SU1019390A1 - Photo-thermoplastic image medium phtographic characteristic determination method - Google Patents

Abstract

DEFINITIONS disputes FOTYGRAFICHBSKIH CHARACTERISTICS photothermoplastic SHSI PVLEY-PICTURE "ua rsfmnrovayie optical interference carrier surface skhodh schimis .kogerenttshi rays of projection ua it RASTER-b rovanio1yu optical wedge odyovremeinym ityvaeniem with optical imaging and opredolemne pho tograficheskgih er41stik the Features of postrennym with iioJ jy4eH niM nzob (a) the key of the calculated characteristics of the curves / O tl and h a w in and and with the fact that, in order to not To To 4HuctH determine xfakteris1zhk, considered It is carried out by a peripheral beam of the beam in the nepBoiM max. mvcfraction.

Description

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The invention relates to electrophotography and can be used in scientific and applied photography to determine the photographic characteristics of photothermoplastic image carriers.

There is a method for determining photographic characteristics of photothermoplastic image carriers, including forming optical interference on the carrier surface with converging coherent rays, projecting a rasterized optical wedge onto it with simultaneous optical reading of the resulting image and determining the phototraffic characteristics by them according to the constructed characteristic according to the obtained and: 4% calculated characteristic curves ll.

The disadvantage of this method is the lack of accuracy of characterization.

The aim of the invention is to improve the accuracy of characterization,

The goal is achieved in that according to the method of determining the photographic characteristics of photothermoplastic image carriers, including the formation of a convergence of La Lys-coherent rays on the surface of an optical interference carrier, projecting a rasterized wedge onto it with simultaneous optical reading of the obtained image and determining the photographic characteristics by the constructed in accordance with the obtained image of the calculated characteristic curves, the reading is carried out by the interfered beam in the first diffraction maximum ..

To determine the photographic characteristics of a photothermoplastic carrier placed in a recording cell with a transparent heating element, a macroscopic raster of alternating light and dark bands (raster widths of 1 mm) is projected through a stepped illumination wedge and simultaneously raster (carrier frequency) in the form of an interference grid formed by two converging coherent beams. Simultaneously with the exposure of the carrier indicated above the light fluxes, it is charged in the field of corona discharge and heat developed by a transparent heating element. As a result of simultaneous processes of charging, developing and projecting on a deformable carrier layer over time (1-2 s), a rasterized image of a stepped illumination wedge with a macroscopic raster is formed by a diffraction grating.

In order to emit the dynamics of the development of the image formation process and determine the photographic characteristics of the carrier at any time of the manifestation, simultaneously with the registration, its reading is carried out. It is carried out by one of the coherent beams used for screening the image with an interference grating. This coherent beam

The light, the passage through the photothermoplastic carrier and the transparent heating element, creates by diffraction on the diffraction grating formed during the recording in the first diffraction maximum, which develops in time the image of the step wedge with a macroscopic image.

To read the image

Q image in l (at any time, the individual elements are sequentially transmitted to the photodetector located on the path of the reading beam. The time modulation of the read image is carried out at a frequency of about 50 s. The signal from the photoreceiver is fed to an oscilloscope. The oscilloscope generates a time-varying pattern of alternating maxima and minima with different ratios. Each oscillogram characterizes the contrast varying by wedge illumination direct macroscopic raster

- at a certain time of image registration, fixed by a time sensor. The recording of a set of oscillograms formed during recording is carried out by transferring them onto a carrier of the image moving relative to the screen of the oscilloscope. After the carrier is developed, the characteristic curves of the carrier are plotted from the obtained oscillograms for

5 any moment of recording. Of these, photographic characteristics of the carrier are determined at each instant of recording and, analyzing these characteristics, determine the optimal charging time and

0 about the appearance of the carrier.

PRI me R. The photographic characteristics of a photothermoplastic carrier are determined on the basis of a photosensitive selenide layer.

With mouse and thermoplastic layer of butyl methacrylate with acrylonitrile. Simultaneously with the krronnry charge of the surface of the carrier, a macroscopic raster is projected through a stepped edge of illumination (0.5-8 lx)

About and interference frequency of 300 l / mm with an intensity of coherent radiation of 10 J / cm. The potential on the oroniruk cement electrode bq, temperature of manifestation is 70 ° С, time

5 charging and exposure 2 s. Razvivak tsees in the process of charging the carrier relief-phase image of a macroscopic raster is read one of the coherent beams used to create an international raster. Image 5 is read in the first diffraction max. the intensity of which varies with time as the depth of deformation formed on the thermoplastic layer of the diffraction grating, tO, increases. The reconstructed image is modulated in time with the help of a rotating one with a frequency of 1500 rpm

The disk, which has two slit slots, the Modulated luminous flux | 5 is focused on the photomultiplier, the electrical signal from which is fed to the input of the oscilloscope, Oscillogram, and recorded with the help of the second carrier with lime characteristics /with. Calculate from the oscillograms the ratio lT / -tce of each moment in time,

build characteristic curves in s

one . .. - Z3

view 3:, p (), where the intensity of the diffracted light in the first diffraction maximum from the bright stripes of the raster, O-, t The intensity of the diffracted light from the dark stripes of the raster. From the characteristic curves, the photographic characteristics of the carrier and and are determined: with the dependence on the time of formation of the image during photothermoplastic recording with interference spreading.

For the studied carrier, the photosensitivity increases from 0 to 3 by increasing the image formation time from 0 to 1 s and (It decreases with an increase in this time by more than 1.5 s.

The contrast ratio of the carrier also reaches a maximum value of 1.5 with an image formation time of 1.2 s.

The proposed method makes it possible; Tracing the dynamics of the formation of the visible image on the carrier and the change in the photographic characteristics of the carrier in the process of recording the image, allows us to establish the point in time at which the optimum photographic characteristics are achieved.

Claims (1)

(54 ·) METHOD FOR DETERMINING PHOTOGRAPH-. By calculating characteristic curves, PHYSICAL CHARACTERISTICS OF PHOTO THERMO - and so on with the fact that, in order to improve the accuracy of determining the characteristics, the reading is carried out by the interfering beam at the first diffraction maximum. . _