off section 28 a of the paper roll 28

taking into account the properties of the one between the charging electrode 21 and the counter

photoconductive layer 4 forming photoconductor, each electrode 26 inserted, the insulating layer the

according to whether it is an η-conductor or p-conductor point electrodes 25 facing the charging electrode.

acts. io when in this state the transparent conductive

If the image of an object 10 via a layer 23 and the counter electrode 26 is a high Po lens 11 through the transparent layer substrate 1 on potential and the original 29 is focused by the line 30 of the photoconductive layer 4, the projected falls, a charge image arises on the recording pa resistance of the pier 28 α struck by the optical image, the content of which corresponds to the optical image in terms of its content depending on the intensity of the 15. The light projected from the charge image, so that the charge of this carrying recording paper 28 becomes α after it is transferred in length over the point electrodes 5 to the insulating layer 8 by a cutting device 31. The removal of the cut is carried out via two feed rollers 32 resistance and the charge transfer is carried out to a developing device 33. In this case, in very favorable values, so that the paper 28a arrives on the insulating ao between two feed roller layers, a charge image with high contrast, which it stands between in a developer tank 35. Guide plates 36 and 37 by a developer

F i g. 2 shows a recorder for electrostatic fluid 38 moving so that the charge image

table charge images for use when executing becomes visible. The developed recording paper

approximately example according to the invention. A conductive 25 28 is discharged via two discharge rollers 39.

Layer support consists of a transparent support. These operations are repeated in order to make several

22, a transparent conductive layer 23, one or a plurality of electrostatic images.

Set photoconductive layer 24 with point electrodes 25. As a recording paper can be used in place

as a charging electrode. A voltage source 27 is also used for the previously described rolled paper

to apply a potential with different po- 30 cut arcs can be used. Also a

Larital to the transparent electrode layer 23 photographic film can be abichiv *,

and to the metallic plate-shaped counter-electrode when it is in contact with the layer carrier 21.

1 sheet of drawings

Claims (1)

marked design with regard to their serviceability- _. and simpler manufacturing options for patent claims: improve and simplify. This task is -,. t. i. i. c nnhuina to the invention solved in that the photoconductive 1. Electrophotographic & nnchtung for J ^"mu ^ f _f charge dissipating. Hemstellung a Ladungsb Ides by ^ bddma- S g ^ f ^^^^ _from ' _e , _ektris ch & 35 ß.ge charge of an insolating £% S ™ JJ ^, _a , _{s point} electrodes of about 1,600 elements nungsmatenals, with an image-wise oelicnten ivmiciiai «^ iSÄS? ^{11 l} ! ^ K! ^ ^Del 5S £ LA £ ^ Dkser ^ oSag allows not only a detent-