DE1926297A1 - Refill device for automatic film developing device - Google Patents

Description

'RING HERO

STUHGART-N, LANGE STRASSE 51

33/74 May 13, 2019 69

Registration number. 121 942

EASTMAN KODAK COMPANY, Rochester, New York State, United States of America

Refill device for automatic film developing devices

The present invention relates to a refill device for an automatic film processor.

In modern rapid development methods 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 films which the developing device passes through per unit of time, the photographic solutions are used up fairly quickly, so that replenishment is necessary at certain time intervals. Up to now, the filling was mostly done by the operator _for the aids such as test film strips and the like. ”“ However, one relied mainly on the operator's experience and knowledge of the daily occurrence of work. So whether this method is successful or not depends on the experience and attention of the person concerned.

^abo SQ 388 1/0936

BATH ORIGINAL

The invention is based on the object of creating an automatically operating wax filling device. These According to the invention, the object is through a refilling device with one that optically scans and modulates the fixed, continuously moving films in its Size of the degree of the permeability of the film dependent signals generating a these signals receiving integrator, whose output signals are dependent on the mean value of the input signals and the time Big have a comparator, which the output signals of the integrator with a fixed DC voltage compares and generates an output signal when the input signal reaches the magnitude of the comparison voltage or exceeds, a counter that generates a control signal when it has a predetermined number of the output signals of the comparator s counted, and a developer and fixer based on the control signals infeed loading device solved.

The device according to the invention enables a precisely controlled charging of the automatic film developing device with developer and fixing liquids ψ on the basis of empirical values of the consumption of these liquids as a function of the size and the

of the degree of blackening of the developed area and of the egg »» determined values. The unpredictability of the human Nature is thereby switched off · This ensures that always the right amount of developer and Fixing liquids refilled quickly and automatically which is necessary to the photographic solutions to always keep their high efficiency »"

Ira following is the invention aahand one on the drawing Ausfühniivrfs shown ^ .. isplels explained »

90988 * 1/09 ^ 3

BATH ORIGINAL

Show it:

Fig. 1 is a schematic representation of an automatic film developing device 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, which is partially shown as a block diagram.

The present invention is particularly suitable for use in automatic photographic film processing s device in which the exposed photographic film is fed into and into the developing device is developed, fixed, watered and dried one after the other. In Fig. 1, therefore, is such an automatic film development s device 10 is shown, which is provided with an automatically operating, electronic wax filling device is"

The developing device 10 is adjacent to a darkroom wall cover 12, with the designated 14 side of the wall cladding facing the darkroom, while Page 16 is exposed to normal lighting conditions. A film import point 18 is the only part that is in the darkroom protrudes? the rest of the developing device is arranged in a normally lit room as the remainder of the film developing device 10 placed in an opaque container 20

909881/0936

is closed. The introduced film F is conveyed by roller conveyors 22 through a developing tank 24, a fixing tank 26, and a washing tank 28 in sequence guided.

In preparation for drying, the film F runs through a Water scraper 30, which is at the entrance to a Filrate dry part 32 is arranged. The dry film part consists of a columnar arrangement in which the * Film is transported to the exit using rollers not identified by reference numbers. An air blower 34 leads thermostatically controlled, warm, filtered air through several tubes 36 to a uniform Ensure drying.

Upon exiting the film dry part 32, the film is through the automatic electronic refill control ■ device scanned according to the invention. The dried film first passes through part of the scanner forming light collection device 38. Here, the film is scanned by the light collection system around the surfaces determine which have been photographically processed so as to provide a value for the developer and To get fixing fluids a job well done. the light measurement values determined by the light collecting system passed on to an electronic circuit designated as a whole by 40. This circuit 40 then gives a signal when the developing and fixing liquids have performed a certain amount of chemical activity. The signal from the electronic Circuit 40 is then used to deliver a pulse to a stepper motor 42, which in individual steps can turn. When the stepper motor 42 has moved a past

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has turned the right angle, he actuates a microswitch 44; after pressing the i-likro switch 44 this activates timers 46 and 48 which control the supply of developer and fixer solution. The timer 46 controls a pump 50 which, through a flow meter 52, feeds fresh developer solution into the processing tank 24 lets flow. Accordingly, the timer 48 controls a pump 54, which is controlled by a flow meter 56 Supplementary solution in the fixing tank 26 supplies.

The light collection device 38 is shown in greater detail in FIG. It should be made clear here that the light collecting unit not at the exit of the film drying section 32 must be arranged. Within the scope of this invention, the light collection device 38 can be disposed there be where the film emerges from the washing tank 28. Once the film is set and developed Picture cannot change, it is quite possible the light collection device after the fixation tank at any suitable location.

The light collecting device 38 comprises a light source which is shown in *. AusfUhrungsbeispiel an incandescent lamp 58 is. Preferably, a single light source is used, so that bein Aging and blackening of the source of the film being scanned is affected to the same degree everywhere. If more than If a light source is used, the problem arises of coordinating the individual light sources with one another.

The light 60 of the lamp 58 is developed depending on the and undeveloped areas of the moving film F are modulated differently. This with just one

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BAD ORiGINAL

The light 60 shown in the single main ray is reflected by means of a 45 mirror 62 onto a lens system 64, which is symbolically represented here by a biconvex lens is shown. The light from the lens system 64 hits a barrier cell 68, which in the embodiment is a selenium cell. Light that by no As moving film is modulated, it is directed to a second junction cell 68, with the unmodulated light from lamp 58 passing through to cell 68 any suitable means, in the exemplary embodiment a light guide 70, is brought, which is also bent can be. The barrier cells 66 and 68 form part of the scanner, which in turn forms a part of the scanner Forms part of the circuit 40.

Cell 66 and 68 are shown here as junction cells; however, it goes without saying that aHe "photoelectric converters can be used, i.e., that the transducers by means of barrier layer effect, photoconductivity or photoemission can work.

The electronic circuit 40 is illustrated in greater detail in FIG. The cathodes of the junction cells 68 and 68 are connected to the ends of a potentiometer 72, the center of which labgriff 74 is connected to ground. The anodes of the junction cells 66 and 68 are connected to the two inputs of a differential amplifier 76, which is a functional amplifier belonging to the prior art. A variable resistor 78 is provided in the feedback path of differential amplifier 76 from the output terminal to the anode of junction cell 66 «A monitoring voltmeter 8C

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is on the one hand to the output of the differential amplifier 76, on the other hand connected to ground. The exit of the differential amplifier 76 is through a resistor 82 connected to the input of an integrator, which acts as an amplifier 84 with a capacitor 86 in the feedback path is trained.

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 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 the amplifier 88 is with the Base of a PNP transistor 96 through a resistor 98 tied together. Two series connected diodes IQO, 102 lie between the emitter of transistor 9 6 and ground. The cathode of diode 102 is connected to ground and the anode of diode 100 is connected to the emitter of the transistor 9 6 · The emitter is also connected to a voltage of +24 V via a resistor 104. ,.

Furthermore, a relay 106 is provided, the coil of which is in series with the _:; .Collector of transistor 9 6 and is connected in parallel to eine.Dipde 108, the drawn Pola_r _t i £ ät being preserved. The relay 106 has immovable contact pieces .110 _f 112 and 114, 116. The movable contact pieces of the relay JL06 rest against the contact pieces 112 and 116 when the relay is de-energized, as shown in FIG. The contact piece 110 and the tensile

909881/0936 '' ead _0RIGI naL ■

arranged movable contact piece form a switch that shorts the capacitor 86 in the closed state closes. 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 is part of the State of the art; it consists of a permanent magnet motor and a wound stator. The rotor shaft rotates gradually according to the energy with which the stator windings 118 and 120 are applied. the Power is provided by a DC power source such as a battery 122. In the unexcited state of the Relay 106 is the circuit of winding 118, and when energized, the circuit of winding 120 is closed.

The microswitch 44 has a movable contact piece 124, which is connected to a voltage source of +24 V via a resistor 126. The contact piece . 124 is designed so that it is between the contact pieces 130 and 132 can be moved. When it rests on the contact piece 132, the microswitch 44 effects the connection a capacitor 128 to the winding of a relay 134, with the other side of the relay winding and the Capacitor 128 is connected to rfasse. The relay has contacts 136, 138 and 140 and 142. The movable ones Contact pieces of the relay 134 are applied to the contact pieces 138 and 142 when the latter is de-energized.

As shown in Fig. 3, the contacts 136 and 138 are the timer 48, the pump 54, and the flow meter assigned, while the contact pieces 140 and 142 the The timer 46, the pump 50 and the flow meter 52 are assigned are.' 90 9 881/0936

Before using the developing device, it is first necessary to calibrate the device accurately. this happens by closing a switch S (Fig.3) and by passing through either a perfectly clear filmstrip or a filmstrip with a chosen one find blackening by the light gathering device 38. The Center tap of potentiometer 72 is then adjusted so that voltmeter 80 is Hull or a minimum voltage indicates. Next, a strip of film is passed through the light saiiune in the direction of either has a selected maximum density or completely black, i.e. 100% developed. The gain of the amplifier 76 is determined by means of the variable resistor 78 is set so that a maximum voltage is obtained on the voltmeter 80. The purpose of this setting is it, an essentially linear output variable between zero and 100% development or between the minimum optical density D. and the maximum optical density D of the photographic film. The refill device is then linearly calibrated and the voltmeter is now switched off by means of switch S.

During normal operation, when the film is through the light-gathering element direction, cells 66 and 68 develop the highest voltage when passing through a clear film or no movie at all. That is the norm of cell 68. The cell 66 then touches the photographically fixed Film off, and the modulated light from which it is applied depends on the changed permeability of the fixed film, which results in a variable signal voltage evokes.

909881/0936 BATHROOM o _RIGINAL

The output of differential amplifier 76 is

^e o ^{= K (e} 2

whereby

e is the output variable of the differential amplifier,

K the gain as' by setting the

^ Resistance 78 has been established

e, the voltage developed by cell 68,

e ~ the voltage developed by cell 66.

The output e of the differential amplifier 76 is applied to the amplifier 84 and as a result thereof becomes the Capacitor 86 charged.

Under typical operating conditions, the comparator reference voltage V £ is set to almost exactly -4 volts. When switched off, the output of the amplifier 88 supplies approximately 3.2 V to ground, whereby the base of the transistor has a potential of +3.2 V to ground. As a result of the current from the +24 V source through resistor 104 and through the series-connected diodes 100, 102, the emitter is at a potential of approximately +1 V with respect to ground. The device is then in the switched-off state emitter against .lasse the voltage of 1 V is fixed by this bias at the emitter-base path of the transistor 96 of this non-conductive. When the sampled film passes through the light collection device 38, the capacitor is charged 86th If the amplifier 88 vosi amplifier 84 applied voltage -4 V or more, then the comparator outputs a

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- li -

Output voltage, with the output voltage of amplifier 88 at approximately -0.5 V from ground falls off. Since the emitter-base path of the transistor 9 6 is now operated in the forward direction, this is conductive. The base ko.u-nt to +0.7 V or very close at +1 V to ground. As a result of the conductivity of the transistor 9 6, a collector current flows through the coil of relay 106, and the coil is energized for a moment, so that the contacts 110 and 114 close.

The stepper motor 42 could be a flip-flop circuit can be controlled, but is included in the exemplary embodiment constant current through winding 118 and a pulse is delivered to the other winding 120 when the relay 106 is excited. It should be noted that the contacting of the contact piece 114 with the coil 120 of the stepper motor 42 energized, causing the motor 42 to rotate by one step, for example by an angle of 15. When contacting of the relay contact piece 110, the capacitor 86 is short-circuited. The diode 108 helps to keep the current flowing by the coil of relay 106 to be maintained.

The discharge of capacitor 86 causes the circuit to return to its original state and transistor 9 becomes 6 switched off again, the movable contact pieces of the relay 106 return to their rest position and come with them contacts 112 and 116 in contact. The process repeats itself and is cumulative when the film is continuously passed through by the light collection device 38. The charge on the capacitor 86 increases slower or faster, depending according to the state of the immediately scanned film, whereby the transistor 9 6 depending on the earlier in the sequence

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or later becomes conductive to actuate relay 106. Each actuation of the relay 106 causes switching of the stepping motor 42 by a certain angle or one step. The shaft of the stepping motor 42 has a cam wheel which is arranged so that a slot the movable contact piece 124 of the microswitch in the cam wheel 44 operated after the rotor shaft has rotated a predetermined angle.

W The capacitor 128 v / ith via the resistor 126 through the connection to the +24 volt source charged when the contact piece 124 contacts the contact piece 130th When the slot of the cam wheel of the stepper motor 42 reaches the movable contact piece of the microswitch 44, it is displaced and makes contact with the contact piece 132. The charged capacitor 128 now discharges itself through the coil of the relay 134. The rapid discharge of the capacitor 128 through the coil of the relay 134 causes excitation and contacting of the contact pieces 136 and 140. As a result, the timers 46 and 48 are excited, the Developer solution timer 46 and

fc the timer 48 is designated for the fixing solution. the Timers 46 and 48 are standard timers in the prior art and can vary between one and sixty seconds or more. Each timer operates its associated pump for the desired one Duration. The flow meters 52 and 56 are set to have a predetermined number of milliliters per minute let through so that the Pampen then the correct amount of developer and fixer solution not shown Pump sources into the respective tanks 24 and 26 and make a supplement based on the empirical determined values takes place.

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Claims (8)

Patent claims: 1. Refill device for an automatic film processor, characterized by a fixed, continuously moving film (F) optically scanning and modulated, their size depending on the degree of transparency of the film Sampling device (38,66,68,72, 76,78) generating signals, an integrator receiving these signals (84,86), whose output signals are dependent on the mean value of the input signals and the time have a comparator (88) which the output signals of the integrator (84,86) with a fixed Compares DC voltage and generates an output signal when the input signal is the size of the Comparison voltage reaches or exceeds a counter (42,106) which generates a control signal, when it has counted a predetermined number of the output signals of the comparator (88), and a developer and charging means (46 to 56) supplying fixing liquids in response to the control signals. 2. Device according to claim 1? characterized, that the scanning device has a light source (58) which is arranged on one side of the film (F) and which receives light throws the film, as well as two photoelectric converters (66, 68), one of which is arranged in the beam path (60) of the light source on the other side of the film (F) and the other is exposed to light from the light source (58) that is not modulated by the fixed film. ORJG / NAL 909881/0938 as well as a differential amplifier (76) whose two inputs connect to the output of one or the other photoelectric converter (66 or 68) are connected and its output signals an i-Iass for the degree of permeability of the straight scanned film section are. 3. Device according to claim 2, characterized in that the two photoelectric converters each as • Photo cells (66,68) are formed, the cathodes of which are connected to one or the other end of a potentiometer (72) are connected to a variable tap (74), the position of the tap (74) being the minimum optical density of the film (F) determines which the device is still processing. 4. Device according to claim 2 or 3, characterized in that the differential amplifier (76) has a feedback with a variable resistor (78) W is seated, the setting of which has the maximum optical density of the film (F) specifies which the device is still processing. 5. Device according to one of claims 1 to 4, characterized in that the integrator as an integrating amplifier (84) is formed with a capacitor (86) ixn feedback circuit and one the capacitor (36) discharge device (106, 110) discharging when each output signal of the comparator occurs, is provided. 909881/0936 6. Device according to one of claims 1 to 5, characterized characterized ^ that the comparator as a differential amplifier rait high gain and a single Output and two inputs is formed, one of which with the integrator (84, 86), the other is connected to the comparison voltage (V_ ^) » 7. Device according to one of claims 1 to 6, characterized by a stepper motor (42) on whose shaft in a certain angular position with respect to the Starting position a cam sits, a first relay (106) with normally open contact pieces (114), the form a switch that controls the stepping motor and enables excitation when closed, wherein the coil of the first relay is in the working circuit of a transistor (9 6), which is conductive while an output signal of the comparator (88) is applied to its control electrode, a second one Relay (134) with a first and a second switch (136,140) in the control circuit of a first, the Control device controlling replenishment of developing liquid kait (46,50,52) or a second control device controlling the refilling of fixing liquid (48,54,56) lie, as well as one which can be actuated by means of the cam disk, next to the shaft of the stepper motor (42) arranged switching device, which is in the excitation circuit of the coil of the second relay (134) and is closed is when the cam is rotated by a certain angle of rotation compared to the start position. ^909881/0936 8. Device according to claim 7, characterized in that that the first relay (106) has a second switch (110) which is closed when the relay is energized, which is in a discharge circuit of the capacitor (86) of the integrating amplifier (84). 909881/0936 AD