EP0003118A1 - Process and apparatus for regenerating and maintaining the activity of a photographic treating solution - Google Patents

Abstract

Two solution concentrates (A, B) and dilution water (W) are used. One concentrate contains hydroquinone, sulfite and sodium formaldehyde bisulfite at a pH below 7, the other contains alkali, buffer substances and possibly Kompolexbildner. Both concentrates are free of bromine ions. The two concentrates are separated and metered in at the same time with a variable proportion of dilution water each time a piece of film to be developed is introduced into the developer tank (11). The concentration of the regenerator mixture or the addition of the dilution water is controlled in accordance with the machine throughput, whereby the concentration is high with a low machine throughput and vice versa. The concentration is controlled by means of time-controlled metering pumps (5, 6, 7) and a three-way valve (8) in the feed line for the dilution water, this valve (8) depending on the position, the water in the processing tank (11) or back to the storage vessel (3) directs.

Description

The invention relates to a method for regenerating and maintaining the activity of a photographic processing solution, in particular a lith processing solution, in a continuous processing machine which is intermittently loaded with exposed photographic material, the processing solution being in each case before, simultaneously with or after the introduction of photographic material Concentrates and dilution water existing regenerator is supplied.

• a) die chemische Erschöpfung durch den Verarbeitungsvorgang selbst,
• b) chemische Veränderungen, die nicht durch den Verarbeitungsvorgang, sondern durch andere Faktoren bewirkt werden, z.B. durch die Einwirkung von Luftsauerstoff, allmähliche Zersetzung einzelner Komponenten, Anreicherung von Nebenprodukten etc.

Care must be taken when processing photographic materials in automatic machines; that the individual processing baths have a constant activity, so that a constant processing quality is always achieved over a longer period of time. There are generally two different factors affecting the activity of the baths over time can change:

• a) chemical exhaustion from the processing itself;
• b) chemical changes that are not caused by the processing process but by other factors, e.g. through the action of atmospheric oxygen, gradual decomposition of individual components, accumulation of by-products, etc.

The change (a) is generally directly dependent on the amount of material processed; the change (b), on the other hand, is generally independent of the amount of material processed, but rather a function of service life and bath temperature.

It is therefore evident in many cases that it is not sufficient to regenerate the processing bath by adding used components in accordance with the amount of material processed; especially during longer downtimes, it will be much more necessary to take the service life of the bath into account and to introduce an additional replacement of components that have been lost due to spontaneous changes or changes caused by atmospheric oxygen.

Service life-dependent behavior is particularly evident in processing baths that contain substances whose effects are based on reduction and oxidation. In particular, it is photographic processing baths that can be easily oxidized by atmospheric oxygen. Another example are the color bleaching baths used in the silver color bleaching process, the effect of which is based on a relatively sensitive redox balance of the bleaching catalysts and oxidizing agents contained therein. However, the regeneration problem is particularly difficult with the so-called lith developers used for the development of high-contrast materials. These contain, in addition to Hydrochi non as the only developer substance, only very little sulfite and are therefore easily oxidized by atmospheric oxygen. In addition, other factors such as the pH and the current concentration of bromine ions are of crucial importance for the activity of lith developers. Since hydroquinone and sulfite are used in the development of photographic material on the one hand and bromine ions are released on the other hand, keeping the activity constant in such baths is a particularly difficult problem, and it is necessary to both the changes caused by the continuous development of photographic Compensate material as well as those caused by the changes as a result of different lengths of service life as precisely as possible.

• 1. Chemische Analyse der Badzusammensetzung und
• 2. Messung der Fläche unddes Schwärzungsgrades des entwickelten Materials.

For the regeneration of lith developers, it is common practice to use at least two or more different solutions, the composition of which is matched to one another in such a way that different activity ratios can be compensated for by different mixing ratios. Various measurement methods are generally used so that the type of activity changes occurring can be correctly recorded and the effect of the bath can be restored by adding suitable components. Two fundamentally different methods are used for this:

• 1. Chemical analysis of the bath composition and
• 2. Measure the area and degree of blackening of the developed material.

Both the first and the second method are relatively complex and only have a real value if they can be carried out with sufficient accuracy. The first method and its application in an automated lith developer regeneration system is, for example, in Deut The German Offenlegungsschrift 2 119 069, the second described, for example, in German Offenlegungsschriften 2,343,242 and 2,343,318. In the methods described in these publications, three different solutions are generally used, the total amount and proportion of the proportions used for the regeneration being determined on the one hand from the amount of film material processed and its degree of blackening, and on the other hand from the service life of the tank content by a relatively complex automatic device and is added at periodic intervals.

From US Pat. No. 3,162,534 a process for the regeneration of lith developers is known, in which only two solutions are used, one of which, of low concentration, for compensation in accordance with the amount of film developed, the other, of higher concentration, for periodic compensation of the changes caused by the service life. Both solutions contain no hydroquinone; the activity of the solutions can therefore only be maintained in this way for a certain limited time.

_. The usual regeneration method, as is used in particular in the case of automatically working development machines, consists in adding measured amounts of the regenerator liquids to the tank contents at periodic intervals and / or at intervals controlled by the amount of material to be processed, while at the same time a corresponding amount of liquid is added by an overflow, the composition of which corresponds to that of the current tank content is fed to a sewage pipe. As a result, the processing liquid maintains a constant volume during the entire operating time and is maintained at constant activity by the constant supply of regenerating liquid.

The object of the invention is to provide a particularly simple method for the regeneration of lith developers, which is particularly suitable for automatic development machines and only requires a single regenerator in which the active components are contained in a constant ratio. In particular, the method according to the invention should not require any complex methods for determining the bath composition or the blackened film surface and nevertheless allow the activity of the lith developer to be maintained for a very long time, e.g. in constant operation for several months to keep constant. This goal is achieved by the measures specified in claim 1.

In practice, the regenerator is preferably divided into two solution concentrates, one of which at a pH below 7 hydroquinone, sulfite, sodium formaldehyde bisulfite and the other, at a higher pH alkali, buffer substances and any other components such as complexing agents and aromatic amines contains, both concentrates being free of bromine ions. Furthermore, the two concentrates are simultaneously, but separately, and metered into the development tank with the dilution water each time a piece of photographic material to be developed is introduced into the developer tank, it being sufficient to determine the blackened portion of the piece based on experience. The ratio of the amount of regenerator converted in the unit of time to the content of the processing tank is used as a measure of the throughput.

By means of the procedure according to the invention it is achieved that both the concentration of bromine ions which is decisive for the activity of the developer solution and that of the hydroquinone which is subjected to air oxidation can be kept largely constant. When developing exposed photographic material, it is known that bromine ions are released, the amount of which in the photographic layer silver bromide and the exposed area is proportional. Since the total volume of the regenerator added is kept proportional to the area of the blackened film to be developed, the concentration of bromine ions in the processing bath remains constant: for each unit area of blackened film, a certain amount of bromine ions is newly introduced into the bath; however, with each dosing burst a proportion by volume of the bath, which is proportional to the developed area, is removed by the overflow. As soon as the process is in equilibrium, the amount of new bromine ions that are created and those that are continuously removed from the bath are inevitably the same. On the other hand, the variation of the regenerator concentration serves to keep the hydroquinone portion constant: with a low machine throughput, the portion of the hydroquinone lost through air oxidation is relatively large. Conversely, with a large machine throughput, the hydroquinone consumption prevails through the normal development process. By using a thinner regenerator at high throughput and a more concentrated one at low throughput, the hydroquinone content of the processing bath can be kept constant.

When the machine is idle for a longer period of time, hydroquinone is consumed by air oxidation without the bromine ions being released at the same time. This influence can now be compensated for by adding an amount of the regenerator corresponding to the expected loss in a concentrated state. If the regenerator concentrates do not contain bromine ions, the bromine ion concentration in the developer liquid changes only very slightly as a result of this measure, namely in accordance with the proportion lost by the overflow, which can be kept very small by omitting the dilution water.

If A and B are the two regenerator concentrates and W is the dilution water, the change in concentration is preferably carried out in such a way that both the Ge total amount of regenerator liquid for a unit area of blackened film and also keeps the ratio of the two regenerator concentrates constant and only changes the amount of dilution water in relation to the amount of the two regenerator concentrates, ie

The regenerator concentration is preferably changed in stages in accordance with the throughput. The minimum concentration, that is to say the minimum ratio of concentrate quantity / total regenerator quantity, can be chosen to be about 2: 6 and can be assigned to a maximum throughput of 60% or higher of the development tank volume. The maximum regenerator concentration depends on the practical minimum throughput, for example approximately 10% regenerator conversion, and can be approximately 2.5: 6 to 3: 6. The most favorable values of course depend on the type and composition of the processing solution and the regenerator.

The invention also relates to a device for carrying out the method
three storage tanks for the two concentrates and for the dilution water, three metering pumps for the concentrates and the water, which are connected by lines to the concentrate and water storage tanks on the one hand and to the processing tank on the other, and is characterized in that the control system is the first input device for the Surface, the exposed portion and a type-dependent characteristic size of the photographic material and a second input device for the expected throughput, and that it the respective amount of the regenerator from the parameters entered by means of the first input devices and the respective from the parameter entered by means of the second input device Determines the concentration of the regenerator and controls the metering pumps accordingly.

• Fig. l - das Ausführungsbeispiel in schematischer Darstellung
• Fig. 2 - ein Blockschaltschema der Steuerung in Fig.l.

An exemplary embodiment of a device according to the invention is explained in more detail below with reference to the drawing. Show it:

• Fig. L - the embodiment in a schematic representation
• Fig. 2 - a block circuit diagram of the control in Fig.l.

As shown, the device comprises three storage vessels 1, 2 and 3 for concentrate A, concentrate B and dilution water W, three metering pumps 5, 6 and 7 driven by a common drive motor 4, a three-way valve 8, a controller 10 for the drive motor 4 and the three-way valve 8 and a processing machine with tanks 11, 12 and 13 for developer, fixer and washing.

The regeneration concentrates A and B and the dilution water W get from their respective storage containers 1, 2 and 3 via lines 14, 15 and 16, the metering pumps 7, 6 and 5 and further lines 17, 18 and 19 into the developer tank 11. The three-way valve 8 lies with its input and its one output in line 19. Its other output is connected to a line 20 which, when the three-way valve is not activated, returns the water to the water reservoir 3.

The controller 10 comprises first setting elements 21, 22 and 23 to take account of the film area, exposure ratio and film characteristics (silver content per unit area) as well as a second setting element 24 to take into account the machine throughput, as well as a start button 25 and generates pulses t ₁ and t ₂ , which the motor 4 and thus put the three metering pumps into operation for the time period t ₁ and activate the three-way valve for the time period t ₂ , so that the regeneration concentrates and the water can get from the storage vessels 1, 2 and 3 into the developer tank 11 during this time. The lengths of the pulses t ₁ and t _{2 can be} influenced in opposite directions by means of the second setting element 24. The controller 10 is designed so that when the engine maximum throughput corresponding position of the second input member 24, the lengths of the two pulses t _l and t ₂ of the same size and equal to a Grundsteuerim ^p uls t _0, which results in the greatest dilution of the regenerator.

The required length of the basic control pulse t ₀ results directly from the constant total amount A + B + W of regeneration liquid required and the output of the metering pumps. This total amount is an empirical value and, as already mentioned, depends, among other things, on the characteristics (silver content) S, exposure proportion E and area F of the film material to be processed. t ₀ is designed for the maximum intended dilution of the regeneration liquid, which is obviously achieved when the three-way valve is activated during the entire operating time of the metering pumps, so that no water is recirculated via line 20. The ratio of regeneration concentrate to dilution water (A + B): W is minimal in this case and is referred to as X below. This ratio is set by appropriate dimensioning or setting of the metering pumps.

The ratio of regeneration concentrate (A + B) to dilution water W can be increased according to the machine throughput by means of the setting element 24. This takes place in that the pulse t ₂ is shortened by a factor Z, which can be set in five stages by means of the setting element 24 between 1 and approximately 0.85, in comparison with t0

So that the total amount of regeneration liquid A + B + W mentioned above remains constant, the duration of the pulse t ₁ must meet the following condition

For the special case of greatest dilution, i.e. for Z = 1, the two conditions (I) and (II) go for t ₁ and t ₂ again over in t ₁ = ^t ₂ ⁼ t ₀ .

A block circuit diagram of the controller 10 is shown in FIG. 2. In addition to the start button 25 already mentioned and the input elements 21-24, it comprises four multipliers 101-104, an integrator 105, an adder 106 and two comparators 107 and 108.

For reasons of drawing, the input organs are symbolized by potentiometer signs. Potentiometers would allow a continuous input of the size area F of the material to be processed, exposure proportion E, film type S and throughput Z. In practice, however, tap changers instead of potentiometers have proven to be completely sufficient and in some cases even more appropriate.

) bzw. (

), wobei die Werte X entsprechend ihrer schon weiter vorne gegebenen Definition in der Regel fest eingestellt sind. Die Ausgangssignale der beiden Multiplikatoren 103 und 104 werden im Addierer 106 summiert und dann zum einen Eingang des Komparators 107 geführt. Das Ausgangssignal des Multiplikators 102 ist zum einen Eingang des zweiten Komparators 108 geführt.The multipliers 101 and 102 form the products EF and E · F · Z of the quantities E, F and Z entered. The multipliers 103 and 104 multiply these products by the terms (1 +

) or. (

), whereby the values X are generally fixed according to their definition given earlier. The output signals of the two multipliers 103 and 104 are summed in the adder 106 and then passed to one input of the comparator 107. The output signal of the multiplier 102 is fed to an input of the second comparator 108.

ergibt, worin k stellvertretend für alle Systemkonstanten des Integrators 105 steht und t die Zeit bedeutet. Dieses Ausgangssignal wird nun den jeweils zweiten Eingängen der Komparatoren 107 und 108 zugeführt und mit den Ausgangssignalen des Addierers 106 bzw. des Multiplikators 102 verglichen.The input element 23 (film type S) goes directly into the time constant of the integrator 105. After reset by the start button 25, this integrator integrates a constant signal in such a way that its output signal increases

results in which k represents all system constants of integrator 105 and t means time. This output signal is now fed to the respective second inputs of comparators 107 and 108 and compared with the output signals of adder 106 and multiplier 102, respectively.

die Grösse der jeweils an den anderen Eingängen der Komparatoren anliegenden Spannungen erreicht, kippt der betreffende Komparator und beendet damit den Impuls t₁ bzw. t₂, wodurch die Dosierpumpen bzw. das Magnetventil wieder ausser Betrieb gesetzt werden. Die Komparatoren verbleiben dann in diesem Zustand, bis sie durch Betätigung des Startknopfs von neuem gekippt werden.If a piece of photographic mate to be developed rials is entered into the developing machine, film type S, area F and exposure component E are set and the start button 25 is actuated, the start pulse optionally being triggered automatically by a microswitch or the like each time a film piece is input. The machine throughput Z estimated for the day was set at the beginning of the day. After the integrator has been released by the start button, the output signal of the integrator is zero, so that the outputs of the comparators become positive and thus activate the metering pumps and the solenoid valve via servo amplifiers (not shown). Once the integrator output voltage

reaches the size of the voltages present at the other inputs of the comparators, the comparator in question tilts and thus ends the pulse t ₁ or t ₂ , as a result of which the metering pumps or the solenoid valve are put out of operation again. The comparators then remain in this state until they are tilted again by actuating the start button.

Wenn der Wert

mit t₀ bezeichnet wird, gehen diese Formeln direkt in die Formeln (I) und (II) über.As can be seen from FIG. 2, the time periods of the pulses t ₁ and t ₂ result in:

If the value

denoted by t ₀ , these formulas go directly into formulas (I) and (II).

The system constants of the integrator 105 represented by k are, of course, to be designed in such a way that the desired metering volume is obtained for the given dimensions of the feed pumps. However, this requires no further explanation for the person skilled in the art.

While maintaining a constant activity of lith developers according to the previously known methods requires continuous, complex control of the bath activity or the operating conditions while at the same time taking the service life into account, it is surprising Schend that according to the inventive method and with the device required for its implementation, the same result can be achieved by simply changing the degree of dilution of the regenerator liquid or the amount of dilution water added simultaneously with the concentrates according to the machine throughput.

The direct use of concentrates and the supply of the dilution water to the processing tank also simplifies the preparation work by eliminating the need to prepare diluted regenerator solutions from the components or from the concentrates.

The following example is intended to explain the method and the mode of operation of the device according to the invention in more detail, although the invention should of course not be limited to the composition of the components shown in this example.

example

A high-contrast photographic material with a silver halide emulsion layer, which contains 6. gr of developable silver per m ^{2 of} the emulsion layer in the form of 70 mole percent silver chloride and 30 mole percent silver bromide, is exposed in a conventional manner and then introduced in the form of individual sheets into a continuous processing machine.

The first tank of this processing machine contains 64 liters of a developer solution, which contains the following substances per liter:

At a temperature of 25 ° C the development time is 1.8 minutes.

• Regeneratorkonzentrat A:
  
• Regeneratorkonzentrat B:
  

In order to keep the activity of this solution constant for a long time, a regenerator solution of the following composition is added when each sheet is introduced into the machine:

• Regenerator concentrate A:
  
• Regenerator concentrate B:
  

1 liter of diluted regenerator solution is added to the developer on each square meter of exposed area of the photographic material, components A and B being diluted with water as shown in Table 1 below, depending on the machine throughput. According to the invention, components A and B and the dilution water are introduced into the developer tank at the same time in individual portions by means of a metering pump.

In the event of a foreseeable machine downtime with the heating switched off and the developer not circulating for more than 48 hours, 160 ml of the two concentrates A and B = 0.25% of the tank content per 24 hours of downtime are added to the development tank.

Provided that the development time and temperature are observed, the same results are still obtained after a period of 6 months.

Claims (13)

1. A method of regenerating and maintaining the activity of a photographic processing solution, particularly a Lith developing solution, in an intermittently with exposed photo ^g rafischem material loaded continuous flow processing machine, the processing solution in each case prior to, simultaneously with or after the introduction of photographic material a from Concentrates and dilution water is supplied to the existing regenerator, characterized in that the concentration of the respectively added regenerator, ie the proportion of the concentrates in the regenerator, is chosen to be higher or lower, depending on whether the throughput expected for a given period, in particular 1 day, is present photographic material is smaller or larger. 2. The method according to claim 1, characterized in that essentially bromide-free concentrates are used for the regenerator. 3. The method according to claim 1 or 2, characterized in that the amount of regenerator added per regeneration process, based on the exposed unit area of the given photographic material, is kept constant. 4. The method according to claim 1, characterized in that the quantitative ratio of the concentrates in the regenerator is chosen to be constant regardless of the degree of dilution. 5. The method according to claim 4, characterized in that a mixture of two concentrates and water is used as the regenerator. 6. The method according to claim 1, characterized in that the concentration of the regenerator at a daily minimum throughput, which corresponds to a consumption of regenerator liquid of 60 or more percent of the development tank content, reaches a minimum and at lower throughputs in several, corresponding throughput ranges assigned levels up to is increased to a maximum corresponding to the lowest expected throughput. 7. The method according to claim 6, characterized in that the minimum regenerator concentration is selected approximately 2: 6. 8. The method according to claim 7, characterized in that the maximum regenerator concentration is selected about 2.5: 6 to 3: 6. 9. The method according to any one of the preceding claims, characterized in that when the processing machine is shut down for a longer period of time, preferably more than two days, a concentrate mixture without dilution water is metered in as an amount to compensate for the changes during the downtime such that the photographic activity of Processing solution is retained over the expected downtime, with the expected loss of activity per unit of time being determined in advance according to methods known per se. 10. Apparatus for performing the method according to claims 1 to 5 with three storage containers for the two concentrates and for the dilution water, with three metering pumps for the concentrates and the water, which on the one hand and with the processing tank through lines with the concentrate and water storage containers ver are bound, and with an electrical control for the metering pumps 23, characterized in that the control has first input elements for the area, the exposed portion and a type-dependent characteristic size of the photographic material and a second input element for the expected throughput, and that it consists of determines the respective quantity of the regenerator from the parameters entered by means of the first input elements and determines the respective concentration of the regenerator from the parameters entered by means of the second input element and controls the metering pumps accordingly. 11. The device according to claim 10, characterized in that the three metering pumps are driven by a common drive controlled by the controller, that in at least one of the three lines leading from the pumps to the processing tank, a three-way valve is installed such that that of the pump in question conveyed liquid in a first position of the valve to the processing tank and in a second position of the valve back to the inlet side of the pump or into the storage vessel, - and that the controller regulates the concentration of the regenerator by the three-way valve during a through the brings the second input member into its first position within a driving time of the metering pumps determined by the first and second input members. 12. The apparatus according to claim 11, characterized in that the three-way valve of the metering pump for the dilution water is connected downstream. 13. The apparatus according to claim 12, characterized in that the controller, the respective drive duration t _{l of} the metering pumps and the part time t ₂ , during which the three-way valve is in its first position, according to relationships

determined in which t _o means the pump running time required for the given delivery rates of the metering pumps in order to promote the amount of regenerator determined for Z = 1 by the first input elements, where x means the ratio of the total amount of concentrate to the dilution water determined for Z = 1 by appropriate dimensioning of the delivery pumps and where Z is a factor ≤1 determined by the second input organ.

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