RU1781664C - Method of checking of process of development - Google Patents

Abstract

The use of photography, in particular technology for chemical-photographic processing of silver-containing phototechnical films. The essence of the invention lies in the fact that the photographic effect is determined visually from the sensitogram obtained by exposing the film through a contact raster to obtain a set of fields with a relative area of the raster elements from 0 to 100%, and as a control, choose a field from 0% to 100% relative area of raster elements

Description

The invention relates to photography, in particular to the technology of chemical photographic processing of silver-containing phototechnical films.

A known method for monitoring the development process is to visually evaluate the image obtained by developing the photographic film on which the original image was photographed, and comparing this image with the reference image. This method requires a highly skilled photographer and makes it difficult to quantify the development results.

A known method for monitoring the development process is to determine the photographic effect from the results of densitometric measurements of optical densities in the developed image of the original or control test object photographed with the original, and

comparing them to reference or using tone reproduction curves. This method is time-consuming and cannot be accurate, since the photographic effect of the developed film depends not only on the development process, but also on exposure, which cannot be constant under non-standard conditions

The closest technical solution, chosen as the quality of the prototype, is a method of controlling the development process by determining the photographic effect on the sensitogram, which consists in calculating the average gradient from the results of optical density measurements on the developed photographic film exposed in the sensitometer.

To determine the average gradient from the fields of the sensitogram with an optical density of at least 0.8, select a field with a density of XJ 00

ABOUT

0.8 or greater than this value by the smallest amount. The second control point is taken from the fields of sensitograms with an optical density of 2.6; a field with a density of 2.6 or higher than this value by the smallest value is selected. The average gradient is calculated according to a formula known from the course of the theory of photoprocesses.

The reference value of the average gradient and the conditions for its achievement for a particular film developed in a particular developer are determined in advance experimentally with the activity of the developer providing optimal sensitometric characteristics (contrast ratio, photosensitivity, etc.). The results of the development process are estimated by the degree of approximation of the average gradient of the control sensitogram and the reference one. If the average gradient of the monitored developed film differs by no more than 0.5-0.7 from the reference, then the process of development is considered normal and does not require adjustment.

A disadvantage of the known method for monitoring the development process is the complexity and duration due to the need to measure optical densities and calculate the average gradient.

In addition, this method requires additional costs for the acquisition of a densitometer for measuring the optical densities necessary for calculating the average gradient of the developed photographic layer.

An object of the present invention is to simplify and reduce the cost of a method for monitoring a development process.

This goal is achieved by the fact that in the known method of monitoring the development process, including the operation of determining the photographic effect on the sensitogram obtained on the film, use the sensitogram, with a set of fields with a relative area of the raster elements from 0 to 100%, obtained by exposing the film in the sensitometer through a contact raster, and the photographic effect is determined visually from the fields with a relative area of the raster elements 0 and 100%.

On the film exposed in the sensitometer through the contact raster after development, a raster sensitogram is obtained, on each field of which raster points of various sizes are formed depending on the amount of illumination distributed by the optical sensor wedge. Since the interval of the optical density of the wedge in the sensitometer is always

If the range of densities reproduced by the contact raster is always possible, it is always possible to produce a raster sensitogram on which raster elements with relative densities from 0 to 100% will be formed.Therefore, there will be two control points on such a raster sensitogram that are quite easy to detect by visual inspection of the sensitogram.

The first control point is the field of the sensitogram, on which there is a raster point with a relative area of 0%, that is, on this field

there are no raster dots at all, there is only a transparent film.

The second control point is the field of the sensitogram, in which the relative area of the raster elements is 100%, i.e. there will be a solid blackening in this field and there will be no transparent raster elements.

Depending on the activity of the development process, the control points will move. With a decrease in the activity of the development process, the control points will shift toward large exposures (to the left), and with an increase in the activity of manifestations will shift toward small exposures (in the right). If the control points move to the left in the control sensitogram, this means that it is necessary to increase the temperature of the solution, increase the development time or introduce a reinforcing additive. If

the control points on the verified sensitogram are shifted to the right compared to the reference, then it is necessary to reduce the activity of the development process.

The proposed method for controlling the development of phototechnical films is illustrated by the following example.

Example 1. Phototechnical film FT-51 was placed in the cassette with the emulsion layer up. A contact raster with a line of 12 lines / cm2 emulsion layer down was placed on top of the film. The cartridge was inserted into the FSR 41 sensitometer and exposed for 20 seconds. Chemical photographic processing of the exposed film was performed for 2.5 flies in a FT-2 developer and fixed in acid fixer for 1 min. The temperature of the solutions is 26 ° C. The resulting raster sensitogram was analyzed using a 7x magnifier. As a result

In the analysis 5, it was found that the control point with a relative area of 0% is located on the 18th field, and 100% on the 5th field of the raster sensitogram. The resulting photographic effect is a reference since

film processing was carried out by rzhimami, which ensure the achievement of optimal sensitometric characteristics.

Example 2. The film was exposed, developed and fixed analogously to Example 1. The temperature of the rasters was 20 ° C. The resulting raster sensitogram was viewed in the same manner as in Example 1. As a result of the analysis, it was found that the control point with a relative area of 0% is located in the 17th field, with 50% in the 8th field, and with 100% in the 4th field. Moving the control points to the left indicates that with a decrease in the temperature of the developer, the activity of the developer decreased.

Example 3. The film was exposed, developed and fixed analogously to Example 1. The developer temperature was 34 ° C. The resulting raster sensitogram was viewed similarly to Example 1. As a result of the analysis, it was found that raster elements with a relative area of 0% are in the 19th field, with 50% - the 11th field, and from 10% to the 6th field of the sensitogram. Moving the control points to the right indicates an increase in the activity of the development process due to an increase in the temperature of the developer,

Example 4. A film exposed analogously to Example 1 was developed at a developer temperature of 26 ° C for 1.5 minutes. The remaining operations were carried out analogously to Example 1. As a result of the analysis, it was found that raster elements with a relative area of 0% are located on the 16th field, with 50% on the 8th field, and from 100% on the 4th field. Moving the control points to the left shows that the photographic effect on the developed film has decreased due to the reduction in development time.

Example 5. A film exposed analogously to Example 1 was developed at a temperature of 26 ° C for 3.5 minutes. The remaining operations were carried out analogously to Example 1. As a result of the analysis, it was found that raster elements with a relative area of 0% are located on the 20th field, with 50% on the 12th field, and from 100% on the 7th field. The results confirm that with a & increase in development time, the photographic effect increases.

Example b (prototype method). FT-51 photographic film was placed in the cartridge with the emulsion layer up. The cartridge was inserted into the FSR-41 sensitometer and exposed for 2 seconds. The exposed film was developed for 2.5 min in a FT-2 developer and fixed in an acid fixer in

within 1 min The temperature of the solutions was 2 ° C. The optical densities were measured on the obtained sensitogram using a Macbeth TD-102 densitometer.

5Selectogram fields were selected

densities in excess of 0.8 by the smallest amount. Thus, a field 14 of a sensitogram with an optical density of 1.04 was selected, which is the first reference point. For the second control point, a field was selected whose optical density exceeds an optical density of 2.6. It turned out to be 11 fields with an optical density of 3.1. From the obtained control densities, the average gradient was determined, the magnitude of which is 4.2.

Example 7 (prototype method). The film was exposed and developed analogously to Example 6 at a temperature of solutions of 20 ° C.

The measurement of optical densities and determination of the average gradient was carried out analogously to example 6. The average gradient is 3.8.

5 From the results obtained in Examples b and 7, it is seen that the average gradient is within the normal range. However, from the theory and practice of photography, it is known that

0 6 ° C should significantly affect the photographic effect. Therefore, the prototype method does not provide accurate control of the development process.

By using the proposed method for controlling the development process, labor productivity is increased due to the rapid assessment of the photographic effect on the raster sensitogram.

0 In addition, due to the lack of sensitogram measurement operation, there is no need for a densitometer, as a result of which the process costs are reduced,

Claims (1)

5 Claims A method for monitoring the development process, including the operation of determining the photographic effect from the sensitogram obtained on photographic film, characterized by the fact that, in order to simplify the method and reduce its cost, use a sensitogram with a set of fields with a relative area of raster elements from 0 up to 100% obtained by exposing the film to 5 by a sensitometer through a contact raster, and the photographic effect is determined visually by field with a relative area of α-raster elements of 0 and 100%.