SU1721582A1 - Device for contact exposure of images onto electrophotographic carrier film - Google Patents

Abstract

The invention relates to a device for contact exposure of an image to an electrophotographic film carrier. It allows to improve the quality of exposure of the image by improving the uniformity of contact between the carrier and the screen. The device has a transparent electrically conducting layer 3. which is located between the dielectric layer 4 and the optical fiber 2. The layer 3 is connected to the power supply 8. 1 sludge.

Description

This invention relates to electrography, in particular, to a technique for recording black-and-white and multi-color images on phase and amplitude film electrophotographic carriers.

The aim of the invention is to improve the quality of exposure of the image by improving the uniformity of contact between the carrier and the screen.

The drawing schematically shows the device.

This goal is achieved in that the device contains a transparent electrically conductive layer between the dielectric layer and the optical fiber, connected to a power source with a voltage regulator of the power source. As a result, when applying voltage to an electrically conductive layer during exposure, additional electrostatic pressing of the image carrier to the screen surface is carried out due to the attractive forces between charges on the surface of the image carrier and the electrically conductive

layer. This leads to improved contact between the source of information and the carrier of the image and provides high-quality exposure of the image. The film carrier of the image is deformed by electrostatic forces, as a result of which the quality of the exposed image is less affected by dust and particles of the developer and in the gap between the screen and the photosensitive layer, as well as the flatness of the screen of the electron-beam device. Uniform contact of the image carrier with the surface of the screen makes it possible to uniformly defocus the structure of individual fibers of the light guide / The thickness of the electrically conducting and dielectric layers, based on the ratio

di. d2D / 1

ni n2 Л} 2Ут -sinp / 2

where di and m are the thickness and the refractive index of the dielectric layer, d2 and P2 are tolSO

with

vj

GO

ate

00

Yu

the thickness and the refractive index of the electrically conducting layer, D is the fiber diameter of the optical fiber, t is the fill factor of the screen with fibers of the optical fiber, p is the aperture angle of the optical fiber.

The magnitude of the voltage of the power supply connected to the electrically conductive layer is chosen from the conditions that the potential difference between the electrically conductive layer and the surface of the image carrier is less than the maximum allowable value at which charge transfer between the carrier and the dielectric layer begins and at the same time this potential difference was greater than a certain minimum value at which a dense electrostatic carrier sign is still provided to the screen surface, until the moment of exposure and after e it is necessary to prevent sticking of the image carrier to an insulating layer on the screen. This will be provided in the case where the potential of the electrically conductive layer is equal to the potential of electrifying the image carrier. In this case, there is no electrostatic attraction force between the video source and the image carrier, and the carrier is separated from the surface of the dielectric layer.

The device includes a cathode-ray tube 1 with an optical fiber 2, on the surface of which an electrically conductive layer 3 and a dielectric layer 4 are sequentially deposited. 8 contact with it is an image carrier consisting of a photosensitive layer 5, a conductive grounded layer 6 and a film basics 1. The electrically conductive layer on the screen of the cathode ray tube is connected to the power source 8 with the voltage regulator of the power source 9.

The device works as follows.

When setting the image carrier to the exposure position, the voltage of the power source 8 is maintained by means of the regulator 9 equal to the electrification potential of the photosensitive layer 5. After mechanically approaching the image carrier to the screen of the cathode ray tube, the potential of the electrically conductive layer 3 is set to provide electrostatic pressure carrier to the screen surface.

The radiation of the cathode-ray tube 1 is modulated by the structure of the optical fiber 2 upon exposure. This parasitic modulation is eliminated due to

image defocusing in the gap formed by the electrically conductive and dielectric layers 3 and 4, the thickness of these layers is small, resulting in significant

deterioration of the resolution of the exposed image does not occur. After the end of the exposure with the help of the regulator 9, the voltage of the power supply 8 again increases to

the potential of electrization of the image carrier. In this case, between the conductive layer 4 and the image carrier, the force of electrostatic attraction ceases to act and the carrier moves away from

the surface of the screen cathode ray tube by mechanical means.

When using the proposed device for contact exposure, the resolution resolution increases

the ability of the recorded image to reduce its modulation of the structure of the fiber and prevent the transfer of charge between the screen of the cathode ray tube and the surface of the carrier image. These benefits provide better recording quality.

Claims (1)

Invention Formula A device for contact exposure of an image to an electrophotographic film carrier containing a cathode ray tube with a screen made on the basis of a fiber from veto water and coated with a transparent dielectric layer, characterized in that, in order to improve the quality of exposure of the image by improving the uniformity of contact between the carrier and screen, it contains a transparent electrically conductive layer located between the dielectric layer and the optical fiber, connected to a power source with a voltage regulator of the power source, the thickness of the dielectric and electrically conductive layers being made based on the ratio where di and m are the thickness and the refractive index of the dielectric layer; da and П2 - thickness and refractive index of the conducting layer; D is the fiber diameter of the fiber; g is the fiber fill factor of the screen; p is the aperture angle of the fiber. IS 5 // f /.,/ ,; f / SSA / Ssr one