DE718481C - Gas-filled photocell for converting light changes into electrical current changes, their switching and coupling to amplifiers - Google Patents

Description

Gas-filled photocell for converting light changes into electrical ones Current changes, - their circuit and coupling to amplifier The invention relates rely on a gas-filled photocell; taking advantage of the external photoelectric Effect serves to convert changes in light into changes in current. It is at these cells. already proposed to adjust the suction tension of the photocells so that that a stable operation of the cells, in the area of the 'independent glow discharge with currents which are greater than the actual ignition voltage of the cells belonging. The continuous operation of the cells can easily be called into question here will.

In order to ensure trouble-free operation, according to the invention suggested that the points of use of the glow discharge outside of the area for influencing light to place the used part of the electrodes. For this purpose, the anode is in cross section trapezoidal or step-shaped; the anode can .aber also at an angle to the cathode get lost. For the coupling to the amplifier is. According to the invention a so dimensioned complex resistance provided that ex preferred the high frequencies transmits.

The invention is to be explained in more detail using the illustrations. Fig.i. shows a previously common photocell coupling; Fig. -> shows a photocell bank@opplun.g, which is modified according to the invention; Fig. 3 shows an embodiment of the anode the photocell according to the invention; Fig. 4 also shows an embodiment the anode according to the egg finding.

Fig. I shows the coupling of the photocell P to the amplifier for the Purposes of sound film reproduction, television or image transmission. It takes place generally so that the photocell P via its battery E or a rectifier connects with a sieve chain with an ohmic resistance Rp. To the terminals of this Resistance, the ohmic resistance RG is placed across a capacitor Co. the Terminals of the resistor Rc are to the grid and with the interposition of a Energy source connected to the cathode of an amplifier tube.

As Fig. Z shows, according to the invention instead of the ohmic resistance Rp no transmitter Ü used for coupling. Since the DC resistance of a such a transformer is generally very small, it is useful; zukr achievement the correct working point on the photocell characteristics in the area more independently To put an ohmic resistor R1 in series with the transformer. Parallel to. Resistance R; a capacitor C1 is connected to the alternating current enables the smooth passage to the transformer Ü for all frequencies to be transmitted. Through this . it is achieved that the @full AC voltage at the transformer and thus takes effect on the grid of the first amplifier tube. In the case of glare discharges one can always observe an inertia effect that results in the transmission factor depends on frequency tvird. The high frequencies are generally transmit less well than the low frequencies. To the phenomenon of inertia eliminate, you either build the transformer in such a way that the high frequencies are preferred or you can switch linearly in series or in parallel with the load resistance distorting limbs that transmit very high frequencies to the load resistor enable.

The circuit can be made in such a way that the phoba cell has a Rectifier with a sieve chain from the alternating current network here supplied with direct voltage will. The same applies to the connected amplifier arrangement. As a result of the larger The photocell can be used by the entire amplifier without any special protective device .be trained as a power supply amplifier, while this was not possible earlier.

In order to increase the service life of the photocell when operating in the glow area, in particular in the field of independent glow discharge is achieved according to the invention photoelectric cell designed so that the points of use of the glow discharge outside of the part of the electrodes or of the used for influencing light Space between the electrodes.

For example, the electrodes can be fused as shown in Figure 3, which shows an anode with a trapezoidal cross-section. The place of the glow discharge is at the edge where the anode is closest to the cathode. The space between the distal part of the anode around the cathode is therefore dark. The luminous flux that controls the photocell falls into this space.

The electrodes of the cell can also be given the shape shown in Fig. 4, in which the anode is step-shaped in cross-section. The glow discharge occurs at the end i closest to the cathode, while parts 2 and 3, which are exposed to the luminous flux from the front, remain dark.

Since the photocell is usually near moving bodies (Additional audio device, scanning disc, mirror wheel) is arranged, the cell is vibrated . exposed. In order to eliminate the disturbances that occur as a result, which result in changes in capacity affecting the anode versus the cathode, it is beneficial to either use the anode or the cathode rigidly with one another by insulating bodies, for example glass rods to be connected so that the electrodes do not move in opposite directions, or the mechanical properties of the anode, if possible from the transmission area relocate out.

Claims (7)

PATENT CLAIMS: i. Gas-filled photocell, in particular photocell with hydrogen filling and a several-molecule-strong Kaliu @ mliydritschicht, for the conversion of light changes into electrical whereby .the suction voltage of the photocell is set so that a stable operation of the cell in the area of the independent glow discharge takes place with currents that are greater than those belonging to the ignition voltage of the cell, characterized in that the points of use of the glow discharge are outside the part of the electrodes used for influencing the light. 2. Photocell according to claim i, characterized in that the anode in cross section trapezoidal -shaped. 3. Photocell according to claim i, characterized in that d.ass the anode is step-shaped in cross-section. q .. Photocell after Claim i, characterized in that the anode runs obliquely to the cathode. 5. Photocell 'according to claim i or the following, characterized in that the anode and Cathode through insulating body, e.g. B. glass rods, rigidly connected to each other are. 6. Coupling circuit of the photocell according to claim i or the following, characterized characterized in that as a coupling resistor to the amplifier a dimensioned complex resistor is provided that it transmits the high frequencies preferentially. 7. Coupling circuit of the photocell according to claim i or the following, characterized .by an impregnation transformer .as a load resistor, with which an ohmic shear in series Resistance is connected, which is bridged by a capacitor. B. Circuit of the photocell according to claim i or the following, characterized in that the suction voltage Remove the photocell from the AC network using a rectifier and a sieve chain will.