FR2752957A1 - Producing colour positive film with enhanced contrast for cinematographic projection - Google Patents

Abstract

Production of a colour positive film with enhanced contrast by intensification of the dark shades, starting with a developed colour negative film, comprises the successive stages of (a) producing an inter-positive film by (i) uniformly exposing a virgin intermediate colour film having a photosensitive silver halide emulsion to actinic light; (ii) printing the resulting film from step (i) by exposing the film to actinic light by way of the image on the already developed colour negative film; (iii) immersing the film from stage (ii) in a basic developer bath containing a reducing agent; (iv) immersing the film from (iii) in a stop bath containing at least one (in)organic acid, and rinsing the film; (v) immersing the film from (iv) in a fixing bath containing at least one fixing salt capable of reacting with the silver halide present in the emulsion to form a water-soluble compound and (vi) rinsing, draining and drying the film; (b) producing an inter-negative film from the inter-positive film from (a); and (c) producing a positive film for cinematographic projection from the inter- negative film from (b), wherein stages (b) and (c) comprise the stages of (A-1) in the case of stage (b), printing an intermediate virgin film coated with a photosensitive silver halide emulsion using the interpositive image obtained in step (a); (A-2) in the case of step (c), printing a virgin colour positive film coated with a photosensitive silver halide emulsion using the internegative image obtained in stage (b); and (B) processing the colour film in the usual way by successive stages of development; stop bath to terminate development; bleaching, optionally after treatment with an accelerator; fixing; draining and drying.

Description

 The present invention relates to a method for producing a color positive film from a color negative film allowing an increase in contrast by intensification of dark hues.

 One of the main focuses of film research is the increase of contrasts in the image.

 At present, two methods of developing cinematographic films are known for obtaining highly contrasted images. These prior art methods involve revealing the impressed image on a positive color film.

A first method is the development method without bleaching the positive. As the name suggests, this process includes conventional development steps excluding the bleaching step. More specifically, the non-bleaching method comprises the following processing steps
a) revealing the positive by immersing the impressed color film in a basic developer bath containing at least one reducing agent. This step consists in transforming the latent image of the film, formed of microscopic aggregates of metallic silver dispersed on the surface or inside the silver bromide crystals, into a visible image, by reducing the bromide grains. metallic silver located in the immediate vicinity of the microscopic aggregates of the latent image. In fact, the reduction is catalyzed by these microscopic aggregates that function as primers or developmental germs. For the reduction, a reducing agent capable of reducing, under the operating conditions chosen, the silver cations, in the oxidation state 1, to metallic silver in oxidation state 0. In doing so, the reducer oxidizes. The oxidized form of the reductant reacts with the dye compound (s) present in the photographic emulsion to form the leuco-derivatives which by subsequent oxidation lead to the formation of dyes, and thus the appearance of colors. It is clear that leuco-dye-precursor derivatives are produced only in the immediate vicinity of developmental nuclei where reduction of the silver halide grains has occurred.

Thus, at the end of the revelation, the emulsion of the color film exhibits both grains of metallic silver and intact silver halide crystals;
b) stopping the revelation, by immersion of the film from the previous step in a stop bath comprising at least one mineral or organic acid. This stop bath has the role of quickly curbing the action of the developer, by abrupt decrease in the pH of the emulsion, thus causing an increase in the oxidation-reduction potential of the silver cation and a lowering of the development energy.

 c) immersing the film from the preceding step b) in a fixing bath comprising at least one alkali metal or alkaline earth metal salt capable of forming a double complex salt of silver and of alkali or alkaline earth metal by reaction with the silver halide present in the photographic emulsion. The characteristic of the double complex salt of silver and metal is its solubility in water. Thus, by immersion in the fixing bath, all the silver halide crystals present in the emulsion is eliminated.

 By this process, the silver image is thus preserved on the film. In this way, we obtain a very particular image rendering, highly sought after by specialists, mixing black and white and color.

Nevertheless, if the increase of the contrasts is clear, it does not correspond to the intention of the desired effect insofar as the fine variations of tone become imperceptible.

 This method has a second major disadvantage. Its implementation leads directly to the positive color for the projection room. In other words, each of the copies intended for projection must be prepared by implementing this method. This constraint is inconvenient insofar as the non-bleaching process can not be performed on conventional development machines, which automatically integrate the bleaching step.

 The second method of the state of the art leading to an increase in contrast is known as a development method without accelerator.

 Compared to the non-bleaching process, this method allows for a softening of the contrasts. The processing steps are those conventionally carried out in the development of color films, except that the step of treating the film with a bleaching accelerator is eliminated.

 More specifically, this process comprises the steps of revealing, stopping revelation, bleaching without prior treatment with an accelerator and fixing.

 Remember that at the end of the revelation, the photosensitive emulsion contains intact crystals of silver bromide and metallic silver. The bleaching step aims at removing the silver metal from the emulsion by oxidation of the silver atoms to Ag + cation. In fact, bleaching has the only consequence of converting the silver metal into silver halide, the latter being effectively removed only in the next fixing step, via the formation of a water-soluble compound.

 In the art, a metal persulfate is commonly used as the oxidizing agent for bleaching.

 However, the kinetics of the oxidation reaction with a metal persulfate is slow.

 Consequently, rather than prolonging the immersion time in the bleaching bath, the emulsion to be treated is activated by immersing it in an accelerator bath containing at least one catalyst for the oxidation reaction before proceeding with the bleaching itself.

 In this case, the bleaching step comprises a first treatment with an accelerator and a second treatment with an oxidizing agent.

 In the case of the accelerator-free process, the treatment with an accelerator is omitted so that the oxidation of the metallic silver is incomplete. As a result, the developed film has after fixing a certain amount of metallic silver. The resulting image is therefore slightly less contrasting than in the case of the processes without bleaching above, in the sense that the blacks appear less dark but there is again an attenuation of the shades of gradient.

 Another disadvantage of this method is that it does not allow easy automation of the production of copies intended for theatrical projection.

 In fact, the implementation of the development process without accelerator leads directly to the projection positive. It is thus understood that since this method involves the elimination of the accelerator bath, it can not be performed simply on conventional development machines.

 A variant of this acceleratorless process has recently been developed by Technicolor.

This method, designated ENR leads, from the point of view of rendering the image, to a result similar to that obtained by the acceleratorless method described above, that is to say that the image is insufficient as to the rendering gradients.

 The ENR method comprises the conventional steps of revealing, stopping revelation, a first fixing and the bleaching step, with, if necessary, prior treatment with an accelerator but includes an additional step of revelation before the final fixing of the film.

 According to this process, the oxidation of the metallic silver is complete because of the prior immersion of the emulsion in the accelerator bath.

 At this stage, therefore, the emulsion of the light-sensitive film comprises exclusively silver halide grains. The next step is a revelation step in which the photosensitive film is immersed in a developer bath comprising at least one reducing agent. In this way, a part of the silver halide present in the emulsion is converted to metallic silver which is not removed from the emulsion during the subsequent fixing and washing steps. Again, a silver image is superimposed on the resulting color image.

 The invention therefore aims to solve the disadvantages of the methods of the prior art by providing a method for producing a color positive film with contrast enhancement by intensification of dark hues, from a developed color negative film.

This method comprises the steps of: a) producing an inter-positive film by
i) uniform exposure of an intermediate virgin color film coated with a silver halide light-sensitive emulsion to actinic light; then
ii) printing the film resulting from step i) by exposing said film to actinic light according to the image of the initially developed color negative film; then
iii) immersing the film resulting from step ii) in a basic developer bath comprising at least one reducing agent; then
iv) immersing the film resulting from step iii) in a stop bath comprising at least one organic or inorganic acid, and then rinsing the film; then
v) immersing the film resulting from step iv) in a fixing bath comprising at least one fixing salt capable of reacting with the silver halide present in said emulsion to form a water-soluble compound;
vi) spinning and drying said film; b) producing an inter-negative film from the interpositive film obtained in the previous step; and c) producing a positive film for cinematographic projection from the inter-negative film obtained in the preceding step b); steps b) and c) above including the steps
al) in the case of step b), printing a virgin interlayer film coated with a silver halide light-sensitive emulsion according to the image of the interpositif obtained in step a) ;
a-2) in the case of step c), the printing of a positive virgin color film coated with a silver halide light-sensitive emulsion according to the image of the internegative obtained at the step b);
) of standard development of a negative or positive film, by revelation, stop of the revelation, bleaching, with the prior treatment by an accelerator, fixing, spinning and drying of said color film.

 For the implementation of the invention, the intermediate and positive virgin color films consist of a flexible support coated with a photosensitive emulsion based on silver halide.

 Preferably, films with an anti-halation effect will be chosen so as to minimize any undesirable light reflection processes by the support / emulsion interface or by the support itself.

In fact, light entering the emulsion of a film can, in the absence of an anti-halation protective layer, be reflected back into the emulsion, causing secondary exposure resulting in an undesirable reduction in the sharpness of the film. image as well as by a certain dispersion of the light called halo.

 In the art the anti-halo effect is obtained, either by coating the support with an anti-halo underlayer consisting of a tinted or silver gelatin layer, or by using a tinted support .

 According to a preferred embodiment of the invention, films having an anti-halo underlayer are used.

 In this case, it is necessary to proceed, before revelation, hydrolysis of the anti-halo underlayer by immersion in a pre-bath. This feature is known to those skilled in the art.

The intermediate and positive virgin color films which can be used according to the invention can be obtained from reputable companies such as
Eastman Kodak.

 Examples of intermediate color films include 5244 (35 mm), 2244 (35 mm) and 7244 (16 mm) films.

 Examples of positive color films include films 5386 (35 mm) and 2386 (35 mm).

 These films are multilayer and have an anti-halo underlayer, a support layer, a red-sensitive emulsion layer, a green-sensitive emulsion layer, a yellow filter layer, and a blue-sensitive emulsion layer. .

 The starting color negative used in step ii) for printing the virgin color film of step i) has a visible image.

The color negative developed initially results from the development of a color film impressed camera according to an image. According to the invention, the development of said color film is implemented in a conventional manner by a standard method ensuring faithful production of the image. By standard method is meant here a development process involving the conventional steps of revelation, stop revelation, bleaching, with, if necessary, treatment with an accelerator, fixing, spinning and drying. The exact operating conditions used during each of these steps are not essential according to the invention as long as they ensure a faithful reproduction of the image without variation of the contrasts.

 Step i) of the process of the invention results in a slight veiling of the virgin film to be impressed. It is commonly spoken in the art of "flashing" of the film to designate the operation performed at this stage.

 The actinic light used during this step (called actinic flashing light) consists of a beam of electromagnetic waves whose wavelengths are in the range from 400 to 700 nm.

 The composition of the actinic light is set from the point of view of contrast rendering and optimized so as to cancel or reduce the effect of "imbalance" occurring following the suppression of the bleaching step.

 Each color film of the multiple emulsion layer type has three characteristic curves relating respectively to the red modulation dye layer, the green modulation dye layer and the blue modulation dye layer. . These curves represent the variations of the optical density as a function of the logarithm of the illumination and this for each of the layers forming the emulsion. Each characteristic curve includes a region of underexposure (low values of illumination), a rectilinear region (average values of illumination) and a region of overexposure (high values of illumination). Ideally, the characteristic curves of the three layers of the emulsion are superimposed, in the absence of a mask on the support.

 When the color film is developed in a standard way by carrying out the conventional steps of revelation, stop the revelation, bleaching with the appropriate treatment with an accelerator, fixing then spinning and drying, the characteristic curves of the emulsions are practically not affected that is, they always overlap after treatment.

 Conversely, the suppression of the bleaching step induces a distortion in the characteristic curves (effect of imbalance), so that these are no longer superimposed after treatment, especially in the area of low light. The result is that in the resulting expanded image, the whites appear slightly colored.

 The method of the invention overcomes this disadvantage.

 According to a preferred embodiment of the invention, the actinic flashing light is obtained by decomposition of a white light of departure into its red, green and blue radiations and mixing the appropriate proportions of said green, blue and red radiation.

 The respective proportions of red, green and blue radiation are determined by those skilled in the art following some preliminary experiments of flashing and development of a virgin color film.

 The determining parameters are in fact the optical densities associated with the red, green and blue radiations (designated respectively by DOR, DOV and DOB in the following) which are measured after development.

During these tests, the development is carried out in a conventional manner, that is to say that it comprises the stages of revelation, stop of the revelation, bleaching, with the optional treatment by an accelerator, fixing, spinning and drying . Preferably, the values of the optical densities are included, after development, in the following ranges of variation.
0.1sDORs0.5 preferably 0, 2SDORSO, 3
0.1sDOVs0.5, preferably 0.15sDOVs0.25
0.2sDO8S0.6, preferably 0, 40EDOBEO, 50
Thus, in these preliminary tests, those skilled in the art will advantageously adjust the respective proportions of green, red and blue radiation so that the resulting optical densities measured on the flashed and developed blank color film are effectively included in the preferred areas of variation indicated above.

 Step ii) relates to the printing of the flashed color film by actinic light (hereinafter referred to as actinic irradiation light) according to the image of the starting color negative.

 The characteristics of the actinic light used at this stage are easily determined by those skilled in the art by calibration according to the image.

 More precisely, the composition of the actinic irradiation light is determined as a function of the intensity of the contrasts sought after the implementation of a few preliminary tests.

 According to a preferred embodiment of the invention, the actinic irradiation light is obtained, as in step i) by decomposition of a white light into its red, green and blue radiations and then mixing appropriate proportions of said red radiation. , green and blue.

 In order to assay the respective amounts of radiation to be mixed, those skilled in the art will develop a sequence of 1) flashing of an intermediate virgin film, 2) image-wise irradiation of a color negative representing a gray to 18% and 3) development.

 During these preliminary experiments, the flashing will be carried out optimally using the actinic light of flashing determined in accordance with the operating protocol set out above. As for the development, this one will be a development without bleaching including the stages of revelation, stop of the revelation, fixing, spinning and drying.

 Advantageously, the actinic light of step ii) is set such that the optical densities associated with red, green and blue radiation are, after development without bleaching, within the ranges of variation indicated below.

1 <DOR <1.5 preferably 1, 2 <DORE1, 4
1.2 <DOv <1.8, preferably 1.4sDOv <1.6
1.8 <D0, 12.2, preferably 1.9 <DOB <2.1.

 The following steps iii) to vi) of the process of the invention correspond to the steps of the conventional methods of development without bleaching.

 The following step iii) is the revelation step in which the silver halide crystals located in the immediate vicinity of the development nuclei formed in step ii) are reduced to metallic silver.

 This step involves immersing the impressed film in a developer bath preferably maintained at a temperature of between 30 and 45 ° C, more preferably between 35 and 45 ° C. The immersion is generally prolonged for 1 to 5 minutes, preferably 1 to 3 minutes. A longer immersion time is to be avoided because it causes a rise in granulation, that is to say the formation of large grains of silver and dyes, which is largely detrimental to the final appearance of the image .

 The developer bath comprises at least one reducing agent.

From a practical point of view, the development bath is an aqueous solution essentially comprising
1) an organic reducing agent which is the essential constituent of the bath. According to the invention, one will preferably select said reducer from paraphenylenes diamine. Usually, the concentration of the reducing agent in the bath is between 1 g / l and 10 g / l, preferably between 2.5 g / l and 4.5 g / l.

 Such substances are commercially available from companies such as Eastman Kodak. The preferred reducing agent is the KODAK color developer sold under the reference CD-3 R, of the formula 4- (N-ethyl-N-2-methanesulfonylaminoethyl) -2-methylphenylenediamine.

2) an alkaline substance in a generally important quantity whose function is to maintain the oxidation-reduction potential at a sufficiently low value by maintaining a high pH. In this connection, it should be noted that despite the presence of the hydrobromic acid formed during revelation, the pH of the developer bath must remain high; this is why a large excess of alkali is necessary so as to constitute with the sulfite (component 3) below) a stabilizing buffer; examples are the alkali metal carbonates and bicarbonates, such as sodium carbonate and bicarbonate;
3) an oxidation preservative which is generally an alkali metal sulfite. The useful dose of this component generally varies between 1 g / l and 5 g / l;
4) an anti-veil retarder that can be mineral or organic. Among the most well known are potassium bromide and 3,5-dinitrobenzoic acid.

 5) optionally an anti-limestone; the antiscalers used according to the invention are those generally described in the art.

 Step iv) is intended to interrupt the reduction of silver halide crystals. This is done by immersing the color film from the previous step in a stop bath. This immersion ensures complete neutralization of the alkali which results in a sudden decrease in pH and a lowering of the development energy by modifying the redox potential.

The stop bath comprises at least one acidic substance of mineral or organic type. For example, acetic acid and sulfuric acid may be mentioned, the latter being more particularly preferred. The immersion time will preferably be between 1 and 15 seconds, preferably between 2 and 10 seconds. The temperature at which the quench bath is maintained is preferably between 20 and 40 ° C. The concentration of the acidic substance is such that the pH of the quench bath is from about 0.8 to about 1.5 percent. the whole step iv)
In the step of stopping the revelation succeeds a first rinsing of the film with a neutral aqueous solution. This rinsing is usually continued for 20 to 40 s.

 Step v) is the fixing step. Fixing involves immersing the film in a bath comprising one or more fixing salts capable of reacting with the silver halide present in the emulsion to form water-soluble compounds.

 The fixing salts most commonly used in the art are the hyposulphites (or thiosulfates) of alkali metals, especially ammonium thiosulfate.

 The thiosulfate content of the fixing bath generally varies between 100 and 200 g / l.

 The duration of the immersion at this stage depends both on the content of fixing salts, but also on the temperature of the fixing bath. Preferably, it will not exceed 4 minutes.

 The temperature of the fixing bath is advantageously between 20 and 45 ° C, preferably between 35 and 45 ° C.

 In a preferred variant, acidic substances such as sodium bisulfite or sodium metabisulphite will be added to the fixing bath. Such substances, by neutralizing the alkali of the developer bath caused by the photosensitive layer, contribute to the stabilization of the fixing bath.

 Step vi) comprises drying and drying the film.

 The duration of the spin depends on the thickness of the emulsion; usually it is at most 4 minutes for cinematographic films.

 When the virgin color film used in step i) comprises, as means for suppressing the halo effect, an anti-halo sub-layer is introduced between the printing steps ii) and iii) revealing, a intermediate step to hydrolyze the anti-halo layer. The hydrolysis conditions depend on the nature of the anti-halo layer present on the support of the film. The ideal hydrolysis conditions are generally specified by the manufacturers of the corresponding color films. This step consists first of immersing the impressed color film in a hydrolysis bath (the pre-bath) and then rinsing the film so as to completely eliminate the anti-halo layer.

This can be done meticulously by brushing or sponging the film.

 By carrying out steps i) to vi) (step a), an inter-positive film is obtained from a developed negative film and an intermediate virgin color film which is then treated according to steps b). and c) the method of the invention. These lead respectively to an inter-negative film and then to a positive film which is the same one intended for theatrical screening.

Steps b) and c) in question involve
a-1) in the case of step b), the printing of a virgin interlayer film coated with a silver halide light-sensitive emulsion according to the image of the inter-positive obtained at step a);
a-2) in the case of step c), printing a positive virgin color film coated with a silver halide light-sensitive emulsion according to the image of the inter-negative obtained at step b); and
ss) the standard development of a negative or positive film by revelation, stop of the revelation, bleaching with, if necessary, prior treatment by an accelerator, fixing, spinning and drying of said color film.

 Insofar as they involve the conventional printing / development steps of conventional processes, steps b) and c) of this method can be easily implemented on continuously operating processors of the state of the art.

 In these two stages, a bleaching operation takes place. This can be carried out according to any of the methods known to those skilled in the art.

 Preferably, the color film is bleached by immersing said film in a bath comprising at least one oxidizing agent, for example chosen from alkali metal ferricyanides and persulfates.

 According to a preferred embodiment, potassium ferricyanide or sodium persulfate is used as the oxidant.

 During bleaching, rehalogenation of the metallic silver present in the photosensitive emulsion is carried out. The bleaching rate, and thus the kinetics of oxidation of silver, is proportional to the concentration of oxidizing agent. It decreases over time. During this oxidation step, it is important that the pH is kept constant.

 For this purpose, it is possible to resort to the addition of a phosphate / sodium hydrogen sulphate buffer or any other type of buffer known to those skilled in the art.

 When an alkali metal persulfate is selected as the oxidizing agent, it is necessary to pretreat the emulsion with an accelerator bath containing one or more catalysts of the oxidation reaction. The nature of the catalyst is not critical according to the invention, one will select indifferently at this stage any of the catalysts commonly used in the art. However, dimethylaminoethylisothiourea dihydrochloride is preferred.

 The invention is illustrated hereinafter with reference to the following examples and figures.

 Figures 1 to 3 show the characteristic curves of the same color film, impressed according to the image of a negative developed starting.

 In the case of Figure 1, a conventional method of development has been implemented.

 In the case of Figure 2, the characteristic curves were plotted after development without bleaching.

 In the case of Figure 3, prior flashing of the film was performed before printing the film according to the image of the starting negative. Then the development of the intermediate film is carried out under bleaching conditions.

Example 1
An example of a general operating procedure for carrying out the process of the invention is detailed below.

A - Obtaining the interpositive
The virgin intermediate color film used is a 5244 (35 mm) film marketed by the
Eastman Kodak Company. Said color film is arranged in a conventional Bell Howell draw apparatus
Model C.

We determine
DOR = 0.30
DOv = 0.25
DOB = 0.50
The composition of the actinic irradiation light is also determined according to the image of a negative representing an 18% gray, by measurement of the optical densities associated with the red, green and blue radiations after implementation of the sequence of 1 ) flashing of a virgin film (the actinic flash light being that developed above), 2) irradiation of the film according to the image of a negative representing a gray at 18%, then 3) development without bleaching (in accordance with the operating protocol outlined below).

The actinic irradiation light selected is such that
DOR = 1.30
DOv = 1.50
DOB = 2.00
The color film is then flashed using the actinic flashing light developed above and then irradiated according to the image of the starting negative film using the actinic irradiation light developed above. after which the bleaching-free development of the resulting film is carried out in accordance with the following operating protocol.

Whiteless development
The development is carried out on an Eclair manufacturing development machine respecting the standards of a Kodak ECN2 type treatment.

 The stages of development are prewash, revelation, stopping revelation, fixing, spinning and drying.

To do this, the baths used are those marketed by the Eastman Kodak Company. References for these baths are shown in Table 1 below
TABLE 1

<tb><SEP> Type <SEP> of <SEP> bath <SEP> Reference
<tb><SEP> Prebain <SEP> PB-2
<tb> Bath <SEP> developer <SEP> SD-49
<tb><SEP> Stop Bath <SEP><SEP> SB-14
<tb><SEP> Bath <SEP> fixer <SEP> F-34a
<tb> Spin <SEP> bath <SEP> FR-2
<Tb>
These baths are characteristic of the development of an inter-positive film.

 The compositions of these different baths are given in Example 3.

Standard development (classic)
The development is carried out on an Eclair manufacturing development machine respecting the standards of a Kodak ECN2 type treatment.

 The stages of development are prewash, revelation, stopping revelation, bleaching, fixing, spinning and drying.

 The composition of the baths used is recalled in Table 2 below. These baths are marketed by the Eastman Kodak Company.

Table 2

<tb><SEP> Type <SEP> of <SEP> bath <SEP> Reference
<tb><SEP> Prebain <SEP> PB-2
<tb><SEP><SEP> Developer Bath <SEP> SD-49
<tb><SEP> Stop Bath <SEP><SEP> SB-14
<tb><SEP> Bath <SEP> fixer <SEP> F-34a
<tb> Bath <SEP> of <SEP> whitening <SEP> SR-29
<tb><SEP> Spin <SEP> Bath <SEP> FR-2
<Tb>
The compositions of these baths are given in Example 3.

B - Obtaining the positive for the theatrical screening
The color film obtained in the previous step A is the inter-positive from which the inter-negative and then the final positive intended for the cinematographic projection are prepared by implementing the conventional steps of FIG.
a) printing a virgin interlayer film coated with a silver halide light-sensitive emulsion according to the image of the interpositif obtained in step A);
ss) Standard (or conventional) development in accordance with Kodak ECN2 treatment standards including pre-wash, revelation, revelation stop, bleach, fix, spin and dry stages. The composition of the baths is shown in Table 3 below;
y) printing a positive virgin color film coated with a silver halide light-sensitive emulsion according to the image of the internegative obtained in step P);
5) Standard (or conventional) development according to Kodak ECP2 treatment standards including pre-wash, revelation, revelation stop, bleach, fix, spin and dry steps. The composition of the baths is shown in Table 4 below.

TABLE 3
Suitable baths for ECN2-Kodak treatment.

<Tb>

<SEP> Type <SEP> of <SEP> bath <SEP> Reference
<tb><SEP> Prebain <SEP> PB-2
<tb><SEP><SEP> Developer Bath <SEP> SD-49
<tb><SEP> Stop Bath <SEP><SEP> SB-14
<tb><SEP> Bath <SEP> fixer <SEP> F-34a
<tb> Bath <SEP> of <SEP> whitening <SEP> SR-29
<tb><SEP> Spin <SEP> Bath <SEP> FR-2
<Tb>
TABLE 4
Suitable baths for ECP2-Kodak treatment.

<tb><SEP> Type <SEP> of <SEP> bath <SEP> Reference
<tb><SEP> Prebain <SEP> PB-2
<tb><SEP><SEP> Developer Bath <SEP> SD-50
<tb><SEP> Stop Bath <SEP><SEP> SB-14
<tb><SEP> Bath <SEP> Fixer <SEP> F-35b
<tb><SEP> Bath <SEP> Accelerator <SEP> AB-lb
<tb> Bath <SEP> of <SEP> whitening <SEP> SR-30
<tb><SEP> Spin <SEP> Bath <SEP> FR-2
<Tb>

 These baths are characteristic of the development of a positive film.

 The compositions of these baths are given in Example 3.

Example 2
This example aims to highlight the quality of the contrasts obtained by implementing the method of the invention compared to the results obtained after conventional film processing.

 For this purpose, the characteristic curves of the modulation layers of blue, red and green of the same color film have been plotted in three specific cases, after printing and development of the positive color film.

 The intermediate color film used for printing is in all three cases a 5244 (35 mm) film marketed by the Eastman Kodak Company.

 In a first step, common to the first two cases, said intermediate virgin color film has been impressed, under the same conditions, according to the image of a developed negative starter.

 The next step is to develop the impressed color film. In both cases, this step was carried out under different conditions.

 The characteristic curves of FIG. 1 correspond to the implementation of a conventional method of development comprising the stages of revelation, stop of the revelation, bleaching, fixing, washing and drying, in accordance with the operating procedure described in example 1 for the standard development of the interposer (standard ECN2 processing).

 The characteristic curves of Figure 2 were obtained after development without bleaching of the impressed color film. The operating protocol followed is that described in Example 1 for the development without bleaching of an interpositive film (ECN2 treatment without bleaching).

 In the third case, we proceeded according to the invention.

 Specifically, the flashing of the film (step i) was carried out under the same conditions as in Example 1, before proceeding to the printing of the film according to the image of the color negative under the same conditions as for the two previous cases.

Subsequently, the resulting color film is developed without bleaching in accordance with the operating procedure described in Example 1.

 The characteristic curves of FIG. 3 were then plotted.

 As mentioned previously, the characteristic curve of a photographic layer represents the variations of the optical density as a function of the logarithm of the illumination.

 At each point, the tangent to the characteristic curve measures the contrast.

 A comparison of the curves of Figures 1 and 2 shows that after development without bleaching the slope of the characteristic curves increased abruptly: for the same image, the blacks are darker; however, we lose in color resolution. Indeed, at small variations in illumination corresponds a significant variation in the optical density.

 In contrast, a comparison of the curves of FIGS. 1 and 3 shows that the slope is substantially the same throughout the rectilinear part of the curves. The essential difference is in fact the level of the strong illuminations for which the values of the optical densities of the curves of Figure 3 are clearly superior to those found in the case of Figure 1: the result is that the blacks are darker, the Whites retain their intensity but, and this is the essential point, the shades of gradation are preserved.

 In fact, in the case of Figure 3, it is noted that the variations in optical density are less brutal for average increasing values of the illumination.

Example 3
Composition of development baths.

Pre-bath PB-2 water (27-28 ° C) 800 ml
Borax decahydrate 20.0 g sodium sulphate (anhydrous) 100 g sodium hydroxide 1.0 g water qs 1 1
The pH of this bath at 27 ° C. is 9.25 and its specific gravity at the same temperature is 1.094.

Developer bath SD-49 water (21-38 ° C) 850 ml Kodak anti-limescale no. 4 2.0 ml sodium sulfite (anhydrous) 2.0 g Kodak anti-veil no. 9 0.22 g sodium bromide (anhydrous) 1,230 g sodium carbonate (anhydrous) 25,6 g sodium bicarbonate 2.7 g developer Kodak CD-3R 4.0 g water qs 1 1
At 270C, the developer bath has a pH of 10.20 and a specific gravity of 1.029. CD-3 refers to sesquisulphate monohydrate of 4- (N-ethyl-N-2-methanesulfonylaminoethyl) -2-methylphenylenediamine.

Stop bath SB-14 water (21-38 ° C) 900 ml sulfuric acid (7.0 N) 50 ml water qs 1 1
The pH of the stop bath is 0.8 before use.

Fixing bath F-34a water (21-38 ° C) 700 ml Kodak anti-limescale no. 4 2 ml 58% ammonium thiosulfate solution 185 ml sodium sulfite (anhydrous) 10.0 g sodium metabisulfite ( anhydrous) 8.4 g water qs 1 1
At 27 ° C, the pH of this solution is 6.5 and its density is 1.086.

Spray bath FR-2 water (21-38 ° C) 900 ml stabilizer Kodak 0,14 ml dearcide 702R (KODAK) 0,7 ml water qs 1 1
Developer Bath SD-50 Water (24-38 ° C) 900 ml KODAK Anti-scale No.4 1.0 ml Sodium Sulfite 4.35 g KODAK CD-2 Developer 2.95 g Sodium Carbonate (Anhydrous) 17.1 sodium bromide (anhydrous) 1.72 g sulfuric acid (7, ON) 0.62 ml water qs 1 1
At 27.00C the pH of this bath is 10.5 and its density of 1.020. CD-2 refers to N, N-diethyl-2-methyl-p-phenylenediamine monochlorohydrate.

Fixing bath F-35b water (21-38 ° C) 800 ml ammonium thiosulfate 100 ml sodium sulfite (anhydrous) 2.5 g sodium bisulfate (anhydrous) 10.3 g potassium iodide 0.50 g water qsp 1 1
At 27.0 ° C., the pH of this bath is 5.8 and its density is 1.060.

Accelerator bath AB-lb: water (24-38 ° C) 900 ml sodium metabisulphite (anhydrous) 3.3 g glacial acetic acid 5 ml
KODAK PBA-1 3.3 g tetrasodium salt (ethylenedinitrilo) tetraacetic acid 0.5 g water
qsp 1 1
At 27.00C the pH of this bath is 4 and its density is 1.007.

SR-30 water whitening bath (24-38 ° C) 850 ml gelatin 0.35 g sodium persulfate 33 g sodium chloride 15 g sodium dihydrogenphosphate (anhydrous) 7.0 g phosphoric acid (85%) 2, 5 ml water qs 1 1
The pH of this bath is 2.3 and its density is 1.037 at 270 C.

SR-29 water whitening bath (32-43 ° C) 900 ml potassium ferricyanide 40.0 g sodium bromide (anhydrous) 25.0 g water qs 1 1
The pH of this bath is 6.5 to 27.00C and its density is 1.037 at the same temperature.

Claims (14)

 A process for producing a color positive film with contrast enhancement by intensifying dark shades from a developed color negative film, comprising the steps of a) producing an inter-positive film by  i) uniform exposure of an intermediate virgin color film coated with a silver halide light-sensitive emulsion to actinic light; then  ii) printing the film resulting from step i) by exposing said film to actinic light according to the image of the initially developed color negative film; then  iii) immersing the film resulting from step ii) in a basic developer bath comprising at least one reducing agent; then  iv) immersing the film resulting from step iii) in a stop bath comprising at least one organic or inorganic acid, and then rinsing the film; then  v) immersing the film resulting from step iv) in a fixing bath comprising at least one fixing salt capable of reacting with the silver halide present in said emulsion to form a water-soluble compound;  vi) spinning and drying said film; b) producing an inter-negative film from the interpositive film obtained in the previous step; and c) producing a positive film for cinematographic projection from the inter-negative film obtained in the preceding step b); steps b) and c) above including the steps  a-1) in the case of step b), printing a virgin interlayer film coated with a silver halide light-sensitive emulsion according to the image of the interpositif obtained in step at);  a-2) in the case of step c), printing a positive virgin color film coated with a silver halide light-sensitive emulsion according to the image of the internegative obtained at the step b); and  ss) standard development by revelation, stop revelation, bleaching with, if necessary, prior treatment by an accelerator, fixing, spinning and drying of said color film.  2 - Process according to claim 1, characterized in that the actinic light used in step i) results from the decomposition of a white light into its blue, green and red radiation, then mixing, in appropriate proportions, said blue, green and red radiations.  3 - Process according to any one of claims 1 and 2, characterized in that the composition of the actinic light used in step i) is such that the optical densities respectively associated with red radiation (DOR), green (DOV) and blue (DOB), measured after uniform irradiation of a virgin color film by said actinic light, and then conventional development of said film, are included in the following ranges of variation  0,1gDORs0,5  0,1sDOVs0,5  0.2sDOBg0,6, it being understood that said conventional development carried out before measuring the optical densities comprises the stages of revelation, stop of the revelation, bleaching, with, if necessary, treatment by an accelerator, fixing, spinning and drying.  4 - Process according to claim 3, characterized in that said optical densities associated respectively with the red (DOR), green (DOV) and blue (DOB) radiations are included in the following ranges of variation  0.2gDOR <0.3  0.15sDOV <0.25  0.40gDOB <0.50  5 - Process according to any one of the preceding claims, characterized in that the actinic light used in step ii) results from the decomposition of a white light into its blue, green and red, then the mixture in proportions appropriate of said blue, green and red radiation.  6 - Process according to any one of the preceding claims, characterized in that the composition of the actinic light used in step ii) is such that the optical densities respectively associated with red, green and blue radiation and measured after implementation , in order, steps R1, R2, R3 and R4 are within the following ranges of variation  IDRC <1.5  1,2 <ODvgl, 8  1.8 <DOB <2.2;  R1) uniform exposure of an intermediate virgin color film coated with a silver halide light-sensitive emulsion to actinic light;  R2) printing the film resulting from step R1) by exposing said film to actinic light in the image of a negative film representing an 18% gray;  R3) immersing the film resulting from step R2) in a basic developer bath comprising at least one reducing agent;  R4) immersing the film resulting from step R3) in a stop bath comprising at least one organic or inorganic acid, and then rinsing the film, fixing, spinning and drying.  7 - Process according to claim 6, characterized in that said optical densities respectively associated with red, green and blue radiation are included in the following ranges of variation  1,2sDORgl, 4  1.4 <ODvgl, 6  1, 9iDOBs2, 1.  8 - Process according to any one of the preceding claims, characterized in that step iii) is used as a developer agent a paraphenylenediamine.  9 - Process according to any one of the preceding claims, characterized in that in step iv), is used as organic or mineral acid sulfuric acid.  10 - Process according to any one of the preceding claims, characterized in that in step v) is used as fixing salt of ammonium thiosulfate.  11 - Process according to any one of the preceding claims, characterized in that, as intermediate color film, an anti-halo-coated color film is used, and, after step ii) d printing the color film, it is immersed in a pre-bath for hydrolyzing the anti-halo layer, before proceeding to step iii) of revealing said color film.  12 - Process according to any one of the preceding claims, characterized in that in steps b) and c), the bleaching is carried out by immersion of the color film, after stopping the revelation, in a bath comprising a chosen oxidizing agent among metallic ferricyanides and metal persulfates.  13 - Method according to claim 12, characterized in that, in step b), the bleaching is carried out by immersion of the color film, after stopping the revelation, in a bath comprising, as oxidizing agent, a metallic ferricyanide .  14 - Process according to claim 12, characterized in that, in step c), the bleaching is carried out by immersion of the color film in a bath comprising, as oxidizing agent, a metal persulfate and a catalyst of oxidation such as dimethylethylthiourea dihydrochloride.