DE1926297C3 - Refill device for automatic film developing devices - Google Patents

Description

The invention relates to a refill device for an automatic device for imagewise developing exposed films with a loading device that automatically feeds fresh developer and fi

supplies xier fluid on the basis of control signals, which are generated by means of a scanning device through which an exposed, continuously moving Film between a light source and a light electrical arranged on the other side of the film Transducer is passed, and the size of which depends on the degree of permeability of the film.

At d Rdk'hl

uci'i modern

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for films, the exposed film is fed through an automatic developing device at a very high speed, the film being introduced at one end of the developing device and coming out fully developed, fixed, washed and dried at the other end. Because of the high speed and the resulting large amount of film that passes through the developing device per unit of time, the photographic solutions are used up fairly quickly, so that replenishment is necessary at certain time intervals. So far, the filling was mostly done by the operator, the aids such as test film
used strips and the like. However, one relied mainly on the experience of the operator

person and the knowledge of the daily workload. Whether this method is successful or not, so it depends on the experience and attention of the operator.

From the German patent 678 232 it is known the refilling of fresh solution and the discharge of a corresponding amount of excess, used one Solution to run independently of an operator by the fact that the Area of the treated film passed through the solution, measured by its length, for control purposes the refill or discharge quantity. Since the actual consumption of the solution is not taken into account, the state of the solution can only be kept approximately constant. A surveillance " Protection against undesired deviations in concentration is still required. A device of the type mentioned at the beginning is known from US Pat. No. 1,895,760, in which a Tes'-film at the same time as the image-wise exposed film is carried out through the developing and fixing liquid, which previously exposed uniformly has been and is scanned afterwards with the aid of a scanning device. In this way, two determine whether the developer and fixer is still usable or has already been exhausted. The disadvantage here is that an additional film is required and that additional facilities for the guidance and exposure of this test film are required, which must be maintained. Besides that a new spool with test film must be inserted at certain time intervals.

The invention is based on the object of creating an automatically operating refilling device, which is simple and reliable in structure and which depends on the supply of fresh treatment liquids made possible by the amount actually consumed.

This object is thereby achieved in a device of the type mentioned at the outset according to the invention solved that the scanning device is arranged on the path of the imagewise exposed film that a second photoelectric converter is provided, which is acted upon by light from the light source, which is not is modulated by the fixed, imagewise exposed film that a differential amplifier is provided, whose inputs are connected to the output of one or the other electrical converter and its output signals are a measure of the degree of permeability of the just scanned, imagewise exposed film cut, and that a the output signals of the amplifier are received Integrator is provided. its output signals one of the mean value of the input signals and the time-dependent size that a comparator is provided which the output signals of the Compares integrator with a fixed DC voltage and generates an output signal when the input signal reaches or exceeds the magnitude of the comparison voltage, and that a the output signals of the comparator counting / ahle provided Is, which then generates the control signal for the loading device when it has a predetermined number has counted the output signals of the comparator. at this Linriehümgwiril the blackening of the pictorial exposed film to control the refill process approach. Since this blackening is an unmillable mark.Wui il <ί tatvu hlichcn consumption of 1 ommij; supplies, it is thus ensured that the developer and fixing liquid is always quickly and automatically in the correct amount is refilled so that the solutions always maintain their effectiveness. You are completely independent of the inadequacy of human surveillance activities.

In an article by ZEISS-WERKZEIT-SCHRlFr, No. 21 of August 1956, are under the Title "Electrical procedures in optical devices" the basic structure of electrical photometers, their various circuit options and their properties are described. This essay could for the subject of the invention all-'S if taken, how the photometric part was to be formed. For the idea of the invention itself, the blackening of the imagewise exposed and developed film as a measure of the consumption of developer and to use fixing solution and thus to control the refilling of fresh solution this article does not provide any guidance.

German Patent 717 367 describes a process for developing photographic image and sound recording copies as a function of the ² S density and / or the contrast of the negative. Reversible developers, namely redox systems, are used, the reduction potential of which is controlled according to the density or contrast of the negative, in order to compensate for the contrasts through soft development, especially in the case of copies of a scene that contains large contrasts between light and shadow, or in the case of copies To be able to increase the contrasts in the positive of dull negatives. This method therefore requires a fully developed original film, regardless of the type of film, in order to control the development of the copy as a function of its density and / or contrast values. However, this method is not suitable and also not modifiable so that a device could then be created with which the developer and fixing solutions could be refilled to the extent that they are used up.

The invention is explained below with reference to an embodiment shown in the drawing. It shows

Fig. 1 is a schematic representation of an automatic Filrnentvickluiigsvornchtung in connection with the embodiment,

FIG. 2 shows an enlarged detail from FIG. 1 with part of the scanning device,

3 shows a circuit diagram of the exemplary embodiment, shown partially as a block diagram.

The present invention is particularly suitable for use in automatic photography Film developing device in which the exposed photographic film is fed into the developing device is introduced and developed, fixed, soaked and dried one after the other. In Fig. is therefore shown such an automatic film developing device 10, which with an automatic working, electronic refill device is provided.

The F.ntwickhmgsvoi 11 Jitung 10 borders on one IHinkelkainmerwandverkicendung 12 at, the mi

fi ₅ 14 marked side, W wall cladding facing the dark fireplace. while page 16 is exposed to the normal üchlve.halimssen. A HIm e.nfuhrslelle IS is the only part that is in you

Darkroom protrudes; the remainder of the developing device is placed in a normally lit room since the remainder of the film developing device 10 is enclosed in an opaque container 20. The introduced film F is fed through a developing tank 24, a fixing tank 26, and a washing tank 28 one by one by roller conveyors 22.

In preparation for drying, the film F runs through a water removal device 30 which is arranged at the entrance to a film drying section 32. The film dry part 32 consists of a columnar arrangement in which the film is transported to the exit by means of rollers not denoted by reference numbers. An air blower 34 supplies thermostatically controlled, warm, filtered air through a plurality of tubes 36 in order to ensure uniform drying.

Upon exiting the film drying section 32, the film is fed by the automatic electronic refill control device scanned according to the invention. The dried film first goes through a part of the light collecting means 38 constituting the scanning means. Here, the film is through the light collecting system scanned to determine the areas that have been photographically developed to thereby form a Value for the work done by the developing and fixing liquids / u. The ones from Lichtsammclsysiem determined Lichtmeßvvertc are to an electronic designated as a whole with 40 Circuit passed. This circuit 4 () then outputs a signal. if the developer and Fixing liquids have achieved a certain level of chemical activity. The Signa! of the electronic circuit 40 is then used to deliver a pulse to a stepper motor 42, which can turn in single steps. When the stepping motor 42 moves a predetermined Has rotated angle, he operates a microswitch 44; after actuation of the microswitch 44 this sets Timers 46 and 48 in operation which control the supply of developer and fixer solution. The timer 46 controls a pump 50, the fresh developer solution through a flow meter 52 into the developing tank 24 lets flow. Accordingly, the timer 48 controls a pump 54, which is controlled by a flow meter 56 Er replenishment solution in the fixing tank 26 delivers.

The light collection device 38 is shown in greater detail in FIG. It should be made clear here that the light collecting unit need not be arranged at the exit of the film drying part 32. Within the Within the scope of this invention, the light collection device 38 can be located where the film is from the washing tank 28 emerges. Once the film is fixed and the image developed cannot change it, it is entirely possible to use the light collecting device Subsequent to the fixing tank at any suitable location.

The Lichtsaromeleinrichuing 38 comprises a light source, which is an incandescent lamp 58 in the exemplary embodiment. Preferably a single light source is used use !, so that as the Ouclle the film to be scanned throughout the same (trad is concerned. When more aK one light source is used, the problem emerges. the individual 1 lchtquelli'ii to coordinate.

The light 60 from the lamp 58 is modulated differently as a function of the enluiect Ilen and flour developed U Iu η make of the moving film F. The light 60 shown here with only a single main beam is reflected by means of a 45 "mirror 62 onto a lens system 64, which is symbolically represented here by a biconvex lens. The light from the lens system 64 hits a barrier cell 66, which in the exemplary embodiment is a selenium cell Light that is not modulated by any moving film is directed onto a second barrier cell 68, the unmodulated light being brought from lamp 58 to cell 68 by any suitable means, in the embodiment a light guide 70, which is also bent The protective layer cells 66 and 68 form part of the scanning device

'5 device, which in turn forms part of the circuit 40.

Cells 66 and 68 are shown here as junction cells; but it goes without saying that all photoelectric transducers can be used, d. H. that the transducers by means of a barrier layer effect, Photolcitbarkeitkcit or Photoemission can work.

The electronic circuit 40 is illustrated in greater detail in FIG. The cathodes of the layer cells 66 and 68 are connected to the ends of a potentiometer 72, the center tap 74 with Ground is connected. The anodes of the protective layer cells 66 and 68 are connected to the two inputs of one Differential amplifier 76 connected, which is a functional amplifier belonging to the prior art is. A variable resistor 78 is located in the feedback path of the differential amplifier 76 from the Output terminals to the anode of the junction cell 66. A monitoring voltmctcr 80 is connected on the one hand to the Output of differential amplifier 76, on the other hand connected to ground. The output of the differential amplifier 76 is connected via a resistor 82 to the input of an integrator, which acts as an amplifier 84 is formed with a capacitor 86 in the feedback path.

The output of the amplifier 84 is connected to one input of a differential amplifier by means of a resistor 90 88 connected with high gain, which forms a comparator. At the other input of the differential amplifier 88 is a reference voltage, the voltage source being connected to the input via a resistor 92. the Amplifier 88 has a feedback resistor 94. The only output of amplifier 88 is connected to the base of a PNP transistor 96 through a resistor 98. Two connected in series Diodes 100, 102 are between the emitter of transistor 96 and ground. The cathode of the diode 102 is connected to ground and the anode of diode 100 to the emitter of transistor 96. The Emitter is also connected to a voltage of + 24V via a resistor 104.

A relay 106 is also provided, the coil of which is connected in series with the collector of the transistor 96 and in parallel with a diode 108. the polarity shown is preserved. The relay 106 has immovable contact pieces 110, 112 and 114, 116. When the relay is de-energized, the movable contact corners of the relay 106 rest against the contact gaps 112 and 116, as shown in FIG. The contact piece 110 and the associated movable contact piece form a switch that controls the con (lens.itor 86 in the unavailable state \\ u / ^ hltcl ';

92b

The purpose of this is explained below.

The contact pieces 114 and 116 are in the excitation circuit of the stepping motor 42. The stepping motor 42 belongs to the prior art; it consists of a permanent magnet motor and a wound stator. The rotor shaft rotates in stages according to the energy applied to the stator windings 118 and 120. The energy is supplied by a direct current source, such as a battery 122 . In the de-energized state of the relay 106 , the circuit of the winding 118 is closed, and in the energized state, the circuit of the winding 120 is closed.

The microswitch 44 has a movable contact piece 124 which is connected via a resistor 126 to a voltage source of +24 volts. The contact piece 124 is designed so that it can be moved between the contact pieces 130 and 132 . When it rests on the contact piece 132 , the microswitch 44 causes a capacitor 128 to be connected to the winding of a relay 134, the other side of the relay winding and the capacitor 128 being connected to ground. The relay 134 has contact pieces 136, 138 and 140 and 142. The movable contact pieces ^ of the relay 134 are applied to the contact pieces 138 and 142 when this is not in motion

As FIG. 3 shows, the contact pieces 136 and 138 are assigned to the timer 48, the pump 54, and the inflow meter 56, while the contact pieces 140 and 142 are the timer 46, the pump 50 and the inflow meter 56.

Before using the developing device, it is first necessary to calibrate the device accurately. This is done by closing a switch .S (Fig. 3) and by passing either a perfectly clear film strip or a film strip with a selected minimum blackening through the light collecting device 38. The Mitlelabgriff of the potentiometer 72 is then set so that the voltmcsser 80 zero or indicates a minimum voltage. Next, a strip of film is passed through the collector, which either has a selected maximum blackness or is completely black, i.e. 100% developed The purpose of this setting is to obtain an essentially linear output variable between zero and KW ·; Development or between the minimum optical density D ^ ₁ -, and the maximum optical density D _{max of} the photographic film. The refill device is then linearly calibrated and the voltmeter is now switched off using switch S.

In Normaibelneb when the film is guided by the light collection device that develop ZEI Li '( "6 and 68 you highest voltage during the passage tine- clear film or none film. That is TIIE norm of the cell 68. The cell 66 then scans tic'i photographically fixed film, and the modulietu light by which it is exposed depends on the changed permeability of the fixed film, which thereby causes a variable signal voltage.

The output of the differential 76 is

- K (r,

C _{11 is} the output of the differential amplifier, K is the gain as determined by the setting of the

Resistance 78 has been established,
C, the voltage developed by cell 68.

_v: the v in cell 66 developed.

The output C _{0 of} the differential amplifier 76 is applied to the amplifier 84 and, as a result, the capacitor 86 is charged.

Under typical operating conditions, the

i "zugsspannung V _rej of the comparator on almost exactly -4 V set. In the off state of the output of the amplifier 88 provides approximately 3.2 V with respect to ground, whereby the base of the transistor has a potential of +3.2 V relative to ground. As a result of of the current from the +24 V source through the resistor 104 and through the series-connected diodes 100 102 , the emitter is at a potential of approximately +1 V with respect to ground composition, the voltage of 1 V has is durcl: this bias at the emitter-base Strcckc dcf transistor 96 of this non-conducting when the sensed film passes through the Lichtsammelcinrichtung 38, the capacitor is charged 86 is the derr amplifier 88 supplied from the amplifier 84.. If the voltage - 4 V or more, the comparator will output an output voltage, the output voltage of the amplifier 88 dropping to approximately -0.5 V with respect to ground. Base route de; Transistor 96 is now operated in the forward direction, it becomes conductive. The base comes here aiii 1-0.7 V or almost + 1 V with respect to ground. As a result of the conductivity of the transistor 96, a collector current flows through the coil of the relay 106, and the coil is excited for a moment, so that the contact pieces 110 and 114 close.

The stepper motor 42 could be controlled by a flip-flop circuit, but in the game Ausführungsbei a constant current flows through the winding

1 18. and a pulse is delivered to the other winding 12 ( when the relay ίϋό is energized. It is; zi note that contacting the contact piece 1 14 to the coil 120 of the stepper motor 42 energizes, which causes the motor 42 rotates by one step, for example by an angle of 15 ". When the relay contact 110 makes contact, the capacitor 86 is short- circuited. The diode 101 helps to maintain the flow of current through the coil of relay 106 .

The discharge of capacitor 86 causes the circuit to return to its initial state, transistor 96 is switched off again, the possible contacts; the relay 106 returns to its rest positions and comes into contact with contact pieces 112 and 116 . The process increases again and is cumulative with the continuous film passage through the light collecting device 38. Dl · charge of the capacitor 86 increases slowly or more quickly, depending on the state of the immediately scanned film, whereby the transistor 96 j. after sooner or later becomes conductive in order to actuate the relay 106. Each actuation of the relay 106 causes the stepping motor 42 to be switched on by a specific angle or step. The shaft of the stepping motor 42 has a cam. which is arranged so that a slot in the cam wheel actuates the movable contact piece 124 of the micro switch 44 after the MotorweMc to ei

409 630 '261

has rotated a new predetermined angle.

Capacitor 128 is connected through resistor 126 to the +24 volt source charged when the contact piece 124 contacts the contact piece 130. When the slot of the cam wheel of the stepping motor 42 reaches the movable contact piece of the microswitch 44, it is moved and makes contact with the contact piece 132. The charged capacitor 128 will now self-discharge across the coil of relay 134. The rapid discharge of capacitor 128 across the coil of relay 134 causes the contact pieces 136 and 140 to be excited and contacted Timers 46 and 48 energized, with timer 46

10

for the developing solution and the timer 48 for the fixing solution. The timers 46 and 48 are standard timers in the prior art and can set to values between one and sixty seconds or more. Each timer operates its associated pump for the desired length of time. The flow meters 52 and 56 are set to have a predetermined number of milliliters per minute so that the pumps then get the right amount of developer and fixer solution pumps from sources not shown into the respective tanks 24 and 26 and a supplement on the basis of the empirically determined values.

1 sheet of drawings

Claims (7)

1 926 2S7 claims: 1. Refill device for an automatic device for developing imagewise exposed films with a loading device that automatically supplies fresh developing and fixing liquid on the basis of control signals generated by a scanning device through which an exposed, continuously moving film between a light source and a on the other side of the film arranged photoelectric transducer is passed, and the size of which depends on the degree of transparency of the film, characterized in that the scanning device (38, 66, 68, 72, 76, 78) on the path of the image-wise exposed film ( F) is arranged that a second iichtelectric converter (68) is provided, which is acted upon by light from the light source (58) which is not modulated by the fixed, image-wise exposed film (F), that a differential amplifier (76) is provided whose two inputs are electrically connected to the output of one or the other en converter (66 or 68) are connected and whose output signals are a measure of the degree of transparency of the currently scanned, image-wise exposed film section, and that the output signals of the differential amplifier (76) received integrator (84) is provided whose output signals a have the mean value of the input signals and the time dependent size that a comparator (88) is provided which compares the output signals of the integrator (84) with a fixed DC voltage and generates an output signal when the input signal reaches or exceeds the size of the comparison voltage, and that a counter (42, 106) counting the output signals of the comparator (88) is provided. which then generates the control signal ¹ for the loading device when it has counted a predetermined number of the output signals of the comparator (88). 2. Device according to claim 1, characterized in that the two photoelectric Converters are each designed as a photocell (66, 68), the cathodes of which with one or the other End of a potentiometer (72) are connected to a variable tap (74), the position of the tap (74) defines the minimum optical density of the film (F) which the device still processed. 3. Device according to claim i or 2, characterized in that the differential amplifier (76) has a feedback with a variable resistor (78) whose setting the maximum optical density of the film (F) which the device is still processing. 4. Device according to one of claims 1 to 3, characterized in that the integrator is designed as an integrating amplifier (84) with a capacitor (86) in the feedback circuit and a discharge device (106, 110) is provided which discharges the capacitor (86) when each output signal of the compensator occurs. 5. Device according to one of claims 1 to 4, characterized in that diii. · Lk comparator as a differential amplifier with high gain and a single output and two inputs, one of which is connected to the integrator (84, 86) and the other to the comparison voltage ( V _Rc .) . 6. Device according to one of claims 1 to 5, characterized by a stepping motor (42), on whose shaft a cam is seated in a certain angular position with respect to the starting position, by a first relay (106) with working contact pieces (114) which have a stepping motor forming a controlling switch which enables an activation when closed, the coil of the first relay being in the working circuit of a transistor (96), which is conductive, while an output signal from the comparator (8-3) is applied to its control electrode, through a second relay ( 134) with a first and a second switch (136, 140) which in the control circuit of a first control device (46, 50, 52) controlling the refilling of developing liquid and a second control device (48, 54, 56) controlling the refilling of fixing liquid ), as well as by a switching device which can be actuated by means of the cam disk and is arranged next to the shaft of the stepping motor (42), d ie is in the excitation circuit of the coil of the second relay (134) and is closed when the cam is rotated by a certain angle of rotation with respect to the start position. 7. Device according to claim 6, characterized in that the first relay (106) has a second switch (110) which is closed in the energized state of the relay and which is in a discharge circuit of the capacitor (8) of the integrating amplifier (84).