DE1242720B - Quickly disconnectable direct current supply circuit for a discharge tube - Google Patents

Description

Quickly disconnectable direct current supply circuit for a discharge tube In DC supply circuits for one or more discharge tubes, for example for the modulator tube and the last stage of the modulation amplifier of a high frequency transmitter, it is necessary that the DC voltage supplied by a supply device (Supply voltage) can be switched off quickly when in one of the above highly stressed tubes cause a flashover between the anode and another tube electrode occurred and struck an arc.

But even if the supply voltage is switched off very quickly As is well known, damage can occur within a tube of the high-frequency news transmitter come because they are in the energy storage of the filter chain, namely the filter capacitors and the smoothing choke, stored energy is retained even after the supply voltage has been switched off discharges via the ignited arc. Tube protection circuits have therefore been developed in those of the discharge path of the tube to be protected one with an ignition electrode equipped gas discharge tube, a so-called ignitron, is connected in parallel. Due to the overcurrent flowing in the event of a flashover of the pipe to be protected is in such a circuit at a resistor in the discharge circuit caused a voltage drop of sufficient magnitude, which the ignition electrode is supplied and with the help of an ignition spark triggered at this electrode Makes discharge path of the Ignitron conductive. This discharge path, which as a result of the gas ionization that has occurred has only a low internal resistance, closes practically the arc ignited in the tube to be protected is short and enlarged the overcurrent drawn from the DC power supply. Through this overcurrent, a so-called overcurrent relay is triggered, which one the disconnection of the supply voltage is derived.

Protection circuits of this type generally work satisfactorily with transmission systems up to medium powers, however, difficulties arise with very high power transmitters and with the use of energy storage systems very much large capacity in the sieve chain for the rectified voltage. Similar difficulties can also arise if the supply device is grid-controlled gas discharge tubes and if from the output of the supply device, its terminals are not through an additional capacity are bridged, immediately a large inductor Inductance is fed. The inductance of this coil then already pulls initiated shutdown of the supply voltage, which is on the grid side caused by the anode-cathode route for some time current, so that the Effectiveness of the blocking is delayed. More difficulties can arise as well result if within the sieve chain between the inductance and a capacitance Energy fluctuations occur, d. H. mutual charges and discharges between the inductance and the capacitance with the resonance frequency of the through these two Elements formed in a series circle, the effect of which is to extinguish the arc is delayed in the pipe to be protected.

To prevent oscillations and overvoltages in inductances, their Power is suddenly turned off is also part of the tasks involved with a familiar Facility to be solved (German patent specification 892 336). There is the useful resistance a tube, the inductances and capacitances (i.e. a parallel resonant circuit) lie in parallel, a dry rectifier connected in parallel. When switching off the With the anode current, a short but very strong current surge flows through the dry rectifier, which must therefore be dimensioned for correspondingly large currents. Besides, the Arrangement to be used only for damping parallel resonant circuits, because on one freely oscillating series resonant circuit only have such low voltages that a parallel-connected Dry rectifier remains ineffective.

In relation to the state of the art, it should also be mentioned that it is already known is, in a protective circuit for transmitter tubes, whose anode supply voltage in the event of flashovers or short circuits through a relay switched off at the same time with the disconnection of the anode supply voltage, the calming capacitor for the Anode supply voltage and possibly also a modulation capacitor located in the anode circuit via a spark gap with ignition electrode or a controllable converter discharged (German patent specification 885 433).

This known arrangement or the previously described (German Patent Specification 892 336), i.e. through the low-resistance bridging of the energy storage device by an ignited gas discharge tube or a dry rectifier the strong decay processes are not damped quickly enough, so that, for example in practical tests a decay current of up to a duration of 2 seconds flowed over the throttle and the ignited gas discharge tube. This time is in view the required rapid restart of the transmitter for far too long. aside from that there were still difficulties with very high performance transmitters, where because of the high operating voltages and the large stored energies are two ignitable Gas discharge tubes had to be used in series, of which often one because of the current reversal already extinguished before the energy decayed to a sufficient extent was.

In addition, there is already a circuit arrangement for avoiding destruction known from transmission tubes in the event of a flashover, in which the anode voltage in a flashover is automatically switched off by a fast-acting protective circuit in which an arc continues to burn between the grid and the cathode, the is fed by the current source for the negative grid voltage, after switching off the anode voltage through a rectifier polarized in this way, e.g. B. a dry rectifier, in the grid lead prevents the normal grid current from passing through becomes (German patent specification 879 263).

In the known arrangement, a rectifier element was already used used in connection with a tube protection circuit, but this element served in the known arrangement for solving another problem, in particular not for damping the "wrong" current direction by using a for this current direction Effectiveness brought about, interacting with the rectifier element resistance element.

There is also a circuit for shortening business interruptions in the case of tube flashovers by means of an interposed choke-capacitor element known by which the discharge oscillation triggered in the event of a short circuit causes the arc extinguishes in connection with a special throttle arranged in series for prevention of immediate re-ignition (German patent application S 23011, published on 10.7.1952).

With this arrangement, rapid arc extinction was carried out another mechanism of action, namely through the conscious induction of a Decay process, aimed at, the arc should extinguish when the Voltage goes through zero. It has been shown that this effect is associated with uncertainties is afflicted and, especially in the case of transmitters with a very high output, does not reach the desired level Goals leads.

The invention is based on the problem mentioned in the case of a DC power supply circuit that can be switched off quickly, the specified Art to fix and the mentioned decay processes within the sieve chain quickly to attenuate and, if necessary, a delay in the blocking of the AC rectifier to avoid.

The object is achieved by the invention specified in claim 1 solved.

In the circuit according to the invention, the phenomenon is used that both in the aforementioned decay processes or energy oscillations as well with the prolonged current draw from the AC rectifier by a choke Reversals of the normal operating voltages on the storage elements or on the Output terminals of the AC rectifier occur. As a result, this Elements or terminals damping ohmic resistors connected in parallel or in series which in normal operation are ineffective due to unilaterally conductive elements are made. By reversing the direction of tension in the exceptional case, if If a flashover has occurred in the pipe to be protected, these become damping Resistances, however, are effective due to the aforementioned elements that are conductive on one side brought, so that there is a strong damping for in the "wrong" current direction flowing Currents results.

Further developments of the invention are given in the subclaims.

The drawing shows, in simplified form, a DC power supply circuit which can be quickly switched off for the tubes 1 and 2 of the last stage of a modulation amplifier and the modulator tube 5 in the last stage of a high-frequency message transmitter. The low-frequency output of the tube stages 1 and 2 is fed to the anode of the modulator tube 5 via the modulation transformer 3 from the secondary side thereof. The further details of the modulation amplifier and the high-frequency amplifier train are not shown, since these can be designed in any known manner. The modulator tube 5 receives its anode DC voltage via the modulation choke 4. In the circuit shown, this can either be connected directly to the positive pole of the AC rectifier 6 via the connections a and b drawn with broken lines or indirectly via the filter choke ?. It is assumed that one or more grid-controlled gas discharge tubes are present within the AC rectifier, which rectify one or more phases of the mains alternating current and can be quickly blocked by voltage control on their grid.

You can see that the sieve throttle? and the capacitor 8 is a normal one Form a sieve chain to filter out the remaining alternating current components. The tubes 1 and 2 get their anode voltage via the filter choke? and the center tap the primary side of the modulation transformer 3. The earth connection of the secondary side of the modulation transformer 3 is routed via the modulation capacitor 9. in the normal operating condition form the filter throttle 7, the modulation throttle 4, the Filter capacitor 8 and the modulation capacitor 9 charged energy storage, their storage energy in the event of a fault consumed as quickly as possible must be, without thereby destroying the overturned tube or a inadmissible extension of the fault time.

For the additional short circuit to weaken an arc ignited in the tube 5, the circuit shown contains the series connection of two ignitable gas discharge tubes 10 and 11. The arrangement is such that the ignitable gas discharge tube 10 is automatically ignited when the gas discharge tube 11 is ignited. This takes place via the resistor 16 located in the discharge circuit of the tube 11, from which the ignition voltage of the ignition electrode of the tube 10 is supplied via the gas discharge tube 13 acting as a voltage wave and the ohmic resistor 12 acting as a current limiter. The gas discharge tube 11 is ignited by the voltage drop across the resistor 17 of the overcurrent flowing to the earth connection. A current-limiting resistor 15 and a gas discharge tube 14 serving as a voltage threshold are also connected into the ignition pin line of the tube 11. In addition, the excitation voltage for the overcurrent relay 18 is branched off from the resistor 17, which responds with the ignition of the two gas discharge tubes 10 and 11 and initiates the blocking of the valves within the rectifier 6.

To dampen the decay processes of the series resonant circuit, which is formed by the inductance of the secondary side of the modulation transformer 3 and the capacitance of the capacitor 9, the series circuit of the ohmic resistor 19 and the one-sided conductive element 20 is connected in parallel to the capacitor 9. While at the normal operating voltage on the capacitor 9, the unilaterally conductive element 20 prevents a current flow through the resistor 19, when the voltage on the capacitor 9 is reversed, the element 20 becomes conductive as a result of a decay process, and a strong current flows through the resistor 19, so that the Build-up of a "wrong" voltage on the capacitor 9 and thus its charging in the opposite direction is prevented. This decay process is therefore effectively attenuated in the first half-cycle when a counter-voltage tries to build up.

In the same way, decay processes of the series circles from the inductance of the filter inductor 7 and the capacitance of the storage capacitor 8 by the series connection of the resistor which is parallel to the storage capacitor 21 and the one-sided conductive element 22 attenuated. Similarly, will a current reversal for the choke? by connecting the ohmic resistor in parallel 25 prevented with the one-sided conductive element 26. While the normal Consumer current flows through the element 26 and in it only a low resistance has to be overcome, a current would have to be in the opposite direction as it does during decay processes can occur, flow through the damping resistor 25, since the unilaterally conductive Element 26 is not conductive for this wrong direction current.

When the modulation choke 4 is connected to the AC rectifier 6 is connected via the drawn connection a, results in the large inductance this choke when the rectifier 6 is switched off the tendency to the existing To maintain current flow for some time. The existing in the rectifier 6 Valves that are blocked from their grille side then continue to operate for some time current through its cathode-anode path, so that the blocking is delayed. For This current is the electromotive force but in the throttle 4, so that reverses the voltage at the terminals of the rectifier 6. For this tension is the series connection of the ohmic resistor 23 with the one-sided conductive element 24 but permeable, so that the current drawn by the choke 4 now passes through the series circuit 23, 24 finds a conductive current path, whereby those located in the rectifier 6 Valves are relieved of this flow and can therefore be quickly blocked.

The combinations of damping resistors designed according to the invention with unilaterally conductive elements have compared to the known arrangements at where the energy storage is discharged via a controllable converter or a voltage reversal across them by connecting a dry rectifier in parallel is prevented, the advantage that by the damping effect of the resistors rapid decay of the decay processes is achieved and that the one-sided conductive elements can be dimensioned weaker, because they are only significantly smaller peak currents are loaded.

With the combinations designed according to the invention practical tests on a large transmitter with 300 kW output power cause quick and safe locking in the event of flashovers in the power amplifier tubes, without damaging the tubes and without them overturning The interruptions in operation caused were noticeable at all. A special Improvement in operation resulted when the modulation reactor 4 directly to the output of the Rectifier 6 was connected.

Claims (1)

Claims: 1. Quickly disconnectable direct current supply circuit for a discharge tube with filter means between the discharge tube and the DC voltage source, each energy storage device of the filter means being assigned a protective circuit at which oscillations or overvoltages can arise when the DC voltage source is switched off, characterized in that the protective circuit consists of the parallel connection of an ohmic resistor (25) and an element (26) which is conductive on one side in the normal current direction and which is in series with the energy store if it is a choke coil (7), and that the protective circuit consists of the There is a series connection of an ohmic resistor (21) and a one-sided conductive element (22) which is polarized against the normal charging voltage of the energy store and which is parallel to the energy store if it is a capacitor (8). 2. A circuit according to claim 1, characterized in that the output of the direct voltage source is connected in parallel with a series circuit of an ohmic resistor (23) and a one-sided conductive element (24) polarized against the normal output voltage of the direct voltage source. 3. A circuit according to claim 2, characterized in that the DC voltage source contains a controllable AC valve rectifier (6) which is blocked in the event of a flashover in the discharge tube within the current half cycle of the AC voltage. 4. A circuit according to claim 3, characterized by its use in connection with the modulator stage (5) of a message transmitter with direct connection of the modulation choke (4) to the output of the AC valve rectifier which is not capacitively bridged to a significant extent. 5. A circuit according to claim 3 or 4, characterized in that the modulation capacitor (9) lying in series with the secondary winding of the modulation transformer (3) not loaded with direct current is a series circuit of an ohmic resistor (19) and one against the normal charging voltage of the modulation capacitor polarized one-sided conductive element (20) is connected in parallel. Documents considered: German Patent No. 892 336; Patent No. 8786 of the Office for Inventions and Patents in the Soviet zone of occupation in Germany.