SU996980A1 - Data medium - Google Patents

Description

The invention relates to information carriers and can be used to display recorded $ on a storage medium onto large screens of collective use.

Information carriers for electrophotographic recording are known, in which films of organic dielectrics deposited on a conductive base are used [1].

Image acquisition on a dielectric carrier is carried out using a device that consists of information converter 1 and information carrier 2. The information converter consists of a glass plate 3 and a transparent conductive 4 and photosensitive 5 layers deposited on it. The information carrier consists of a glass plate 6 and a transparent conductive 7 and dielectric 8 layers ^deposited on it. Using this device, the method is as follows. The data carrier is located flat 25 'parallel to the transducer. In various embodiments of the device, the air gap 9 between them is 2-10 microns. Exposure of the image on a photosensitive layer is performed simultaneously with applying voltage to the electrodes of the carrier and the information converter. In places of exposure, the conductivity of the photoconductor increases and the charge is transferred to the dielectric layer as a result of the breakdown of the air gap 9 that exists between the carrier and the information converter. The resulting latent electrostatic image can be developed using a dry or liquid developer with the corresponding sign of the charge of the particles.

Most blizkym ¹ to technical essence to the proposed information carrier is composed of a glass plate, a transparent conductive tin dioxide layer and an organic dielectric, which is used as polystyrene, polyethylene, ethylcellulose and shellac. The best results are obtained when using polystyrene, whose properties most fully meet the requirements for the material of the dielectric [2].

The disadvantages of this media are the low image quality when projecting images in the light and short life.

The most significant quality characteristics of the resulting image are contrast and resolution. The low contrast of the image is explained by the relatively low transmittance of the light of organic films with a thickness of 1-10 μm, associated with a limited transmission band and the presence of scattering centers in them. So even for polystyrene with a thickness of 0.4 μm quartz glass, absorption in the visible region of the spectrum reaches 10%.

The resolution limitation is due to the relatively large thickness of organic films (as a rule, more than 1 mkm), which, in turn, is determined by the technology of producing continuous organic films.

The short life of the carrier with the recorded information is explained by the low heat resistance of polystyrene. When projecting an image onto a large screen, you pass through a dielectric storage medium. Ί Luminous flux of high power, which leads to heating of the organic film to temperatures causing its clouding and cracking. So polystyrene films withstand less than 20 cycles of heating and cooling in the range of 20-200 ° C.

Repeated recording of information on a medium is possible after recovery of the medium by erasing the recorded information after it is projected onto the screen. Erasing is performed by mechanical erasing and erasing repeatedly by removing the toner from the surface of a dielectric film, for example, with a gauze swab or a brush moistened with: conductive * fluid. This leads to abrasion of the organic dielectric, which has low mechanical strength, as well as to wetting its surface and, therefore, to its swelling and peeling, and it is not suitable. for use when recording information multiple times (100 or more times). .

The aim of the invention is to improve image quality and increase the service life of the media with repeated use.

This goal is achieved in that the storage medium containing a glass base with a sequentially transparent conductive coating of SnO ^ and a film deposited on it, as a film, it contains an inorganic dielectric ie BtC ^ or Al ^ O ^.

The drawing shows a storage medium.

The design and principle of operation of the device are similar to those previously discussed.

The Converter 1 and the storage medium 2 information are located plane-parallel to each other at a distance of 2-10 microns. 65

A high voltage is applied to their electrodes with the simultaneous illumination of the photosensitive layer, as a result of which a latent image forms on the dielectric layer of the carrier, which then appears as a toner.

The dielectric film of the information carrier is silicon dioxide SiOj with a thickness of about 1 μm, which is obtained by the plasma-chemical method as a result of the decomposition of silane at a pressure of P = 10 ’- ^ mm Hg.

During the operation of a data carrier manufactured in this way, the following advantages were revealed in comparison with the prototype: the image quality is improved, which consists in increasing the contrast and resolution. The achievement of high contrast is due to the higher transmittance of silicon dioxide in the wavelength range of 0.2 - 7 μm, and the increase in resolution is due to the possibility of obtaining high-quality Si0 ₂ films less than that of organic films with a thickness (0.2 - 2 μm). >

In addition, the service life of the information carrier is increased when repeatedly projecting onto a large screen by increasing the heat resistance of dielectric films.

Moreover, the high mechanical strength of the films of inorganic dielectrics, their resistance to conductive liquids allow the production of information. On a carrier with a SiOg film, information was rewritten more than 5000 times while maintaining high image quality. The use of an inorganic dielectric film leads to a qualitatively new result, namely, the possibility of using a medium for multiple rewriting of information.

Similar results are obtained when using an information carrier with an inorganic AI2O3 film about 0.8 microns thick.

Thus, the present invention allows to significantly expand the possibilities of using an electrophotographic device when displaying information on a large screen, as well as to increase its technical and economic indicators due to the multiple use and increase the service life of the information carrier of an electrophotographic device.

Claims (2)

1.Greniiishn S.G. Electrophotographic process. M., Science, -, 1970, p. 162. 2. Electrography and magnetography, Vilnius, 1965, p.225 (prototype). // i / M. y / 7 // f7 / jf / / / 7 / y / j // jf77ji /// 7 // l - A , :: b f