DE847249C - Exposure device for photographic layers, especially for the measurement of blackening and the recording of blackening curves in sound films - Google Patents

Description

For recording blackening curves in sound films for the purpose of checking the emulsion it is necessary that the photographic layer is exposed in the manner of a gray wedge, its Blackening can be measured at different points after developing. For the accuracy The even illumination of the wedge plays a particularly important role in the measurement Role that works with normal light sources, e.g. B. incandescent lamps, can not be easily achieved. According to the invention it is therefore proposed as a light source for the measurement exposure of the photographic Not a gas discharge tube, preferably to be used in the form of a rod-shaped fluorescent tube. Tests have shown that the light intensity on the surface of the gas discharge tube is very constant and there are deviations are less than 1%, an accuracy which is easily sufficient for the blackening measurement is. so that advantageously special means for keeping the light intensity constant along the Step wedge are not required. Another advantage of the invention is that the light the gas discharge tube is very effective photochemically, and further that the lamp is hardly in operation gets warm; damage to the photographic layer due to inadmissible heating or the risk of fire can therefore not occur during the measurement.

According to a further development of the invention, it is proposed that the film strip to be exposed parallel to a rod-shaped fluorescent tube in one

to arrange opaque box and to provide means which cause the from the Fluorescent tube amount of light acting on the filmstrip from one end of the filmstrip to the at the other end decreases continuously or according to a regular function. This is special a perforated screen with holes in a row, which are in the box between the Light tube and the film is arranged. The ίο light transmission of the holes is supposed to be from one From the end of the row of holes to the other end, they become steadily smaller or larger. Furthermore, should be appropriate Means are provided which are suitable for changing the overall light intensity, in particular in that exchangeable filters, ground glass or the like. Arranged between the aperture and the fluorescent tube that change the light transmission of all holes in the pinhole together. Alan can use it to change the exposure to adapt the meter to films with different Sensitivity.

According to a further development of the invention, the measuring arrangement is to be set up so that one not only measure the steepness of the blackening curve, but also measure a certain blackening that results from a fixed exposure of the film. One can measure by the latter i.a. control the development process. If z. B. with the optical sound recording in the sound camera If a certain luminous flux is used, the same blackening should always result on the film after development. The steepness of the blackening curve and the blackening caused by a certain striking Amount of light generated are not directly related; therefore both should Values are measured separately. With the help of the measuring arrangement of the invention, the second Measurement are carried out in such a way that the blackening of a certain field of the exposed step-by-step Film is determined. A prerequisite for this, however, is that the gas discharge tube outgoing light amount is constant with each exposure. According to a further development of the invention this condition is to be met by a switching device that, after generating a certain Amount of light (lumen X time) the fluorescent tube switches off automatically if necessary. The lighting duration However, this is not decisive in all cases for keeping the amount of light constant, because the luminosity can change. According to a development of the invention, therefore a control arrangement can be provided, which consists essentially of a photosensitive Cell, e.g. B. a photocell, which is illuminated by the fluorescent tube, and in connection thus a switching arrangement that switches off the fluorescent tube after a certain amount of light.

The invention and related details are explained with reference to FIGS. 1 and 2, for example.

In Fig. Ι the measuring arrangement is shown in principle and in Fig. 2 a tube circuit for achieving a constant amount of light at the Measurement exposure.

In the measuring arrangement of FIG. 1, the elongated box 1 is in an opaque box Bar-shaped fluorescent tube 2 installed, which works on the principle of gas discharge lamps. the Light intensity is relatively constant along its straight extension. About it is the as Intermediate wall formed perforated screen 3 is provided, which in a parallel to the fluorescent tube 2 extending row contains several holes whose diameter is from one end of the row until the other end becomes smaller or larger. With the same hole diameter you can also different permeable light filters can be used. Polarization filters are used as light filters into consideration, which are optionally set up adjustable. Suitable for weakening light there are also small pinholes. Between the fluorescent tube 2 and the diaphragm 3 is another in Fig. Ι not shown device attached, for. B. a color filter or a focusing screen, through which the total light intensity can be changed; the filter or the ground glass can be replaced will. The film strip 4 to be checked for the measurement is placed over the row of holes placed on the panel 3 and expediently with a holding device, not shown in detail, z. B. a frame held.

In addition to the fluorescent tube 2, the photoelectric cell 5, for. B. a photocell, arranged so that they is irradiated in a suitable manner by the fluorescent tube 2. The photoelectric cell 5 is to the Tube circuit 6 connected, at the output of which the relay 7 is located, the switching contact 8 of which in the supply circuit of the fluorescent tube 2 is switched on. After switching on the fluorescent tube 1 the film 4 becomes like a step wedge in a number of fields corresponding to the number of holes exposed to different degrees. After generating a certain amount of light, the photoelectric causes Cell 5 the termination of the exposure via the tube circuit 6 and the relay 7, its contact 8 interrupts the supply circuit and the fluorescent tube 2 switches off. After developing of the film is the blackening of the individual fields in a manner known per se The density meter is measured and the steepness of the density curve is determined from it. Since the the amount of light used has been kept constant, one can also control the development process control by determining the blackening of a very specific field.

The already mentioned gradual change of the total light for the adaptation to different Film emulsions can also be produced by making the perforated diaphragm 3 exchangeable and uses perforated diaphragms with other hole diameters. The holes can do this too be provided in a metal strip, which is installed in the box 1 in place of the panel 3 and can be adjusted. The strip contains

several different rows of holes and next to each row of holes a marking with the designation the associated film emulsion.

The tube circuit 6 is shown in detail in FIG. It contains the electron tubes 9 and 10 operated in a bridge circuit, which are strongly counter-coupled for stabilization. The winding of the relay 7, the contact 8 of which is connected to the supply circuit of the gas discharge tube 2, is connected to the cathodes of the two tubes. The grid of the tube 10 is given a certain fixed bias, e.g. B. 30 V, which is kept constant by the stabilizer 11. On the grid of the tube 9 is the capacitor 12 and parallel to it the photoelectric cell 5. Furthermore, a toggle switch 13 is provided, via the contact α of the stabilizer 11, a voltage can be applied to the capacitor 12, which voltage, z. B. 80 V, is greater than that on the grid of the tube 10. The contact b of the toggle switch 13 is in the supply circuit of the fluorescent tube 2 in series with the relay contact 8 and is mechanically coupled to the contact α. When putting the circuit into operation, the toggle switch 13 is first placed in position I so that the capacitor 12 is charged, e.g. B. as mentioned to 80 Y. In the tubes 9 and 10 thus different large cathode currents flow so that the relay 7 is excited by the equalizing current and its contact 8 is closed. Then the toggle switch 13 is turned to position II and the fluorescent tube 2 is switched on and ignited via the contact b. At the same time, the voltage of 80 V is removed from the capacitor 12 via the contact a. The now burning fluorescent tube 2 irradiates the photocell 5 in addition to the film strip 4 to be exposed, so that a countercurrent is generated in it, which discharges the capacitor 12. Thus the voltage on the grid of the tube 9 gradually decreases, and the currents in the tubes 9 and 10 equalize one another. With current equality, which is achieved when the grid voltage of the tube 9 the value of the grid voltage of z. B. has reached 30 V of the tube 10, the relay 7 drops out and the fluorescent tube 2 is switched off at the relay contact 8. The amount of light achieved in each exposure is constant, regardless of whether the brightness of the fluorescent tube 2 changes. In the case of different brightnesses, a more or less large discharge current is generated in the photocell 5, so that the discharge process of the capacitor 12 proceeds quickly or more slowly according to the light intensity.

In certain cases, the automatic switching can be dispensed with, and you can instead use a measuring arrangement on which the amount of light can be read. For this purpose z. B. an electrostatic Voltmeter suitable, which is placed in parallel with the capacitor 12. This will initially be like charged to a certain voltage during automatic switching, then the gradual discharge via the photocell 5, and you can switch off manually as soon as a certain lower voltage is displayed on the voltmeter.

The invention is generally applicable to measurements in photographic layers, e.g. also in photographic layers Papers, is suitable and is not limited to the density measurement of sound films.

The control circuit for keeping the amount of light constant may also be universal usable e.g. B. in copying processes, enlargers and as a special device for the light quantity counting.

Claims (8)

75 claims: 1. Exposure device for photographic layers, in particular for density measurement and the recording of density curves in sound image films, thereby marked net that the light source for the measurement exposure of the photographic layer is a gas discharge tube, is preferably provided in the form of a rod-shaped fluorescent tube (2). 2. Device according to claim 1, characterized in that that the film strip to be exposed (4) parallel to a rod-shaped fluorescent tube (2) in an opaque Box (1) is arranged, and means are provided which cause the from the Light tube (2) acting on the film strip (4) amount of light from one end of the film strip (4) decreases steadily to the other end or according to a regular function. 3. Device according to claim 2, characterized in that the means for the generation the decrease in the amount of light acting on the film (4) between the film (4) and luminous currents (2) an optionally exchangeable aperture plate (3) with lying in a row Holes is provided whose light transmission from one end of the row of holes to the other end becomes smaller, e.g. J3. by arranging different hole diameters or, with the same diameter of the holes, through differently permeable filters or perforated diaphragms. 4. Device according to claim 2 or 3, characterized in that means are provided that are suitable for changing the overall light intensity, in particular with interchangeable ones Filter, e.g. B. in the form of focusing screens, which the light transmission of all holes in the Change the aperture together. 5. Device according to one of claims 1 to 4, characterized in that means are provided which are appropriate to the amount of light acting on the photographic layer to keep constant during exposure, e.g. B. by a switching device that after generation a certain amount of light (lumen X time) the fluorescent tube (2) possibly automatically turns off. 6. Device, in particular according to claim 5, characterized in that as a means for Keeping the amount of light constant, a light-sensitive cell illuminated by the fluorescent tube ίί'ι. / .. Vi. Photocell, is provided. soft ge is suitable for controlling the amount of light. 7. Device according to claim 6, characterized in that that the photoelectric cell (5), e.g. Usually the photocell, the discharge of one to one Caused certain voltage charged capacitor (12). 8. Device according to claim 7, characterized in that the photoelectric cell (5) is in connection with a tube circuit with at least two counter-coupled Rölin-ti (u, \ o) operated in a bridge circuit, of which the eitu- (ιοί mil ιΙιπ- μι (iiltfr to i'iner constant bias voltage litgi and the other with its grid on a aut a higher voltage chargeable capacitor (12), which is discharged by the photoelectric cell 5 connected in parallel, and that a relay (7) is provided, whose winding ends are on the cathodes of the two tubes and whose contact (8) is in the feeder circuit of the Leight
tube (2) is switched on. 1 sheet of drawings © 5298 8.