DE562745C - Circuit for glow amplifier tubes - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
OCTOBER 28, 1932

REICH PATENT OFFICE

PATENT LETTERING

VR 562745 CLASS 21a ⁴ GROUP

Dr. Georg Seibt Akt.-Ges. in Berlin-Schöneberg circuit for glow amplifier tubes

Patented in the German Empire on April 20, 1930

The invention relates to a circuit, fed from a direct current or alternating current network, comprising one or more amplifier tubes arranged in cascade, in which the electron source is a glow discharge that passes between two electrodes provided for this purpose, the so-called glow discharge electrodes. These tubes also have one or more control electrodes and a so-called amplifier anode, which attracts some of the electrons formed by the glow field. The special subject of the invention is a combination of the individual feed circuits of this tube circuit in such a way that unnecessary current losses are avoided. Such an arrangement could not be realized with the previously known means of tube technology.
With the usual filament tubes, the supply of the heating circuit on the one hand and the anode circuit on the other hand is known to cause the following difficulties: Since the heating circuit has low voltages and relatively large currents, whereas the anode circuit has high voltages and low currents, it is always difficult to get both types of current from the same power source refer to. It is well known that battery devices have two different power sources; in the case of mains connection devices, in which one initially only has a single power source, one must, however, resort to other aids which, on the one hand, make the production and on the other hand, above all, the operation of the device more expensive. Has one z. B. an AC power supply, it is necessary to provide a special transformer for heating and anode voltage, but at least a separate secondary winding of the supply transformer, of which one winding for high voltage and low current and the other for low voltage and higher current is set up. In the case of DC power supply units, the situation may be even more unfavorable; In this case, it is necessary to destroy around 95% of the available mains voltage in the heating circuit by means of an appropriately dimensioned series resistor. In addition, in order to avoid even greater losses, all the filaments must be arranged in series in the case of cascade connections.

All of these difficulties are overcome by an arrangement in accordance with the present invention eliminated. The features of the new network connection circuit which characterize the invention lie in that the cascade-connected amplifier tubes are provided with a glow discharge path as an electron source, whose feed circuits are switched so that the glow discharge circuit together with a relatively low series resistance itself as a voltage divider for the amplifier anode leading amplifier voltages. This makes it possible to use each of the individual

electrical circuits despite simultaneous direct current consumption from the same power source to feed practically loss-free.

It has already been proposed per se in the case of tube circuits for direct current mains connection been to arrange the filaments in series to form a resistor at which the anode voltages be tapped and the total voltage drop with the filaments, required for the anode and heating voltage. However, as has already been stated, this results in extremely considerable amounts Losses. These losses occur in the subject matter of the invention because of the order of magnitude approximately the same dimensioning of the glow voltage on the one hand and the amplifier voltage on the other hand does not have. But above all, she has Invention, caused by the special properties of a glow discharge, also include the following Advantage: It is created by the resistor connected in series with the glow path and the decrease of the amplifier anode voltages from these resistors a kind of DC feedback, which greatly increases the gain of the tube has the consequence. This effect will be discussed at the end of the description will.

The invention will first be explained in more detail with reference to the simplified circuit according to the figure. The circuit diagram shows as an example two glow amplifier tubes T ₁ and r ₂ in a cascade connection with transformer coupling. Both tubes are fed by a current source q, which in practice is either a direct current network or a rectifier operated from an alternating current network. It is assumed that the DC voltage that prevails at q has already been smoothed. This voltage, which may be 220 volts, for example, is now closed via a series resistor w _{and via the glow discharge path g x} and g _{2 of} the tubes T ₁ and r _% , which are connected in series with this but parallel to one another. The series resistor w shown is not only used to regulate the glow voltages in the glow gaps g _lt g. ₂ , but at the same time as a potential resistance for the supply lines leading to the amplifier anodes V ₁ , W _2. So the amplifier anode voltage of the tube r _{2 is} dissipated from the point +220 of the voltage divider; the voltage at the amplifier anode V ₁ is somewhat lower; it is around 210 volts. From the given voltage distribution it can already be seen that only a small part (about 10%) of the total voltage is applied to the switching resistor w. This voltage difference, which is 25 volts according to the figure, corresponds to that voltage between the glow discharge anode and the amplifier anode V ₁ or v. ₂ , which must not be exceeded in order not to transform the amplifier current into a pure glow current. This is the so-called ionization voltage of the gas filling in the tubes. The series resistor w has a resistance value in the order of magnitude of a few hundred, at most ι 000 to 3,000 ohms; so it causes practically no current loss, since the resistance of the glow path is significantly higher and since the amplifier current and the glow current can be dimensioned so that they are approximately the same size. The ohmic value of the ballast and voltage divider resistance w is roughly the same as the internal tube resistance between the glow path and the amplifier anode. It can be advantageous to make the resistor w adjustable as a series resistor of the glow path. For further regulation or setting, a resistor could also be arranged parallel to the glow path or lines, which would mean considerably greater than the ballast and potentiometer resistor w.

Another advantage of the described arrangement consists in the following: If one assumes (cf. the patent drawing) that a certain current flows in the tube Y ₁ at a certain negative bias at the control grid S ₁ , then depending on the penetration of this tube a Reduction of the discharge current between V ₁ and g _x occur when the bias voltage at S ₁ is changed towards more negative values. This change in the anode current as a function of the grid bias is now greatly increased by the special coupling between the glow path and the amplifier path by means of the resistor w : If, assuming a certain initial state, the bias of the grid S ₁ changes towards more negative values, then it changes Not only does the discharge current change between V ₁ and g _v, but there is also a retroactive effect on the glow path ^ ₁ . If the internal resistance of the tube V ₁ rises due to the negative grid bias at S ₁ , a current increase will take place in the parallel path formed by w and g _x , which will decrease as a result of the negative resistance of the glow path ^ ₁ the voltage between the glow electrodes. This considerable decrease in the glow voltage results in a lower electron yield and consequently a further reduction in the amplifier current between V ₁ and g _x . This explains the strong increase in the degree of reinforcement.

The invention is particularly suitable in connection with such glow amplifier tubes, in which, according to previous patents of the

finders the discharge anode is designed in such a way that it acts as a shield between the glow path and amplifier electrodes acts.

Claims (1)

Claim: Circuit fed from a direct current or alternating current network from a or several tubes arranged in a cascade with glow discharge paths as electron source, characterized in that that in the circuit of the glow discharge paths connected in parallel with one another, namely connected in series with them, there is a resistance, from which at the same time the supply lines to the amplifier anodes, whose potential is higher than that of the positive glow electrode, preferably changeable are tapped. 1 sheet of drawings