DE1522150C3 - Exposure control device for photographic enlargers - Google Patents

Description

The present invention relates to an exposure control device for photographic enlargers, in particular photo typesetting devices. With the latter, negatives, which contain letters and numbers, are on Photo paper or film enlarged or reduced in size and thus set texts in a familiar way.

With the known photo typesetting devices, the exposure times must be for the different letter sizes taken from tables or estimated and then set by hand on a time control device will. The exposure takes place in the end through a red filter diaphragm, which is made by an electromagnet the beam path is drawn.

The very high dependency of the luminous intensity of the projection lamp and the color temperature of the light from the supply voltage (mains voltage) is not taken into account and easily leads to incorrect exposures. The calculated surcharges for the minimum exposure times lead to a reduced working speed and may result in overexposure.

The aim is to keep the effect of light on the photographic layer as constant as possible in order to on the one hand with the shortest possible exposure time (high working speed) sufficient blackening and on the other hand not to reduce the sharpness of the images produced by overexposure.

The amount of light falling on the unit area of the photographic layer is controlled by the opening and closing a shutter placed in the beam path of the projector. The projector lamp is only used for the Exposure time fully switched on; in the breaks it is de-energized or burns with reduced voltage, in order to enable relatively short adjustment operations by means of a red-permeable aperture To better utilize the lamp life and to reduce the electrical work consumption of the device.

ίο If the aperture is constant, the photographic Effect of the light from the projector lamp depending on the magnification of the facility, on the light intensity of the lamp, the imaging optics used and the sensitivity of the used photographic material.

The magnification changes with the projection distance, the light intensity and the intensity of the Lamp light change mainly with the supply voltage of the lamp; likewise have age and manufacturing tolerances the lamp has an influence on this.

A control or regulation of the lamp light intensity is with considerable effort in power electronics connected, such as phase angle controls with thyristors or magnetic amplifier devices. Even the Compensating for mains voltage fluctuations is expensive and difficult with the current state of the art and voluminous magnetic voltage stabilizer, is now the exposure time of the photo setting device influenced by control as a function of the projection distance, there is a relationship between Letter size and exposure time in the form of a quadratic function.

In the practical implementation of a corresponding control device also interferes with the fact that the lamp has a takes a certain amount of time to reach its full light intensity after switching on, because the filament of the Lamp has to be heated up first. Especially with short exposure times of tenths of a second a deviation from the parabolic course becomes noticeable: the exposure must be longer here.

In addition, the percentage error of the exposure time in this area must not be as large as in strictly parabolic course of the relationship, since the main part of the photochemical reaction is in the light-sensitive layer towards the end of the exposure time, when the lamp has reached its full light intensity has, plays and thus small changes in the exposure time have a relatively large impact on the degree of blackening of the photographic material.

The invention is based on the object of an exposure control device to create in which the influence of the supply voltage on the lamp brightness is compensated and that allows the exposure time to be set according to the magnification.

This object is achieved by the means characterized in claim 1.

An exemplary embodiment of the invention is explained below with reference to a drawing:

The illustration shows the circuit diagram of the control unit. Between A and Z? the supply voltage is applied (in the example equal to the lamp supply voltage; it is a low-voltage lamp), between C and B the reduced lamp voltage for modeling light.

State of the circuit after applying the operating voltage: transistors 72, 73 and 74 are blocked. Relay ReIi has dropped out, Re / 2 is picked up. lamp

Lp burns with reduced voltage. The current flowing through transistor 71 (current generator) is controlled as follows: Di is a Zener diode across which a constant voltage drop occurs. There is therefore a voltage across the resistors Ri and R2 which corresponds to the supply voltage AB minus the voltage across the Zener diode Di. Since there is a voltage across Ri and R2 that is smaller than the voltage AB, but the fluctuations are transferred to Ri and R2 unimpaired, the percentage fluctuation of the voltage across Ä1 and R2 is greater than that of the supply voltage AB. The fluctuation in the voltage across Ri and R2 can now be made so large by suitable dimensioning of Ri, Rl and Di that it corresponds to the fluctuation in the photographic effectiveness of the lamp light, which is also greater than that of the supply voltage AB.

At R3 , the emitter current of transistor 71 produces a voltage drop which is so great that the sum of this voltage drop and the emitter-base voltage of 71, which is necessary to generate the emitter current in question, is the voltage between A and the tap of R2 is equivalent to. With suitable dimensioning, the emitter current can now be set equal to the collector current of Tl and the base-emitter voltage of Ti can be neglected compared to the voltage on Ri. Then the collector current of 71 depends on the voltage at R2 and the set value of R3 . In the present circuit, R3 is adjusted by the projection apparatus at magnification distances by changing the projection distance according to a parabolic function; R2 is used to compensate for lamp tolerances and the like.

If the switch S is pressed, the charging current of the capacitor Cl discharged in the switching pauses via R8 flows via ReIi and Rl to 73. 73 becomes conductive, the bistable flip-flop 73 to R6, 74 to R7 switches to the conductive state, relay ReIi picks up via 74th contact ib switches the lamp to full voltage

voltage, contact la opens, so that Reh drops off after a few tenths of a second after capacitor Q has discharged via Rel2 , now contact 2b closes, magnet M attracts and opens the red filter screen. Contact 2a, which is also open, cancels the short circuit of Ci so that the collector current of Ti begins to charge the capacitor Ci.

When the voltage at Cl has reached the level of the switching voltage of the unijunction transistor 72 after the time determined by the capacitor capacitance and charging current, 72 becomes conductive and Ci is discharged via R4. The resulting pulse at /? 4 blocks 73, the flip-flops 73 and 74 tilts back into the blocked state, ReIi drops, contact ib switches the lamp to reduced voltage, la lets Rel2 attract, 2b switches off the diaphragm magnet M and relay contact 2a shorts Ci . The initial state of the circuit is thus restored.

A stepwise changeability of Cl can be used to adapt the device to different optics will.

1 sheet of drawings

Claims (4)

Patent claims: 1. exposure control device for photographic magnifying devices, in particular phototypesetters devices in which the exposure is controlled electronically by an RC element and an electromagnetically controlled red filter, characterized in that parallel to the lamp (Lp) a of a Zener diode (Dl) and resistors (Ri, R2) existing voltage divider is provided, which controls a transistor (Tl), which is in series with the RC-G \\ ed {R3, Ci) , whereby Dl, Ri and R2 are dimensioned so that the collector current of 71 the changes in brightness the lamp (Lp) compensated by changing the resulting exposure time, and that a potentiometer (A3) is provided in the emitter circuit of the transistor (71), which is used to set the magnification. 2. Apparatus according to claim 1, characterized in that a capacitor of variable capacitance (Cl) or a variable resistance is provided, which allows the exposure times to be increased with freely selectable factors or to decrease. 3. Apparatus according to claim 1 and 2, characterized in that means (C3, R9) are provided in the circuit arrangement, which delay the opening of the red filter diaphragm relative to the switching on of the projector lamp (Lp). 4. Apparatus according to claim 1, 2 and 3, characterized in that for triggering the diaphragm control a unijunction transistor is used.