DE1057243B - Gas discharge tubes for generating tilting vibrations - Google Patents

Description

GERMAN

Gas discharge tube for generating tilting vibrations

The invention relates to gas discharge tubes for generating tilting vibrations by discharges via the plasma inside the tubular envelope with an existing between the cathode and the anode Tension.

The expression "plasma" means a gaseous atmosphere in which an increased and substantially equal concentration of positive and negative charges; d. H. of free electrons and ions, is present.

The usual flip-flops with gas discharge tubes are constructed in such a way that a capacitor is parallel to the discharge path. The capacitor is charged by a DC voltage through a resistor, which is greater than the ignition voltage of the tube. As soon as the voltage of the capacitor reaches the value reaches the ignition voltage, the tube ignites, whereupon the capacitor discharges through the tube. Then the process is repeated. The prerequisite for the operation of these flip-flops is their existence a voltage that is greater than the ignition voltage of the tube.

In the case of ultra-high frequency vacuum tubes, it is known to use the screen grid block capacitor in the interior of the 25th to eliminate the inductance of the supply lines

To arrange tube. The application of this measure

However, on the Kippkondensator the usual Kippschaltun- 2 gen with gas discharge tubes is not common,

since no advantages are to be expected from this. known radiation source for beta particles is also already known, is arranged in a gas discharge 30 , so that a permanent transfer of the electrical

Applicant:
Center d'Etudes & Developpements
de l'Electronique, SARL,
Courbevoie _r Seine (France)

Representative: Dipl.-Ing. E. Prince
and Dr. rer. nat. G. Hauser, patent attorneys,
Munich-Pasing, Bodenseestr. 3 a

Claimed priority:
France, November 30, 1956

tube to place an electrode that is not held at a fixed potential. This electrode is supposed to act as an electrostatic screen and make it easier to ignite the tube.

Furthermore, it is known to mount radiation sources for beta rays in gas discharge tubes, which have the purpose of ionizing the gas and thereby reducing the ignition voltage of the tube.

The invention makes of these various dimensional charges from that associated with the cathode Occupancy of the capacitor to the occupancy in contact with the plasma is effected. The arrangement according to the invention has the effect that the radiation source is essentially the Task of the otherwise usual external voltage source and the series resistor for charging the capacitor takes over. The voltage source that is also still present is only used to deliver the

took use of the current flowing in a novel association 40 of the discharge. The beta particles

result in a surprising and beneficial effect. This makes it possible to use tilting vibrations a gas discharge tube, although the existing voltage is far below the ignition voltage the tube lies.

This is achieved according to the invention in that the latter is lower than the running voltage that in on As is known, the tubular flask contains at least one capacitor, one of which is occupied is in contact with the plasma and has no fixed electrical potential in a manner known per se, while the other coating is isolated from the plasma and electrically connected to the cathode in a manner known per se is connected, and that in the capacitor one on

The radio isotopes used in this arrangement are fast electrons that carry a negative charge. Their effects can be compared to those of electrons from a thermionic source delivered

and accelerated by a strong electric field. The beta particles wander through the space between the capacitor assignments and settle on the outer assignment, which is in There is contact with the tube atmosphere, but they do not enter this atmosphere. By accumulating with more and more charges, the potential of this occupancy increases until between the cathode and If the assignment is not at a fixed potential, the ignition voltage of the tube has been reached. As soon as the ignition

909 510/363

1 05

has taken place, a current flows on the one hand between the cathode and the anode of the tube, its Strength is determined by the DC voltage source lying between these electrodes, and on the other hand the capacitor discharges, whereupon the process begins again.

This creates an automatic toggle switch based on a completely new principle. The kinetic Energy from the particles emitted by a radioactive substance is converted directly into electrical energy converted, and this electrical energy is used to generate the ignition voltage. This gives the advantage that the voltage of the external voltage source can be very low. Furthermore, all are essential parts of the toggle switch housed inside the piston tube, so that a very compact structure results. Above all, however, are the efficiency and power amplification of the arrangement significantly increased compared to the usual multivibrator circuits, since the otherwise unavoidable losses in the series resistor omitted. The charging of the capacitor by the radiation source takes place very evenly, so that there is a high level of stability and operational reliability of the arrangement.

An embodiment of the invention is shown in the drawing as an example. In it shows

1 shows a cross section through the gas discharge tube, the associated circuits being indicated are and

2 shows a section through a possible embodiment of the capacitor contained in the gas discharge tube.

The tube has a piston 1 . This contains a cathode, which consists of a rod or a cylinder 2 and is covered with a layer 3 of an electron-emitting substance, and an anode 4, which is coaxial with the cathode. The cathode should be a cold cathode; the use of a thermionic cathode is generally not beneficial except in circuits where higher performance is desired. The anode 4 is interrupted over a certain sector. In the space formed in this way, a capacitor arrangement is attached, which can have an outer cylindrical covering 7 and an inner covering 5 lying coaxially thereto. A layer 6 made of a radioactive isotope, which emits beta particles, is applied to the inner surface of the covering 5. For the sake of clarity, the proportions of the various parts are not shown correctly. A metal coating 11 serves to dissipate charges which strike the wall of the bulb opposite the opening of the anode.

A conductor 8 connects the cathode with the inner coating 5 of the capacitor. From the point of view of the invention, it is immaterial whether this electrical connection runs inside the piston or outside it. The details of the seal, the bushings and the mechanical mountings are not shown in detail, since they result from the known prior art by themselves.

The capacitor is assumed here to be coaxial, and FIG. 2 shows a section of two insulating plates 12 and 13 which keep the two assignments at a distance from one another. From this illustration it can also be seen that the pin 8 used to supply the voltage carries the entire arrangement and supplies the occupancy 5 with voltage via the conductive cross struts 14 and 15. Such an arrangement

7 243

A prerequisite for this is that the assignments are not separated by a solid dielectric. The plates 12 and 13 can, for. B. consist of glass or a ceramic material, and the space formed by them and the outer occupancy 7 of the capacitor is evacuated. However, you can also capacitor arrangements with solid dielectric, z. B. use glass, mica or an organic material, but it should be emphasized here that the leakage resistance of the dielectric should preferably be selected to be very high, so that the capacitance of the capacitor and thus its space requirements are not too large. Leak resistance and capacitance primarily determine the breakover frequency of the arrangement. In the example, the inner lining 5 is a very thin nickel tube, e.g. B. with a thickness of about 25 μ. A thin layer of a radioactive isotope, which emits beta particles, is attached to the inner wall of the occupancy 5. This layer can either be produced in the form of a pure substance by thermal vapor deposition or, because it is easier to implement, from a salt of this isotope, which is applied by chemical reaction with the wall or by precipitation or sedimentation. Obviously, the chosen method has no effect on the intended effect of the invention. It should be noted here that the handling of a substance which emits beta rays does not in itself present any dangers which cannot be eliminated with simple and cheap protective measures. Substances emitting beta rays are available for the intended use, which are in a large range of the useful life, which can be from a few months to several tens or even thousands of years. Obviously, there is no need to resort to radioactive isotopes in the practice of the invention whose useful life exceeds the intended life of the tube itself. As an example, thallium 204 can be given, the useful life of which is about 2.7 years, and silicon 31, the useful life of which is 14 years, but other isotopes can also be used without distinction in the gas discharge tube according to the invention.

The emitted particles penetrate the thin wall 5j which, due to its property and its thickness, has only a very low absorption coefficient for beta rays. For a nickel wall with a thickness of 25 μ, this absorption coefficient is below 10%. The particles traverse the dielectric and hit the coating 7 at a very high speed, where they release their electrical charges. As a result of the accumulation of these charges, the voltage of the coating 7 increases continuously until it reaches the ignition voltage for the gas in the bulb between the cathode and the coating.

Between the cathode and the anode of the tube there is a voltage which is determined by the battery 9 . As already mentioned, this voltage need not be very high. For a filling of mercury vapor or cadmium vapor, it can for example be below 6 volts; for a filling of hydrogen, nitrogen, argon, krypton or xenon it can be below 12 volts, and for a filling of felium or neon it can be less than 24 volts. The anode voltage actually contributes neither to the formation nor to the maintenance of the plasma, but is only used during the times when the plasma is due to the phenomenon described

Claims (3)

is present, for supplying the current which passes through the plasma, which is known to have a very low resistance. The gas discharge tube according to the invention thus acts in a certain sense as a transformer or current converter which converts a low direct voltage into a high alternating voltage, specifically in a purely electronic way. The term "alternating voltage" is to be understood in the broadest sense, since it is a tipping phenomenon, so that at least theoretically the voltage tapped at the terminals of a load resistor in series with the anode-cathode circuit of the tube is sawtooth-shaped. However, as is known, the deionization time of a gas discharge tube is by no means negligibly short, as a result of which the teeth of the sawtooth voltage become less symmetrical. This phenomenon is regarded as a disadvantage in the case of the usual gas discharge tubes, which are intended to act as switches or relays. For the purposes of the invention, however, this is seen as an advantage which can be increased by introducing a certain amount of a metastable gas into the piston. A metastable gas is understood to be a gas whose impact ionization occurs at lower voltages or currents than that of the gas which forms the main part of the tube filling. The shape of the tapped voltage can then be designed approximately triangular, so that it is much easier to convert it into a sinusoidal curve, if necessary, by means of simple filters in the consumer circuits. If the transformer 10 shown in the circuit diagram is used to decrease the voltage, this effect occurs automatically, since the triangular voltage curve is "integrated" by the self-inductance of the primary winding of this transformer. The breakover frequency is determined by the following factors: the capacitance of the capacitor 5-7, the transmission current between its assignments or the leakage resistance of its dielectric, the level of the ignition voltage of the gas discharge tube. For a given weight of the radioactive isotope, the transmission current depends on the load resistance, which is formed by the leakage resistance between the coverings, i.e. H. in other words, from the resistor in parallel with the capacitor. It also depends on the activity properties of the selected isotope. So you can either determine the frequency of the discharge per microgram of a certain isotope or, conversely, determine the weight of a certain isotope, which is necessary to achieve a desired flip frequency if the other conditions are assumed to be the same. In order to have an indication of the low weight of the isotope, which in the majority of cases is sufficient for the practical implementation of the invention, it should be given as an example that the tilt frequency 1 with one microgram of silicon 31, with a capacity of IOpF and one Ignition voltage of 100 V. In practical use, however, the sweep frequency determined in this way is subject to fluctuations when the ambient temperature changes. As is well known, the product of the volume and pressure of the plasma in the flask changes linearly with temperature. There can of course only be relatively limited temperature fluctuations, e.g. B. from -40 to - | -110oC. However, capacitors are known in the art, the dielectric of which has a negative and approximately linear temperature coefficient. It is therefore provided as an additional feature of the invention to use the presence of such capacitors to compensate for the temperature-induced fluctuations in the frequency fluctuation by connecting such a capacitor with an appropriately selected negative temperature coefficient in parallel to the tilt capacitor of the gas discharge tube. This can be done by connecting this compensating capacitor outside the piston between bushings, which are branched off from the assignments 5 and 7 for this purpose, or by inserting the compensating capacitor calculated beforehand into the interior of the piston and connecting it in the same way, if this is the case spatially is possible due to the dimensions of the piston and the compensation capacitor. In other respects it often appears advantageous to be able to change the frequency of the sweep to facilitate practical application. This can also be done in a very simple manner in that an auxiliary capacitor is connected in parallel to the tilt capacitor enclosed in the flask, with corresponding bushings being branched off from the assignments 5 and 7 for this purpose. However, it is preferable here to provide only one adjustment option, but no control option within large limits, since the efficiency of the arrangement is greatly reduced if it always has to work with a predominant external capacitance, since the transfer and accumulation of electrical charges continues to must be carried out solely by the capacitance located inside the tube. All possibilities for the practical application of the invention emerge from the above description. A control grid can also be attached to modulate the amplitude of the voltage generated. Patent claims: 1. Gas discharge tube for generating tilting vibrations by discharges via the plasma inside the tube bulb with a voltage between the cathode and the anode, characterized in that the latter is lower than the burning voltage that in a known manner in the tube bulb at least one capacitor is included, whose one coating (7) is in contact with the plasma and has no fixed electrical potential in a manner known per se, while the other coating (5) is isolated from the plasma and electrically connected to the cathode (2) in a manner known per se is connected, and that a known radiation source (6) for beta particles is arranged in the capacitor, so that a permanent transfer of the electrical charges from the occupancy of the capacitor connected to the cathode to the occupancy in contact with the plasma is effected. 2. Gas discharge tube according to claim 1, characterized in that the radiation source for Beta particles consist of a radio-isotope or the salt of a radio-isotope, which on the one Assignment of the capacitor is applied. 3. Gas discharge tube according to claim 2, characterized in that the source for beta rays consists of silicon 31 or thallium 204 or a salt of these radio-isotopes.