DE1173329B - Automatic exposure device for enlarging devices - Google Patents

Description

Automatic exposure device for enlargers The invention relates to an exposure machine working according to the reflection method.

In the case of devices that have become known working according to this method, falls the light reflected from the positive image area during the exposure time a suitable photo element, e.g. B. a secondary electron multiplier whose Measurement current is used for time-dependent charging of a capacitor. After reaching a certain charge voltage is determined by appropriate electrical and electronic Means triggered the shutdown of the light source of the enlarger.

The aim of the invention is the technical effort and the dimensions an automatic exposure machine working according to this process to reduce significantly as well as to make the device universally applicable.

The subject of an older patent is a reflection method working photoelectric light meter with one only in the exposure breaks additionally constantly irradiated photoresistor as a photoelectric indicator and with a second photoresistor as a circuit element, which is also of a Light source is illuminated with constant strength over time. It is assumed that to use the higher light sensitivity of a photoresistor without it To let disadvantages appear. However, this is there by a constant Irradiation of the photoresistor achieved both before and during exposure. That is, the illuminance of the light source required for exposure is adjusted manually from case to case before the actual exposure so that The same illuminance always occurs at the photoresistor, regardless of whether it is is irradiated from the pre-exposure light source or from the measurement object. For the way of working This measuring method is unsuitable for an automatic exposure device for enlargers.

As a photoelectric indicator has become known among the Process of secondary electron multiplier enforced. It is the most sensitive to light and the most expensive of the known photo elements and requires a considerable technical Effort for the power supply. The power supply must be stabilized if the required Measurement accuracy is to be achieved. In addition, secondary electron multipliers are strongly dependent on temperature and subject to wear and tear. A11 this has the consequence that automatic exposure machines equipped with secondary electron multipliers are unwieldy, are sensitive and expensive. But it is also known as a photoresistor as an indicator to use. Basically, photoresistors have the opposite of other photo elements a number of advantages: In the case of very high light sensitivity, only those from the secondary electron multiplier is exceeded if they have an exposure latitude not achieved by other photo elements, are small, light and cheap, are not subject to wear and tear and are robust Components.

It is well known that the photoresistors have a relative disadvantage as a disadvantage they have great indolence, and they have a kind of memory. Was a photoresistor z. B. exposed to the dark for a long time, then he reacts extremely slowly a very weak radiation. It can. Take hours for a photoresistor assumes its final resistance value under these operating conditions, whereas a photoresistor that immediately precedes a relatively large illuminance responded much faster to a sudden change in radiation exposure.

From this behavior of the photoresistors it follows that it is through a Pre-exposure is only possible in the pauses in exposure, the inertia reduce the photoresistors significantly. Assuming a pre-exposure, which is so strong that the photoresistor hits one of these in no time Pre-exposure sets the associated resistance value, then the photoresistor has the property of always reacting in the same way after switching off the pre-exposure and in the case of e.g. B. very close to complete darkness after a few seconds to assume its final resistance value, which corresponds to its dark value. When there is any illuminance after switching off the pre-exposure the pre-exposed photoresistor sets up much faster the associated resistance world than would be the case without a pre-exposure.

The purpose of the pre-exposure is therefore to reduce the inertia a portable and reproducible measure. Despite the pre-exposure just described of the indicator, which is the subject of an earlier patent, could not be Sufficient proportionality between the illuminance and the exposure automat produce switched exposure time. Because the photoresistor despite the pre-exposure its resistance value cannot change abruptly when the lighting changes At the beginning of the exposure the capacitor received a fault current, which the measurement result would affect differently with different long exposure times.

According to the invention, this fault current is avoided in that with a second photoresistor, also preexposed only in the exposure breaks a capacitor is shunted. Through the second photoresistor At the beginning of the exposure, a compensation current flows that: in its size and its course corresponds to the above-mentioned fault current and with the help of the pre-exposure can be influenced.

In the drawing, the invention is illustrated by means of exemplary embodiments explained. It shows F i g. 1 shows an enlarger with an indicator, FIG. 2 an operating and control device combined to form a unit, FIG. 3 one operating and a control device which are spatially separated and connected by cables, FIG. 4 a circuit diagram of the operating and control device. The exposure time determination will be the effective negative image sizes 1 (see Fig. 1) are used as a basis. Also own the surfaces of the copying frame 3 facing the measuring probe 2 with its format diaphragms 4 and the base plate of the enlarger 5 have similar reflective properties like the paper to be exposed. In addition, the measuring probe containing the indicator 6 is 2 mechanically connected to the movable projector part 7.

Through these arrangements it is achieved that the measuring probe alone the provides correct values for determining the exposure time, so that when the Magnification scale and / or the positive image size 8 in contrast to known Process no additional correction or adjustment means on the copy frame or on the Magnifying device are necessary.

With the help of the basic photometric law and the lens equations it can be demonstrated that the required conditions are met if the The measuring probe is mechanically connected to the magnifying optics and the light-sensitive Area of the indicator by the amount of the focal length 9 of the magnifying optics used in each case removed from their main plane l0 according to FIG. 1 is mounted. At this level 11 all theoretical prerequisites are given, according to which changes in the Convert the magnification scale or lens change into correct measured values, if The measurement is based on the projected negative image size 1.

According to FIG. 1 the light arrives by diffuse reflection from the positive image area for indicator 6.

Photoresistor 13 is housed together with light source 14 in a light-tight housing. The shunt to the capacitor 18 is therefore canceled because the photoresistor 13 very quickly approaches its dark value (well over 100 megohms) after the light source 14 has been switched off.

The indicator 6 and the photoresistor 13 form with resistor 17 and condensate 18 an RC network, which in connection with the described Pre-exposure the effect of the inherent inertia of the photoresistors on the Measurement result almost eliminated. In addition, it is still possible with the help of the pre-exposure metering the proportionality between the effective illuminance and the exposure time to influence so that the Schwarzschild effect is compensated.

During the exposure process, indicator 6 influences the RC network already explained in such a way that an exposure-dependent voltage change occurs at point 19 of the network. The required voltage curve can be adjusted with the aid of the setting means 15 and 16. These setting means influence the pre-exposure of the two photoresistors and thus also indirectly the voltage curve at point 19. If the setting means 15 and 16 are correctly set, the voltage at point 19 during an exposure process runs as if a certain ohmic resistor alone would charge the capacitor 18.

In the exemplary embodiment, an alternating voltage is superimposed on the rising direct voltage at point 19 via resistor 21, which, in contrast to known methods that work with thyratrones, causes a cathode-coupled monostable multivibrator, which is known per se, to increase with a very slow direct voltage rise at point 19 (Fig. 4 ) exactly triggers the shutdown process. If the direct voltage at point 19 has risen so far that the positive peaks of the superimposed alternating voltage cause a change in the anode current at tube 22, the multivibrator tilts into its unstable position in a manner known per se, ie, tube 25 is de-energized.

The multivibrator is connected in such a way that a relay A is located in the anode circuit of the tube 25, and the normally open contact a4 of the relay A is located in the same circuit. This circuit has the effect that the necessary switching operations, such as switching on the magnifying lamp, switching off the darkroom lighting and discharging the capacitor 18, are carried out with the aid of the relay A. The normally open contact a 4, which acts as a self-holding contact for the relay A, ensures that the circuit of the tube 25 remains open even when the multivibrator has returned to its stable position. Experiments with this circuit have shown that significantly longer switching times can be achieved with it than with thyratrones or cold cathode tubes. The reason is that the latter cannot be switched to a powerless state and that the photocurrents become vanishingly small at extremely low illuminance levels.

The tuning and switching means 23, 24, 26 still provided are used the calibration of the device or the change in the exposure time. In the exemplary embodiment also takes place the switching of the capacitor 18 by means of switch 27 for the purpose Adjustment of the automatic exposure system to the different types of paper or for individual change of the exposure time. The automatic exposure consists of the measuring probe 2 and the operating and control device 28, which are connected to each other are connected by cables to form a functional unit. This construction has in the In contrast to known methods the advantage that each module is practical Can be optimally adapted according to requirements.

According to the invention, two embodiments are therefore proposed, according to FIG. 2 and 3 that once the operating and control device 28 forms a unit and that in the second case the control unit 28 a is spatially separated from the control unit 28 b and both are connected to each other by cables.

In the latter embodiment, several control units, z. B. according to FIG. 3 can be connected with the associated measuring probes. To this Way it is possible to use several enlargers in a particularly efficient and space-saving way Type to automate at the same time and in the mode of operation independently of each other.

Automatic release pushbuttons 29 are provided for the control panel, Switch 31 and the exposure time selector switch 27.

In the following functional description of the exemplary embodiment according to FIG. 4 it is assumed that relays A and B are de-energized. This state occurs after the device is connected to the power supply or after the exposure process has ended. The following conditions prevail: the indicator 6 is exposed to light by the light source 12, as is the photoresistor 13 by the light source 14. The light sources 12 and 14 receive voltage via the controllable resistors 15 and 16 together via relay contact a 1. The measuring network, containing indicator 6, photoresistor 13, resistor 17 and capacitor 18, is de-energized as a result of the opened relay contact a2. Capacitor 18 is short-circuited via resistor 33 by contact a 3 and is therefore without charge. The darkroom lighting 34 is switched on via the relay contact b 1. A switch 31 is provided to enable the image to be adjusted. With its actuation, the exposure lamp 32 can be switched on and off without the state of the automatic undergoing any change.

The start of exposure is initiated by briefly closing the automatic release contact 29. Contact 29 closes the circuit, consisting of relay A, tube 25, resistor 23 or 24 and switch 26. After relay A has picked up, the automatic release contact 29 is bridged by its contact a4. B-relay is activated via relay contact a5. The darkroom lighting 34 is switched off via contact b 1 and the exposure lamp 32 is switched on via contact b 2.

The exposure of the indicator 6 and the photoresistor 13 through the light sources 12 and 14 is interrupted by opening the relay contact a 1. The measuring network receives voltage via relay contact a2, and the shunt from capacitor 18 via resistor 33 and photoresistor 13 is opened by opening relay contact a3 or canceled as a result of the extinction of the light source 14.

At point 19 of the measuring network, the voltage rises until a peak of the alternating voltage superimposed on this rising direct voltage, which is fed to the network via resistor 21, at the anode of tube 22 generates a negative impulse and thus, in a known way, the stable state of the multivibrator ended. Tube 25 is de-energized and ikelais A drops out. In order to the initial state of the description is reached. In the embodiment according to F i g. 2 are changed to F i g. 4 the darkroom lighting 32 and the Exposure lamp 34 switched directly from relay A, with contact a5 in the circuit the exposure lamp 34 and contact a 6 in the circuit of the darkroom lighting 32 is switched. The power supply is in this embodiment in the operating and Control unit according to FIG. 2 included.

Claims (1)

Claims: 1. Automatic exposure system working according to the reflection process for enlargement devices with a photoresistor, which is also constantly irradiated only in the exposure breaks, as a photoelectric indicator, which is mechanically connected to the enlarging optics and electrically via cables to the control and operating device, with the exposure time determining the total projected negative size is based, and with a second photoresistor, which is illuminated by a light source with a constant intensity over time, characterized in that the second photoresistor (13) is also only exposed in the exposure pauses and is arranged in such a way that a shunt to a capacitor ( 18), to which the light value-dependent resulting measurement current of the indicator (6) is supplied, is produced. z. Automatic exposure machine according to Claim 1, characterized in that the illuminance levels occurring at the two photoresistors during the pauses in exposure can be regulated independently of one another by electrical setting means (15 and 16) and by mechanical setting means (diaphragms; distance: light source-photoresistor). 3. Automatic exposure machine according to claim 1, characterized in that the light value-dependent resulting measuring current fed to the capacitor (18) can be regulated by setting means (17). 4. Automatic exposure machine according to claim 1, characterized in that the charging voltage generated on the capacitor (18) by the measuring current is superimposed by a pulse or alternating voltage which is fed to the tilting arrangement via switching means (20 and 21) and capacitor (18). 5. Automatic exposure machine according to claim 1, characterized in that the capacitor (18) can be changed in steps for setting the individual exposure time. 6. Automatic exposure machine according to claim 1, characterized in that the light-sensitive surface of the indicator (6) is arranged by the amount of the focal length of the respective magnifying optics used from its main plane in the direction of the image plane. 7. Automatic exposure device according to all of the preceding claims with a tilting arrangement connected downstream of the capacitor (18), characterized in that a relay (A) with a self-holding contact is arranged in the circuit of a high vacuum tube (25). B. Automatic exposure machine according to all of the preceding claims, characterized in that a relay contact (a3) is arranged as a normally closed contact in parallel with the capacitor (18). 9. Automatic exposure system according to all of the preceding claims, characterized in that a relay contact (a1) is arranged as a normally closed contact in series with the lamps (12 and 14). 10. Automatic exposure device according to all of the preceding claims, characterized in that the components belonging to the overall circuit with the exception of the indicator (6) and its exposure lamp (12) are combined in a control unit (28) and the latter is connected by cable to the measuring probe. 11. Automatic exposure machine according to all of the preceding claims, characterized in that the control unit (28a) is spatially separated from the control unit (28b), electrically connected by means of cables, and in that any number of independent control units are provided for a control unit. References considered: Eleetronics, January 1.949, pp. 101-103 ; U.S. Patent No. 2,484,299. Prior Patents Considered: German Patent No. 1145 908.