DE1046497B - Timing device for photographic copiers - Google Patents

Description

The present invention relates to a time switch device for photographic copiers with a grid-controlled tube, one of its state of charge changing time circuit con- 'connected to the tube capacitor and a device influencing the switching time sequence for taking into account the Schwarzschild exponent of the photosensitive material to be used.

It is known that the exposure of photosensitive material according to the relationship

Jt " = const

take place, where / means the intensity of the light hitting the photosensitive material, ί the ^; Exposure time and p is the Schwarzschild exponent of the photosensitive material. In the previously known time switching devices for copiers, the Schwarzschild exponent was usually taken into account in such a way that the sensitivity of the photocell arranged in the path of the copying light was changed either optically or electrically during the switching time sequence. Furthermore, it has already been proposed to influence the charging circuit of the time circuit capacitor in order to take into account the Schwarzschild exponent.

However, with the above-mentioned devices, the present object could not be satisfactorily achieved be solved, at least not without a major investment in resources.

According to the invention, it is therefore proposed, in the case of time switching devices of the initially mentioned, Type the Schwarzschild exponent of the photosensitive material exclusively by changing the To take into account the potential of an electrode of the tube of the time switch device during the switching time sequence, preferably by changing the cathode potential when the potential of the grid is the Tube is influenced by the timing capacitor.

In one embodiment of the invention, a voltage divider with a potentiometer and a voltage divider are used for this purpose Drive device, soaked through with the cathode the tap of the potentiometer connected to the tube is adjusted during the switching time sequence. Preferably an electric motor that can be switched on by the main switch of the device is provided for this purpose, to which the tap of the potentiometer by means of a magnetic coupling and the relay of the timer switched on for the duration of the lapse of the season.

In a further embodiment of the invention, the cathode of the tube is connected to a capacitor which changes its state of charge during the switching time sequence and which is operated by the relay of the time switching device for the duration of the switching time sequence
for photographic copiers

Applicant:

Agfa Aktiengesellschaft,

Leverkusen-Bayerwerk,

Kaiser-Wilhelm-Allee

Dr. Richard Wick, Munich,
has been named as the inventor

can be switched into a charging circuit. With a preferred Embodiment of the invention means are provided by which the voltage in the charging circuit of the last-mentioned capacitor lying voltage source is changed during the switching time sequence.

According to the invention, the means influencing the cathode potential are adjustable in the circuit Resistors arranged through which the extent of influencing the cathode potential according to the measure the size of the Schwarzschild exponent of the light-sensitive one being used Material is adjustable.

The object of the invention enables the present object to be achieved in a very satisfactory manner Way with a relatively small expenditure of resources.

Some embodiments of the invention are shown in the drawings, namely FIG

1 shows the circuit diagram of a first embodiment with a device driven by a motor to change the cathode potential of the electron tube,

2 shows the circuit diagram of a second embodiment with a cathode potential of the electron tube influencing capacitor,

FIG. 3 shows a third embodiment which represents a further refinement of the object of FIG. 2.

In the figures, 1 denotes the copy lamp of a photographic copier, not shown. It is connected to a conventional alternating current network 4, 5 via the lines 2, 3.

To automatically switch off the copy lamp 1 after the optimum exposure time has elapsed, a photoelectric density control device is provided. It comprises a circuit 6 and a time

809 698/145

circle 7, which is connected to the secondary coils 8, 9 of a primary side on the network 4, 5 lying transformer 10 are connected, with the interposition each a rectifier arrangement 11, 15, which in a known manner capacitors 12, 13 or 16, 17 and Resistors 14, 18 are assigned to smooth the rectified current.

Between the conductor 19 carrying negative voltage and the conductor 20 carrying positive voltage of the circuit 6, the thyratron 21, the relay 22 and the trigger switch 23 are arranged in series. The relay 22 actuates, among other things, the switch 22a in the circuit of the copy lamp 1.

In the time circuit 7, the photocell 26 and the capacitor 27 are connected in series between the conductor 24 carrying negative voltage and the conductor 25 carrying positive voltage. The photocell 26, which can also be designed as an electron multiplier, is arranged on the copier (not shown) in such a way that it is struck by light beams from the copier lamp 1 during the exposure of the copier material. The charging capacitor 27 is connected to the grid 29 of the thyratron 21 via the conductor 28. The switch 22 b actuated by the relay 22 is connected in parallel with the capacitor 27.

In the embodiment shown in Fig. 1 of In accordance with the invention, a voltage divider is located between the conductors 24, 25 parallel to the photocell 26 and the capacitor 27, that of the controllable resistors 30, 32 and the potentiometer arranged between them 34 exists. The sliders 31, 33 of the resistors 30, 32 are mechanically coupled to one another. Of the Tap 35 of the potentiometer 34 is via the partially flexible conductor 36 with the cathode 37 of the thyratron 21 conductively connected and arranged on a shaft 38, which are coupled to the shaft 41 of an electric motor 42 by the magnetic coupling 39, 40 can. The motor shaft 41 rotates smoothly counterclockwise. The wave 38 is under the action of a spiral spring 43, which strives to tap the shaft 38 and thus the potentiometer 35 to turn clockwise.

The transformer is used to connect the motor 42 and the magnetic coupling 39, 40 to the power source 44, which is connected to the network 4, 5 on the primary side. The motor 42 is connected to a secondary winding via the lines 45, 46 47 of the transformer 44 connected, while the electromagnet, not shown, of the magnetic Coupling 39, 40, which is arranged on the clutch disc 40, via the conductors 48, 49 and the switch 22 c actuated by the relay 22 with a further secondary winding 50 of the transformer 44 connected is. Two arranged on a sleeve 51 of the clutch disc 40 are used for power transmission Slip rings 52, 53, on which sliding contacts 54, 55 of the conductors 48, 49 rest resiliently.

The mode of operation of the device shown in FIG. 1 in the standby state is as follows: When the main switch 56 is open, the entire device is de-energized, the switches 22a, 22c are closed, the switch 22b is open. The tap 35 of the potentiometer 34 is under the action of the spring 43 at the end of the potentiometer resistor 34 facing the resistor 30. When the main switch 56 is closed, the tube 21 immediately ignites because its grid 29 is initially positive towards the cathode 37. In this way, the relay 22 is energized, so that the switches 22a, 22 b, 22 c in the position shown in Fig. 1 position to be transferred. In the process, the grid 29 of the tube 21 becomes negative with respect to the cathode 37, but this does not interrupt the passage of current through the tube 21. The cathode 37 of the tube 21 is at the potential of the contact point 57 between the resistor 30 and the potentiometer 34. Furthermore, when the main switch 56 is closed, the motor 42 is switched on, but the coupling 39, 40 remains ineffective.

If an exposure process is now to take place, the release switch 23 is opened by the contact element 58 the contact element 59 folded over. By briefly opening the switch 23, the tube 21 goes out, the relay 22 is de-energized, and the switches 22a, 22c are closed, the switch 22δ is opened. As a result, on the one hand the copy lamp 1 is switched on, while on the other hand the magnetic coupling 39, 40 becomes effective, so that the shaft 38 and with it the potentiometer tap 35 by the motor 42 can be rotated against the action of the spring 43 and counterclockwise. Of the Potentiometer tap 35 migrate during its adjustment on the potentiometer resistor 34 in Direction to the resistor 32, so that the potential of the cathode 37 of the tube 21 with increasing exposure time is changed towards positive values.

At the same time, the time circuit capacitor 27 is charged by the photocurrent of the photocell 26. As soon as the grid 29 of the tube 21 connected to it has reached the ignition voltage with respect to the cathode 37, the tube 21 ignites, the relay 22 is energized again, and the switches 22a , 22b, 22c are shown in FIG Position postponed. As a result, the copy lamp 1 is switched off. Furthermore, the magnetic coupling 39, 40 becomes ineffective, so that the shaft 38 and with it the potentiometer tap 35 are rotated clockwise by the spring 43 and returned to the initial position, the cathode potential of the tube 21 falling again to the potential of the contact point 57.

It can be demonstrated that the Schwarzschild exponent p is precisely taken into account during an exposure process if the potential U of the cathode 37 changes as a function of the exposure time t according to the following equation:

^v - ⁿ -k

The components of the circuit are dimensioned so that the cathode potential at the time ί = ί ₀ (calibration time) is equal to U ₀ .

By a corresponding resistance curve of the potentiometer resistor 34 or by a between the clutch disc 39 and the potentiometer tap 35 arranged gear, z. B. by a Cam control gear, it is achieved that the cathode potential tapped at the potentiometer resistor 34 is changes depending on the exposure time exactly according to the above equation. Included the angular velocity of the shaft 38 is chosen so that the tap 35 the resistor 34 during the longest exposure time that usually occurs.

By adjusting the two coupled sliders 31, 33 of the resistors 30, 32, the device can be adapted to different Schwarzschild exponents. With the above arrangement, Schwarzschild exponents ρ <Ξ 1 can be taken into account. For the case p ^> i, which, however, rarely occurs in practice, a second option, which can be switched on and not shown in the figures, can be used

shown potentiometer allows a shift of the cathode potential towards the negative will.

An approximate solution of the present problem with much simpler means allows Embodiment of the invention shown in FIG. 2. With regard to the circuit 6 and the timing circuit 7, this embodiment corresponds to that shown in FIG Exposure control device. The change in the cathode potential of the tube 21 with time is however no longer through a motor-driven potentiometer tap, but through an additional, reaches its state of charge changing capacitor 60.

The capacitor 60 is in series with a controllable resistor 61 and is connected to the taps 64, 66 of two potentiometers, the resistors 63, 65 of which are connected in series and arranged between the conductors 24, 25 of the timing circuit 7. The wiper of the resistor 61 and the potentiometer tapping 64, 66 are mechanically coupled to one another. The contact point 67 between the capacitor 60 and the resistor 61 is connected to the cathode 37 of the thyratron 21 via the conductor 68. The switch 22d actuated by the relay 22 lies parallel to the capacitor 60.

In the initial state of the device shown in FIG. 2, the capacitors 27 and 60 are short-circuited, and current flows through the tube 21. The potential its grid 29 is negative with respect to the cathode potential, the potential of the potentiometer tap 63 corresponds.

At the beginning of the switching time, ie when the trigger switch 23 is flipped, the switches 22 b, 22 d open. Thereafter, the voltage across the time capacitor 27 and thus the potential of the grid 29 of the tube 21 increase linearly, while the voltage across the capacitor 60 and thus the potential of the cathode 37 increase according to a logarithmic function. As soon as the grid 29 of the tube 23 has reached the ignition voltage with respect to the cathode 37, the tube 21 ignites and the relay 22 is energized. As a result, the exposure process is ended in a manner analogous to that in the embodiment shown in FIG. 1; the capacitors 27., 60 are short-circuited.

The voltage of the capacitor 60 can rise to a maximum value during its charging, which is determined by the difference in the potentials of the potentiometer taps 64, 66. The resistance 61 is set taking into account the setting of the potentiometer taps 64, 66 so that the duration of the charging of the capacitor 60 to the maximum value of the longest, usually occurring Exposure time corresponds.

By adjusting the potentiometer taps 64, 66 and the wiper of the resistor 61, the device in turn are adapted to different Schwarzschild exponents.

A further approximation to the exact solution of the task at hand can be achieved, if instead of a single i? C element, as is used in the subject of FIG. 2 (switching elements 60,61), two i? C links can be used. This embodiment of the invention is shown in FIG shown.

There the circuit 6 and the timing circuit correspond 7 in turn the corresponding assemblies of FIGS. 1 and 2. Between the conductors 24, 25 of the timing circuit 7, the resistors 69, 71, 73 of three are parallel to the photocell 26 and to the Zeitlireiskondensator 27 Potentiometers arranged in series. Between the potentiometer taps 70, 72 are located Capacitor 75 and a resistor 76 of a first i? C element and a resistor 77, while between the potentiometer taps 72, 74 apart from the resistor 77, a capacitor 78 is arranged. The capacitor 78 and the resistor 77 form the second IC element. So that the two i? C links do not significantly influence each other, the resistance value of the resistor 76 is considerably greater than the resistance of resistor 77. Capacitor 75 is connected via conductor 79 to the Cathode 37 of the tube 21 connected. Parallel to the capacitors 75,78 are the switches 22 * ?, 22 /, which are actuated by the relay 22.

Before the start of the switching time, the capacitors 75, 78 are short-circuited, the cathode 37 of the tube 21 is at the potential of the tap 70. When the trigger switch is flipped, the switches 22 e, 22 / open and the capacitors 75, 78 begin to charge. The potential of the cathode 37 of the tube 21 rises in accordance with the voltage on the capacitor 75. The ignition of the tube 21 and the termination of the exposure process take place in an analogous manner to the devices according to FIGS. 1 and 2.

At the start of the switching time, the IC element 75, 76 is at a voltage which corresponds to the potential difference between the potentiometer taps 70, 74. The additional IC element 77, 78 ensures that the voltage applied to the RC element 75, 76 decays to a value which corresponds to the potential difference between the potentiometer taps 70, 72 with increasing duration of the switching time sequence. In this way it can be achieved that in the above-mentioned device the increase in potential at the cathode 37 of the tube 21 occurs faster in the first part of the switching time sequence than in the device shown in FIG. 2, in which the cathode potential increases according to a logarithmic function.

Of course, the subject of Fig. 3 by adjusting the potentiometer taps 70, 72, 74 and the variable resistors 76, 77 different. Schwarzschild exponents are adjusted.

Claims (7)

Patent claims: 1. Time switch device for photographic copiers with a grid-controlled electron tube, a its charge state changing, connected to the tube time circuit capacitor and a Device influencing switching time sequence for taking into account the Schwarzschild exponent of the photosensitive material, characterized in that to take into account the Schwarzschild exponent Means are provided for changing the potential of an electrode of the tube (21) during the switching time sequence. 2. Time switching device according to claim 1, characterized in that the time circuit capacitor (27) is connected in a manner known per se to the grid (29) of the tube (21) and that means are provided, through which the potential of the cathode (37) of the tube (21) during the switching timing is changed. 3. Time switching device according to claim 2, characterized by a voltage divider (30,32) with a potentiometer (34) and a drive device (42), which with the cathode (37) of the Tube (21) connected tap (35) of the potentiometer meters (34) adjusted during the switching time sequence. 4. Time switching device according to claim 3, characterized by a means of the main switch (56) switchable electric motor (42) and a tap (35) of the potentiometer (34) the motor-switching magnetic clutch (39,40), which is controlled by a relay (22) of the .Zeitschaltvorrichtung is switched on for the duration of the switching time. 5. Time switch device according to claim 2, characterized by a with the cathode (37) of the tube (21) connected capacitor (60,75) and one of a relay (22) of the time switch device operated switch (22i £, 22 e), through which the capacitor (60, 75) for the duration of the switching time can be switched into a charging circuit is. 6. Time switching device according to claim 5, characterized by means (77, 78) through which the voltage of the voltage source lying in the Ladesirora circuit of the capacitor (75) during of the viewing time sequence is changed. 7. Time switching device according to one of the preceding claims, characterized in that adjustable resistors (30, 32; 63, 65; 69, 71, 73, 7: 6, 77) are arranged in the circuit of the means influencing the cathode potential, through which the The degree of influencing the cathode potential is adjustable in accordance with the size of the Schwarzschild exponent of the photosensitive material. ' 1 sheet of drawings 809 698/145 12.58