DE2600171B2 - Photoconductive control grid - Google Patents

Description

The invention relates to a photoconductive control grid according to the preamble of the claim.

Control grids of this type are known (Offenlegungsschrift 24 34 433 and 24 29 303). The insulating cover layer covers the one below photoconductive layer and the electrically conductive grid core only partially, so that part of the conductive Material is exposed. This also applies to a known control grid (DE-OS 24 29 303) during its manufacture the insulating layer was originally the wires of the mesh core designed as a braided mesh essentially completely enclosed by a subsequent grinding process on one side of the grille again as far as possible that as far as possible and on this side again the conductive Material is exposed and not covered by insulating material. Because of the stitch pattern, at During this grinding process, the insulating material is not abraded in all areas of the wires, especially on At the intersection points of the mesh fabric, the insulating material remains partially on the entire surface of the wire is present, which is actually not wanted in the known grid, most of the However, even with this known grid, the wire surface is exposed on one side and is not with Insulating material covered. These known control grids have the disadvantage that the load along the Insulating layer can get into the conductive areas of the grid core and then against ground is derived, therefore the charge acceptance and the charge density in these known control grids is relatively limited.

It is an object of the invention to provide a photoconductive control grid of this type in terms of improvement and improvement Increase the achievable charge density to improve.

This task is based on a photoconductive control grid according to the preamble of the main claim solved in that the insulating cover layer is not only on the photoconductive layer but also on the extends from this exposed lattice core areas. This ensures that the charge over the Lattice core can not flow off to mass and is due to the fact that with a control grid after the Invention a significantly greater charge density is possible than with the known grids. It will be in Essentially an accumulation of charge on the surface of the insulating material in the area of the not from photoconductive material covered metal of the grid core is achieved and thus is an increase in Charge density of 30 to 100% possible.

The invention is explained in more detail below with reference to schematic drawings of an exemplary embodiment explained.

F i g. 1 shows a perspective partial view of a control grid according to the invention,
F i g. 2 shows the associated cross section.

The illustrated photoconductive control grid, which in a known manner for image-wise modulating a on an insulating recording material directed corona ion flow, consists of an electrically

ίο conductive grid core I ₁ which is designed as a wire mesh grid in the embodiment shown. The lattice core could of course just as well consist of another suitable metal part provided with corresponding lattice openings in a known manner. The grid openings of the exemplary embodiment have a largest dimension of 0.074 mm, for example. The wire mesh 1 is braided from wires 2 made of stainless steel, for example. A layer 3 of photoconductive material is applied to the wires 2 in such a way that this layer only partially envelops the wires and leaves the lower part of the wire uncoated. A wide variety of known materials are suitable as the photoconductive material. In the exemplary embodiment, a uniform coating of amorphous selenium was vapor-deposited in vacuo, preferably with an average thickness of about ΙΟμπι. In the exemplary embodiment, the wire diameter was 0.05 mm.

The insulating cover layer 4 is applied to this photoconductive layer 3. In the embodiment shown A plastic such as polystyrene was used for this insulating layer. It became a solution Made from polystyrene with a solids content of 5% by weight. The solvent contained 4 parts of butyl acetate, 4 parts of methyl glycol acetate and 2 parts of methyl ethyl ketone. The obtained solution became sufficient Quantity sprayed onto the grid so that an insulating layer of about 4 μΐη is formed in the dry state Thickness revealed. When using thermoplastic

■ to plastics such as polystyrene these are up to State of plasticity heated to obtain a smooth even surface. After this The grid was sprayed on in a stream of warm air kept at room temperature for three hours dried to remove all solvent and a full through drying of this layer to reach.

A cross-sectional photomicrographic examination has shown that the selenium layer at the top of the Grid core was applied and the underside of the grid core as well as the sides of the metal wire were left completely free. The sprayed-on insulating material not only covered the photoconductive layer, but was also present as a thin layer on the underside of the wire mesh. So it was that too metallic surface of the grid core covered by the insulating material. However, this was in in no way the actual task of the control grid, namely the image-wise modulation of one on one

f> o insulating recording material directed corona ion flow to enable, hindered or disturbed, the electrical fields occurring here remained undisturbed.

The from Fig. The formation of the cover layer, which can be seen in FIG. 2, enables a significantly greater charge density compared to a grid in which the grid core is partially exposed and in which the danger is that as the charge density increases, the

Charge in a lateral direction across the surface of the insulating layer is distributed and finally with continued ion exposure the ions to it tend to eventually get into the area of the conductive wire and then along the surface to be derived from ground. This is made possible by the continuous insulating cover sheet. in the invention Control grid prevents, since the charge only changes with continued exposure to ions accumulates on the insulating surface without with conductive parts of the grid to come into contact. This is due to the fact that 30-100% more charge can be applied than with conventional grids of this type.

1 sheet of drawings

Claims (1)

Claim: Photoconductive control grid made of an electrically conductive grid core, which is on part of its Surface carries a photoconductive layer, which in turn is covered by an insulating cover layer is for the imagewise modulation of a flow of corona ions directed onto an insulating recording material, characterized in that the insulating cover layer (4) extends outside extends over the photoconductive layer (3) also over the lattice core regions (2) left free by this.