BE410154A - - Google Patents

Description

       

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  DESCRIPTIVE MEMORY filed in support of a patent application BERLIN GRUNEWALD (Germany)
DEVICE INTENDED TO CONTROL THE DISCHARGE OF A GAS OR VAPOR IN A CHAMBER OF
SHOCK
The subject of the invention is a device intended to control the discharge of a gas or a vapor in an electric gas discharge chamber, for example in a current rectifier, in particular a metal steam rectifier, by means of high frequency oscillations, said device consisting in placing in front of the anode of a gas discharge, in the direction of the cathode, a diaphragm which reduces the passage section available for the discharge and at the same time delimits , in the discharge chamber, a separate chamber which surrounds the anode.

   When the intensity of the current of the discharge increases to a certain value, it

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 in said chamber a depletion of positive ions. As a result, high frequency oscillations arise in the space between the node and the diaphragm, the voltages of which take on a large amplitude and are applied, at the time chosen for ignition, to discharge control devices and control discharge in any suitable manner.



   It is particularly advantageous to use the aforementioned device, intended to produce high-frequency oscillations, in combination with a device intended to control the discharge of a gas or a vapor in an electric discharge chamber with an electrode. barrier, device in which the discharge is controlled in such a way that at the moment chosen for ignition, positive ions are brought into the vicinity of the barrier electrode, in sufficient quantity so that the field created by the charge of the barrier electrode negative with respect to the cathode, or with respect to the ionized gas atmosphere which surrounds it and which surrounds the various parts of the barrier electrode, either destroying and allowing a discharge towards the main anodes to originate.

   The necessary positive ions are produced by the high frequency oscillations which the aforementioned device according to the invention gives rise to.



   High frequency oscillations can be brought about - in a particularly simple way, by operating the auxiliary gas discharge in the same empty chamber as the main gas discharge to be controlled. It is of course also possible to use a special gas discharge vessel to generate the high frequency oscillations therein. In addition, the cathode, necessary for the gas discharge to be controlled, can be used simultaneously to supply the auxiliary discharge which gives rise to the high frequency oscillations.



   The attached drawing represents several examples of reali-

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 sation of the invention; on this drawing:
Figure 1 shows a connection mode in which the high frequency oscillations are produced in a particular discharge chamber and, once produced, are applied to the barrier electrode of a mercury vapor rectifier;
Figure 2 shows a connection mode in which high frequency oscillations are produced in the chamber. discharge to be checked itself,
FIG. 3 represents a connection mode in which the control of the gas discharge by the high frequency oscillations is effected by indirect means;

   
Fig. 4 shows a second embodiment, in which the high frequency oscillations are produced in a particular discharge chamber and, once produced, are used to energize an oscillating circuit which controls the initiation of the discharge;
Figure 5 shows a variation of Figure 4 consisting in the production of the high frequency oscillations in the main discharge chamber itself; FIG. 6 represents said oscillating circuit in isolation;
Figure 7 shows another embodiment of the oscillating circuit of Figure 6;
Fig. 8 shows a third embodiment of the oscillating circuit for controlling the discharge;

     andFigure 9 shows another embodiment in which the high frequency oscillations can be used to control the discharge.



   In figure 1, 1 is the empty chamber of a mercury vapor rectifier, 2 is the cathode and 3 are the anodes which enter it through the insulators 4. The anodes 3 are surrounded by tubes. of anode protection 5, in which the control grids 6 are insulated. The current is supplied to the

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 control grids by means of special insulators 7. In addition to the empty discharge chamber 1 proper, a second gas discharge chamber b is intended to generate high-frequency oscillations and in front of its anode 9 is interposed a diaphragm 10 The cathode is an incandescent cathode 11, heated in the usual way, for example by a battery 12.

   A choke coil 13 is interposed in the anode circuit. The auxiliary discharge chamber 8 is supplied by a direct current source.
14. When increasing the intensity of the current in the circuit formed by 14, 13, 9, 10 and 11, so that, in the chamber limited by the diaphragm 10 and in which the anode 9 is located, a depletion of ions occurs, a high frequency oscillation takes place in this chamber, due to the fact that the potential of the anode 9 undergoes high frequency oscillations with respect to its neighborhood and in particular with respect to the diaphragm
10. The same oscillations in the opposite direction to these potential oscillations occur passing through the choke coil 13.



   In order to initiate a discharge between the main anodes 3 and the cathode 2 of the rectifier 1, and consequently to control the gas discharge in the rectifier 1, it is carried out at least for a short period, at the time of ignition, the control grids 6 arranged opposite the main anodes 3 at one of the voltages which exist between the anode 9 and the diaphragm 10 or in the choke coil 13. For this purpose, the incandescent cathode 11 of the auxiliary discharge chamber 8 is connected by a conductive wire to the cathode 2 of the rectifier 1, while the anode 9 is connected alternately with one of the two control grids 6 through the intermediary of 'a switch 15 and wire inputs 7; the resistors 16 are interposed as usual in the gate circuits.

   The connection is effected by placing the arm 17 of the switch in alternate contact with one of the two pads 18, 19.



   Switch 15 can have the form @

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 rotary switch, for example a form similar to that of the distributor of the ignition device of an internal combustion engine. The switch is controlled by a motor 20, which is connected to the voltage of the AC winding of a transformer 21 supplying the rectifier, so that the motor 20 rotates in synchronism with the frequency of the supply network. alternating current which is, for example, 50 periods.



   In view of the high frequency and the high voltage of the oscillations produced, it suffices to provide for the closing of the current zones of luminescence in the switch 15, that is to say that the contact elements approach at a low rate. distance from each other and that this gap is crossed by the current, thanks to the voltage of the high frequency oscillations. This embodiment has the particular advantage of avoiding wear of the contacts and, consequently, of making it possible to achieve perfect switching by means of a device of small size and light construction.



   In the embodiment shown, the high frequency voltage is taken between the anode 9 and the cathode 11. But it is also possible to take it between the anode 9 and the diaphragm 10 or at both ends of the diaphragm. choke coil 13.



   In the embodiment of the. Figure 2, the auxiliary discharge chamber is constructed in conjunction with the discharge chamber 1 to be controlled. It consists of a piece of tube 22 through which enters, by means of an insulator 23, the conductive wire of the anode 9. An auxiliary discharge is therefore maintained, which gives rise to high frequency oscillations. desired and which starts from the voltage source 14, passes through the choke coil 13, the anode 9, the diaphragm 10 to arrive at the cathode 2 of the discharge chamber 'to be checked.

   The potential of the anode 9 therefore undergoes high frequency variations and is transmitted, exactly as in the embodiment of FIG. 1, alternately and

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 for a short period of time, to one of the two control gates 6 via the rotary switch 15.



   The timing of the ignition determined by the control grids 6 can be varied in various ways, for example by mechanically changing the position of the movable part of the switch 15 relative to the rotor of the control motor 20, or by shifting the phase of the field of the stator of the motor 20 with respect to that of the AC power supply network. It is evident that other modifications of the timing of ignition are also embodied in the principle of the invention.



   To switch off the main discharge chamber 1, it suffices to interrupt the high frequency discharge passing through the auxiliary discharge chamber 22 because, once the high frequency discharge has been interrupted, the main anodes 3 are no longer in operation. state of carrying out the priming, given that the control grids 6 which precede them prevent, by an appropriate method of construction, the main discharge from occurring.



   In certain particular cases, the high-frequency power borrowed from the anode 9 is insufficient to suppress the blocking action of the control gates 6. In this case, according to the invention, the devices are used. high frequency oscillations at. control of an auxiliary gas discharge tube which, in turn, controls the control grids themselves. FIG. 3 represents an exemplary embodiment of a connection device of this type.



   In the connection device of FIG. 3, the same numbers designate the same parts as in the previous figures.



   However, the control gates 6 are connected to a positive voltage via gas discharge zones, for example luminescent tubes 24. Said tubes 24 consist, for example, of small glass tubes, in which one has evacuated and which has been filled with a rare gas and in which are arranged, for example, one opposite the other, two electrodes 26 in the form of a plate.

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   ques. The rare gas pressure and the plate spacing have been chosen here such that the voltage of the auxiliary source 25 is insufficient to give rise to a discharge passing through the tubes 24 and hence obviously to the maintain.

   Each tube 24 has another electrode which can be placed inside the tube or externally surround the surface of said glass tube 24 in the form of a strip 27. The high frequency oscillations are applied to this external electrode 27, in passing through the switch 15, in the same way as the control gates 6 of the discharge chamber itself of Figures 1 and 2. The auxiliary discharge chamber 8 intended to generate the high oscillations frequency is constructed in the same way as in figure 1, and connected to the luminescent tubes 24. But the chamber intended for the production of the high frequency oscillations can also be placed inside the main discharge chamber, thus as shown in Figure 2.



   Figures 1 and 2 show embodiments in which the high frequency oscillations produced by means of the oscillator act on the barrier electrode itself, directly or indirectly. lfais it is also possible, a priori, without departing from the scope of the invention, to bring the high-frequency oscillations to a winding which surrounds the vacuum chamber, which should then be made of glass, in the vicinity of the or barrier electrodes. In addition, this high frequency winding can still be replaced by electrodes which surround the vacuum chamber, etc.



  However, in some cases the use of these special control devices such as windings, electrodes, etc., is not convenient. Therefore, according to another characteristic of the invention, the anode itself is used as a control agent. This is achieved by arranging the anode in such a way that it forms part of an oscillating circuit which is charged

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 at the time chosen, for ignition, by bringing a voltage to it at high frequency and thus ionizing the gases or steam between the anode and the barrier electrode placed in front of it, so that the anode can act through the barrier field created by the barrier electrode.

   This oscillating circuit must be arranged in such a way that, by its blocking action, it prevents high frequency energy supplied to the anode from passing into the alternating current network.



   Preferably, the oscillating circuit is formed by the anode and the metal parts of the chamber, which are in front of it, such as barrier grids, anode sockets, wire entries which. form capacitors, as well as a self-coil interposed in the anode circuit and which forms an inductance, so that a blocking or barrier capacitor prevents the normal operating voltage, which must reach the anode, d 'arrive at the metal parts of the chamber which are in front of the anode and such as the barrier grids, the anode sockets, the wire entries.



   The high frequency can be produced in any suitable manner. However, it is advantageous to employ an oscillator, as has already been described above.



   It is advantageous to bring the high frequency by a coupling in the manner of a transformer using the inductance of the oscillating circuit. In order to distribute the high-frequency oscillations over the various anodes, it is possible to provide a rotary switch with adjustable speed, the distribution contacts of which are arranged in the form of luminescent zones or similar devices not coming into effective mechanical contact.



   In Figures 4 to 8, 1 always designates the empty chamber of a mercury vapor rectifier, 2 the cathode and 3 the anodes which enter it through the insulators 4. The anodes 3 are surrounded by protective tubes 5 , in which the @

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 ment but who can be. In the anode circuit is interposed an inductor coil 107, the upper end of which furthest from the anode is connected via a blocking or barrier capacitor 124 with the electrode. barrier, or in this case, for example with the metal box 1.



  The choke coil 107 by its inductance and the capacitance constituting by their reciprocal action between the anode 3, the barrier electrode 6, the socket 5 of the anode and the input of wires 4 an oscillating circuit shown in isolation by FIG. 6, in which the capacitor 125 represents the blocking or blocking capacity, constituted by the anode and the metal parts which are in front of it.

   Once the frequency at which the ignition must be carried out has been chosen, it suffices simply to tune the choke coil 107 to the capacitance constituted by the anode 3 and its vicinity, so as to fulfill the condition with sufficient accuracy. expressed by the known formula: ce 2 = 1
LC
To start the anode, a high frequency close to the resonant frequency of said circuit is brought to the oscillating circuit. Consequently, the amplitude of the oscillations of the oscillating circuit does not stop increasing, so that the alternating voltage, at the capacitance of the oscillating circuit as well as between the anode 3 and the barrier electrode 6, also increases.

   As the gas or vapor lithosphere which is located between the barrier electrode 6 and the anode 3 permanently contains charge particles, in particular electrons, said electrons take a pendular motion under the influence of high frequency and after several high frequency oscillations, the amplitudes of their velocities keep increasing until they finally become sufficient to tone the neutral particles of gas or vapor which the electrons strike. When these ionization phenomena have taken on sufficient magnitude, the barrier electrode or its vicinity is enveloped in a sheath of positive ions, resulting in the rupture of the

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 barrier field that exists on the surface of the barrier electrode.



  As soon as this happens, the electrons can exit the main discharge chamber of the empty chamber 1 by passing through the barrier electrode 6 to the anode 3, which allows current to flow and discharge. to settle down. The high frequency necessary for the load of the oscillating circuit can also be produced by any means other than that which has been indicated above.



  As, as we know, the starting voltage necessary to trigger a discharge, between two electrodes arranged in a gaseous atmosphere, decreases from 106 periods per second for increasing values and as, for 108 periods per second it achieves significantly lower values than for lower frequencies, it is advantageous to use at least high frequencies of 106 to 108 periods per second. The application of the high frequency is advantageously done inductively, by means of a winding 126 coupled in the manner of a transformer with the choke coil 107.



   The high frequency is still produced by a special oscillator constructed in the same way as the oscillator in Figures 1 to 4.



   In order to control the discharge between one of the main anodes 3 and the cathode 2 of the rectifier 1, the windings 126 are brought for a short period, at the time chosen for ignition, to one of the voltages which exist between the anode 9 and the diaphragm 10 or in the choke coil 13. For this purpose, the incandescent cathode 11 of the discharge-auxiliary pulpit 8 is conductively connected to one of the ends of the windings 126 or 126 ', while the anode of 9 is connected alternately with the other of these two windings 126 or 126' through the intermediary of the switch 15. The connection is established by the alternating contact of the arm 17 of the switch with one of the two studs 18.19.



   In the embodiment shown, the voltage at high

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 The frequency is borrowed between the anode 9 and the cathode 11. But it is also possible to borrow it between the anode 9 and the diaphragm 10 or from both ends of the choke coil 13.



   In the embodiment of FIG. 5, the auxiliary discharge chamber is constructed in connection with the discharge chamber 1 to be controlled. It consists of a piece of tube 122 through which, by means of an insulator 123, the conducting wire of the anode 9 enters.



  An auxiliary discharge is therefore maintained, which gives rise to the desired high-frequency oscillations and which starts from the voltage source 14, passes through the choke coil 13, the anode 9, the diaphragm 10, to arrive at the cathode. 2 of the discharge chamber to be checked. The aperture of the diaphragm 10 should be calculated so that the high frequency oscillations already occur when the operating pressure of gas or vapor in the chamber is normal. The potential of the anode 9 therefore undergoes high frequency variations and is transmitted exactly as in the embodiment of FIG. 4, alternately and for a short period of time, to one of the two windings 126 by through the rotary switch 15.



   The timing of the ignition determined by the windings 126 can be varied in various ways, for example by mechanically changing the position of the movable part of the switch 15 relative to the rotor of the drive motor 20 or by shifting the phase of the field. of the stator of the motor 20 with respect to that of the AC power supply network. It is evident that other modifications of the timing of ignition are also included within the scope of the idea of the invention.



   In order to switch off the main discharge chamber 1, it suffices to interrupt the high frequency discharge passing through the auxiliary discharge chamber 122, because once the high frequency discharge is interrupted, the main anodes 3 are no longer available. state to perform priming.

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   In the embodiment shown in Fig. 7, the anode socket 5, mounted on the empty metal chamber 1, is isolated therefrom by means of an elongated insulator 127 and is connected with the end of the coil. choke 107 farthest from the anode via the blocking or barrier capacitor 124. The conductive wire passes through the wall of the chamber and is isolated therefrom by the wire entry, 128.



   In an oscillating circuit of this type, the capacitor therefore consists of the anode, the barrier grid and the anode socket.



   The embodiment described above can also be applied to glass tubes after having been judiciously modified.



   FIG. 8 represents another embodiment of the oscillating circuit, intended for tubes made of glass or any other insulating material. In this figure, 129 denotes the empty glass tube in which the anodes 3 are mounted in the usual manner. Each anode is surrounded by a sleeve 130 arranged inside the tube and carrying the barrier electrode 6. Outside the tube and opposite the barrier electrode 6, there is a metal sheath 131 which is connected with the end of the coil 127 furthest from the anode. The outer sheath 131, the socket of the anode 130, the barrier electrode 6 and the anode 3 then constitute the capacitance of the oscillating circuit which consists of several capacitors mounted in series, as well as is easy to understand without further explanation.



  It is advantageous to place the metal parts 130 and 131 in the immediate vicinity of the two faces of the glass wall, so that the capacitance of the capacitor constituted by the sheath 131, the glass wall forming the dielectric and the sleeve of the anode 130 is large compared to the capacity of the internal capacitor formed by the sleeve of the anode 130, the dielectric electrode and the anode 3, because, thanks to the distribution of the voltages which results from it, the ignition of discharge is thereby facilitated.



   In the event that a smaller capacity is sufficient, we can

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 remove the sleeve from the anode 130 and fix the barrier electrode 6 to the glass wall itself.



   However, if in the embodiments according to Figures 7 and 8, the existing capacity of the oscillating circuit is not sufficient, a shunt capacitor can be coupled to it as indicated in the figures.



   In the oscillating circuit described above, the blocking or barrier capacitor 124 is not needed, since there is no need to worry about rushing the normal running voltage to be transmitted to the anode, d Arrive at the anode sockets and the barrier electrode.



   The invention should not be considered as limited to the embodiments of the oscillating circuits indicated above, but all the oscillating circuits in which the anode is used in an equivalent manner as a control anode are embedded in the principle of l 'invention.



   In some cases, for example in the case of glass tubes with a cathode, an anode and a barrier grid between the cathode and the anode. it is advantageous to isolate the barrier electrode from the casing and to connect it to the cathode or to a negative voltage.



   In the embodiments shown in Figures 4 to 8, inductance 107 should be given a magnitude such that, referred to the frequency of the high-frequency oscillations, the inductance is at least approximately in resonance. series with the capacitance which originates between the anode and its vicinity, Gela means that # L = 1 / # C, L being the inductance, C, the aforementioned capacitance and #, the frequency in radians of the high frequency oscillations . The inductance L can in certain cases take very considerable values, which makes the construction more expensive. In addition, as the inductance increases, its influence on the characteristics of the operating current increases more and more.

   This can result in considerable voltage drops at the inductance

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 of the normal running current which, in turn, may have an unfavorable influence on the electrical operating conditions of the discharge chamber, in particular of the switching.



   This drawback can be avoided by constituting the inductive resistance in the conducting wire of the anode or of each anode by an oscillating circuit mounted in volaat. It is advantageous to grant in an oscillating circuit at least approximately on the frequency of the high frequency oscillations used for the control, that is to say that its natural frequency, determined mainly by its self induction and by its capacitance. that we have chosen, is substantially equal to the frequency of the high frequency oscillations. In the case where the flywheel-mounted oscillating circuit is tuned exactly to the frequency of the high-frequency oscillations, the resulting resistance of the oscillating circuit represents an ohmic resistance equal to L1, Ll being the inductive choke, C1 the capacity and r
C1r the ohmic resistance of the oscillating circuit.

   If it is desired that the oscillating circuit mounted in a flywheel represents an inductive resistance which is equal or approximately equal to 1 (C still being #C the capacitance between the anode and its vicinity), the circuit must be slightly shifted. oscillating on the frequency of the high frequency oscillations, that is, its actual frequency differs by a certain amount in the proper direction of the frequency of the high frequency oscillations. The characteristics of the oscillating circuit mounted while flying can be determined a priori in this way.

   However, in some cases, it is preferable to have the oscillating circuit so as to be able to tune it first to the high frequency oscillations (maxima), by adjusting its capacitor built in the form of a capacitor. variable (disc capacitor) and, consequently, to be able to bring it out of resonance until its resulting resistance represents an inductive resistance of the desired magnitude. Instead of the capacitor, one can also make the inductance variable, for example, in the form of

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 variometer. If necessary, the capacitance as well as the inductance can be adjustable.



   Thus, as has already been indicated, the best solution from the point of view of the magnitude of the inductance and the capacitance of the oscillating circuit mounted in a flywheel consists in establishing said oscillating circuit in such a way that, for the normal operating currents of the discharge chamber, it gives rise to a practically negligible drop in potential. In the case where high frequency oscillations with a frequency of 106 periods or greater are preferably used, the inductance can be formed by a few windings, if necessary by a single winding of wire, tube. or copper strip.

   In some special cases it is also advantageous to choose the frequency of the high frequency oscillations used in the control (that is to say to give it a relatively strong value) so that the oscillating circuit, or its self induction, have as little influence as possible on the characteristics of the normal operating current and give rise for normal operating currents to a drop in potential as low as possible.



   FIG. 9 represents an exemplary embodiment of an assembly of this type. It differs from the embodiment according to FIG. 4 only in that one does not insert inductors 107, 107 'in the conductive wire of the anodes 3, but indeed an oscillating circuit' mounted on a flywheel. The capacitance of this oscillating circuit formed in the form of a disk capacitor is designated by 127 and 127 ', so inductance by 128 and 128'.

   The oscillating circuit 127, 128 or 127 ', 128' is set up as indicated above or adjusted by means of the disk capacitor 127, 127 'so that it is tuned approximately to the frequency of the high frequency oscillations, but consti. however kills an inductive resistance which is equal or at least approximately equal to 1 / # C, C still being the capacitance between the anode and its vicinity and # the frequency in radians of the high frequency oscillations.

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   Blocking or through-blocking capacitors 124 and 124 'should be sized such that they practically form a short circuit for high frequency oscillations, so that they do not exert on the high frequency oscillations. equality to be established between the resulting resistance of the flywheel mounted oscillating circuit 127, 128 or 127 ', 128' and the capacitive resistance of the capacitance of the anode of 1 that an insignificant and practically inappreciable influence- #Cable .



    CLAIMS
1) A device intended to control the discharge of a gas or a vapor in a gas discharge chamber, in particular in a current rectifier, by means of high frequency oscillations, characterized in that, to produce the high frequency oscillations, a diaphragm is placed in front of the anode of an auxiliary discharge and in the direction of the cathode, and the intensity of the current of the auxiliary discharge is brought to values for them. - which there is a depletion of ions in the space between the anode and the diaphragm.


    

Claims (1)

2) A device according to claim 1, charac- terized in that the high-frequency oscillations are applied, at the time chosen for ignition and for a short period, to the control devices, for example to carrara electrodes. 3 j A device for controlling the discharge of a gas or a vapor in an electric gas discharge chamber, in particular in a current rectifier with a barrier electrode, in which, at the time selected for ignition, one brings to the vicinity of the barrier electrode forming a barrier without voltage variation, positive ions which have the effect of destroying the barrier field and are produced by means of high frequency oscillations, characterized in that, for produce the high frequency oscillations <Desc / Clms Page number 17> in the direction of the cathode and the intensity of the current of the auxiliary discharge is brought to values at which an ion depletion occurs in the space between the anode and the diaphragm, from which it follows that high frequency oscillations arise in the known manner. 4) A coupling device according to claim 1 and the following claims, characterized in that the auxiliary discharge zone which serves to give rise to the oscillations at one frequency is installed in the same empty chamber as the main discharge , the two discharges advantageously taking place towards the same cathode and the opening of the diaphragm placed in front of the oatnode is calculated so that the desired high-frequency oscillations already occur, when the operating pressure in the chamber is normal . 5) A coupling device according to claim 1 and the following claims, characterized in that an inductor coil is interposed in the anode circuit of the auxiliary discharge, coil on which the high oscillations are taken. frequency. 6) A coupling device according to claim 1 and the following claims, characterized in that pour.rpar- tir high frequency oscillations on the barrier electrode (s) forming a barrier to the discharge chamber to be controlled, we have provided a rotary switch with adjustable speed whose distribution contacts are constructed in the form of luminescent zones or other contact devices not coming into mechanical contact. 7) A coupling device according to claim 1 and the following claims, characterized in that the high frequency oscillations produced by the auxiliary discharge control other gas discharges which, in turn, act on the barrier electrodes which serve to control the main gas discharge. 8) A coupling device according to claim 7, charac- terized in that luminescent areas, for example <Desc / Clms Page number 18> Luminescent tubes are arranged in the control circuits for the main gas discharge, said zones normally not letting any current pass, but igniting when they are ionized by the high frequency oscillations. 9) A coupling device according to claims 7 and 8, characterized in that a switch distributes the high frequency oscillations on the luminescent areas in the various control circuits. 10) A device for controlling the discharge of a gas or a vapor, according to claim 3 and the following claims, characterized in that the anode forms part of the oscillating circuit which is charged , at the moment chosen for ignition, by the application of a high-frequency voltage corresponding in general to the resonant frequency of the oscillating circuit and that, therefore, the gas or vapor which is between the anode and the barrier electrode placed in front of it are ionized so that the anode can act through the barrier field created by the barrier electrode. II) A device according to claim 10 characterized in that the oscillating circuit which comprises the anode acting as a barrier electrode prevents the high frequency energy received by the anode from passing into the AC network. 12) A device according to claims 10 and 11, charac- terized in that the capacitance of the oscillating circuit is constituted by the anode and the metal parts which are in front of it, for example, the barrier electrode , the anode socket, the chamber wall and the line entry. 13) A device according to claims 10 and 11, charac- terized in that the oscillating circuit consists of the anode and the metal parts which are in front of it, for example, the anode. barrier electrode, the anode socket, the metal parts of the chamber and the input of capacitor-forming wires and a <Desc / Clms Page number 19> tance, a blocking or barrier capacitor capable of preventing the normal operating voltage which must be transmitted to the anode from reaching the metal parts of the chamber which are in front of the anode. 14) A device according to claim 10 and the following claims, characterized in that the anode is surrounded by a sleeve which carries the barrier electrode and which is insulated from the empty chamber in metal and that the socket of the anode is connected via a blocking or barrier capacitor to the end of the inductance furthest from the anoe, -said capacitor preventing the normal voltage of transmitted at the anode to reach the anode socket and the barrier electrode. 15) A device according to claim 10 and claims 11 to 13 and intended for vacuum discharge devices with a glass chamber, characterized in that a metal sheath is applied to the outer face of the chamber at the vicinity of the barrier electrode, said sheath preferably surrounding the entire periphery of the barrier electrode, and that this sheath is connected to the end which is furthest from the anode of the inductor interposed in the anode circuit. 16) A device according to claim 15, characterized in that the anode is surrounded by a metal sleeve carrying the barrier electrode and that this sleeve and the outer sheath apply closely against the walls of the glass cnambre. 17) A device according to claims 10 to 16, characterized in that the high frequency voltage of the oscillating circuit is transmitted inductively in the manner of a transformer, preferably to the choke coil . 18) A device for controlling a gas discharge according to claim 1 and the following claims, characterized in that a high frequency voltage of 106 to 108 periods per second is employed. <Desc / Clms Page number 20> 19) A device according to claims 10 to 18, charac- terized by the fact that in order to distribute the high frequency voltage over the various oscillating circuits, a rotary switch with adjustable phases and speeds is provided, the distribution contacts of which are provided. - tion are constructed in the form of luminescent zones or other contact devices not coming into mechanical contact and that this switch connects alternately and for short periods of time to the oscillator windings coupled in the manner of a transformer with the choke coils of the oscillating circuits. 20) A device according to claim 13 and the following claims, characterized in that the inductive resistance (#L) in the anode circuit is calculated so as to be at least approximately equal to the capacitive resistance (1 ) of the capacitance C between the anode and the metallic parts which #C are in ¯face of it (consequently L = 1). #VS 21) A device according to claim 13 and the following claims, characterized in that the inductive resistance interposed in the anode circuit consists of an oscillating circuit 128,127 mounted as a flywheel. 22) A device according to claim 21, characterized in that the oscillating circuit 128, 127 is approximately tuned to the frequency of the high frequency oscillations. 23) A device according to claim 21, characterized in that the oscillating circuit 128, 127 is arranged so as to be able to preferably be first tuned exactly to the high frequency oscillations (maxima) that it receives, by the adjustment of its capacitor 127 with variable capacitance and to be thus brought out of resonance until its resulting resistance represents an apparent inductive resistance generally equal to 1 #C expression in which C is the capacitance between the anode and the metal parts in front of it (in particular the barrier electrode). 24) A device according to claim 21 or one <Desc / Clms Page number 21> of the following ones, characterized in that the magnitude of the inductance 128 of the oscillating circuit 128, 127 is chosen so that the oscillating circuit 128, 127 does not give rise, for the normal operating current of the discharge chamber than at a practically negligible voltage drop. 25) A device according to claim 21 or to one of the following, characterized in that the inductance 128 of the oscillating circuit 128, 127 consists, when preferably employing high frequency oscillations with a frequency of 106 periods per second or more, in a few windings, preferably in a single copper wire, tube or tape. ABSTRACT A device intended to control the discharge of a gas or a vapor in a gas discharge chamber, in particular in a current rectifier, by means of high frequency oscillations, characterized in that, to produce the oscillations at high frequency, a diaphragm is placed in front of the anode of an auxiliary discharge and in the direction of the cathode, and the current intensity of the auxiliary discharge is brought to values at which ion depletion occurs in the space between the anode and the diaphragm.