SU1381417A1 - Method of scanning electrophotographic transparent microimage - Google Patents

Abstract

The invention relates to a method for screening an electrophotographic transparent micro-image. Improves image quality by eliminating direct contact of the optical raster with a transparent micro image. Rast- pHpoBaHiie is performed on the substrate side of the electrophotographic material. The raster is made phase on a transparent photothermoplastic material. During rasterization, the raster faces the relief to the substrate. For a rasterization and exposure, a variable aperture light flux is used. (ABOUT

Description

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FIELD OF THE INVENTION The invention relates to microfibration, in particular, to photography, electrophotography, photothermoplasty, which are involved in the registration of thumbnail images.

The purpose of the invention is to improve the image quality by eliminating direct contact of the optical raster with a transparent image of my image.

The essence of the invention is as follows.

On the substrate side of the electrophotographic material, an optical raster is placed, which is made phase, and is exposed. Moreover, for exposing the raster structure before, during or after exposing the main image, applied light sources with an angular size relative to the focusing phase elements of the raster, so that the image of the light source in the focal plane of these elements is not right-handed (where A is the phase raster period , K 1 - the ratio of the width of the dark elements of the raster to the width of the light elements) “Change the angular size of the light source relative to the background

The base raster by changing its distance to the specified raster can quickly change the value of K to achieve the desired ratio of the width of the elements of the raster structure. The high resolution and uniformity of the phase raster is ensured by the fact that it is produced on a photosensitive maternate, in particular on a photothermoplastic material, by recording a hologram on it at a carrier frequency corresponding to the frequency of the microstructure. In particular, this can be a hologram that is obtained when recording two crossed coherent plane waves. In this case, a lined phase raster is formed with a period L defined by the angle at which the plane waves are scaled. In this case, moire effects may occur in the rastropane image. To eliminate them during the formation of the phase raster, the interference of the reference and object beams, t, e, is used to record the real Fresnel hologram-fy, in which there is no clear direction of interference fringes, like in a ruler raster.

II p e rio To register a journal text reduced in 21x, the FTPP-M2 photothermoplastic material is used, the B1 is a metallized lavsan substrate 175 mm thick (n 1.6) and a photothermoplastic layer d 4 microns thick based on PVC and styrene-divinyl copolymer. FTPS has the best deformation properties at the frequency of quasi-resonance

1000, „, - -1 / g,

o7 125 Mh5, and frequencies below 40 La.

50 FTPS practically does not transmit, In the recorded image there are lines of various widths in the range of 15-100 µm, which cannot be registered without rasterization. For this, a hologram of two plane coherent waves (LG-52 laser) is recorded on the same FTPS, as a result of which a relief is formed on the surface of the photothermoplastic material, corresponding to a raster with a frequency of 100 mm and a depth of 0.5 µm. A phase raster is obtained with elements focusing the light flux in a plane spaced from the phase raster to a distance of f - 100 μm in air (or at a distance n 100 μm 160 μm in lavsan). Phase reliefs are nlotally pressed to the substrate using an electrostatic sensitization unit up to a voltage of 250 V. Next, the raster structure is exposed to a decrease in the average potential to 180V, and then the image of the magazine page is exposed to a reduced NIN potential to 100V. The resulting image is shown to be a pulsed infrared block -1 power-and-cool 1 J / cm for 0.8 sec. For a raster exposure, a 70 W incandescent lamp with a filament body size of 5 mm is used. At a distance of 100 mm from the phase raster, the width of the light and dark elements almost coincides, so that when the recording material is developed, a raster of symmetric C-structure with a depth of 0.6 µm forms on the dark elements of the recorded image. By removing the source from the phase raster, it is possible to form an asymmetrical raster on the photothermoplastic material, which has better deformation properties and allows you to magnify.

depth of the phase relief is achieved by the fact that, in order to improve the quality of the image by eliminating

direct contact of the optical formula of the raster with a transparent microimage by an electrophotographic screening method, screening is carried out from a graphic transparent microisob-side of the electrophotographic substrate, including exposing the material with a light flux from a microimage to an electrophotographic-variable aperture, with this pattern. | Qfilled with phase and transparent photodistribution of luminous flux through a thermoplastic material and image cue raster distinguishing Shchen-relief to the substrate

Claims (1)

SUMMARY OF THE INVENTION A method for screening an electrophotographic transparent micro-image, comprising exposing the micro-image to an electrophotographic material while simultaneously screening it with a light stream through an optical raster, characterized in that, in order to improve image quality by eliminating direct contact of the optical raster with a transparent micro-image, the screening is carried out from the substrate side electrophotographic material with a variable aperture light flux, When this phase raster formed by a transparent material and facing photothermoplastic relief to the substrate,