DE1047951B - Circuit arrangement for switching on and off gas discharge tubes - Google Patents

Description

As is known, gas discharge tubes can be ignited and extinguished by giving them impulses suitable polarity, which supplies the voltage applied to the tube for the purpose of ignition via the ignition voltage raise it or lower it below the extinguishing voltage for the purpose of extinguishing. Ais erase voltage; is in In this context, the voltage limit is understood, below which a burning limit is understood Tube is deleted. If you want to turn on a gas discharge tube by supplying it with pulses. the Ignite and extinguish the same place, for example at the anode, so it is according to the known Circuits required to use pulses of different polarity when feeding on the anode namely positive impulses for ignition and negative impulses for extinguishing. This use of pulses different polarity is noticeable disadvantageously in many cases, since this is a special one Means effort with the pulse generator.

There are also known circuit arrangements for gas discharge tubes with two or more cathodes, in which pulses of the same polarity in each case at the same point via capacitors in the -over The circuit leading to the tube can be introduced in order to maintain the discharge path. Depending on the polarity, such a pulse ignites or extinguishes a discharge path, with im in the latter case, the operating voltage causes the ignition of the following discharge path ". But with that now the previous route does not continue to burn or is re-ignited, must be in the individual Cathode circuits delay elements, for example i? C elements, can be arranged. Through the during the When the capacitor charged in the discharge path burns, the testicular potential is raised in such a way that that prevents further burning or reignition when the following discharge path is ignited will. These i? C elements are therefore known for the deletion of the discharge path in the Circuit arrangements and thus absolutely necessary for their proper operation.

In contrast, the invention is concerned with the task of allowing the ignition and extinguishing of a gas discharge tube only with the aid of pulses of the same polarity, which are fed via a differentiating element at the same point in the circuit leading through the tube. This problem is solved according to the invention in that the time constants of the differentiating element, which are decisive when the tube is ignited and extinguished, and the pulse duration are coordinated in such a way that, as a result of the differentiation of the pulses of the ignition pulse supplied to the extinguished tube, the compensating pre-circuit arrangement is created
for igniting and extinguishing
of gas discharge tubes

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dipl.-Ing. Günther Willibald,

Holloman AFB / NM {V. St. A.),

and Dipl.-Ing, Siegfried Zahlhaas, Munich,

have been named as inventors

The voltage on the ignited tube does not occur or only for a shorter time than the deionization time below 'the erase voltage drops during the fed through the back flange of one of the ignited tubes further impulse resulting equalizing process the voltage on the tube over the deionization cell also below the erasing voltage -hold, so that the tube is erased again.

The differentiation can be made with a capacitor or an inductance.

In Fig. 1, a circuit arrangement is shown in which a capacitor is used.

Fig. 2 shows the corresponding circuit with an inductance.

3 shows, in the form of a diagram, the electrical processes taking place in such circuits again.

The circuit diagram according to FIG. 1 shows a gas discharge tube R which is connected to the battery voltage Uo via an anode resistor WL and a cathode resistor WI . This battery voltage Uo is below the ignition voltage Us of the tube, but still above its operating voltage Ub. A pulse generator PG is connected to the anode of the tube via a capacitor C and delivers positive pulses. Such a pulse is differentiated by the circuit, since the capacitor C in connection with the resistors W1 and W2 and the internal resistance of the tube R has a differentiating effect

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forms. The internal resistance of the battery supplying the voltage Uo is assumed here to be negligibly small. Depending on whether the tube is ignited or extinguished, the differentiating element has a different time constant. When the tube is extinguished, the differentiating element has the time constant Tl resulting from the capacitor C and the resistor Wl ; when the tube is ignited, however, the time constant from the capacitor C and the parallel connection of the resistor Wl with the sum of the resistance W2 and the internal resistance of the tube egg? resulting smaller time constant T 2.

The function of the circuit will now be explained with the aid of the diagram in FIG. 3. The upper part of the diagram shows the course of the voltage Ua, measured from the anode of the tube R to earth. A state in which the tube has been extinguished is assumed. As a result, the battery voltage Uo is applied to the anode. At time ti , the pulse Pz shown in the lower part of the diagram begins, which is supposed to ignite the tube. This impulse is initially added with its full height to the voltage Uo prevailing at the anode. It is differentiated by the difference element (time constant Tl) consisting of capacitor C and anode resistor Wl , since the tube initially remains in the extinguished state. This differentiation process lasts as long as the ionization time of the tube lasts, namely until time t2. The time constant Tl = C, which is decisive for the period between ti and t2, is so great that the voltage at the anode of the tube R only drops insignificantly during this period. With the onset of ignition at time t2, the resistance of the differentiating element is the parallel connection of the resistor Wl and the sum of the resistor W2 and the internal resistance of the tube R. The time constant T 2 , which is now relevant, is therefore much smaller, so that the voltage at the anode R. drops rapidly until the trailing edge of the pulse Pz occurs at time i3. This shifts the voltage Ua abruptly by the amount of the pulse voltage, so that the voltage Ua does not continue to decrease after the dash-dotted line Ll , but is suddenly lowered below the erase voltage Ul. As long as the tube is still in the ionized state, the previously effective differentiating element, consisting of capacitor C _1, resistors W1 and W 2 and the internal resistance of tube R, is decisive for the subsequent equalization process. According to the time constant T 2 of this differentiating element, the voltage Ua thus tends towards the burning voltage Ub , which is slightly above the extinguishing voltage Ul , since a certain current flows through the tube in this state.

As is apparent from the diagram, is below the erase voltage Ul during the period ta of the last-described compensation process. This period of time is shorter than the deionization time of the tube (which is drawn in after the second pulse and denoted by te ). As a result, the tube cannot be erased by the trailing edge of the Pz pulse. The pulse Pz thus caused the tube to ignite, initially for a long time.

At time f4, the second pulse Pl begins, which in the example chosen is of the same duration as the pulse Pz . However, it should be pointed out here that this is not absolutely necessary. This is discussed in more detail below.

In contrast to the pulse Pz , the pulse Pl is added to the running voltage Ub that prevails at the anode of the tube R in this state. The pulse is immediately differentiated by the differentiator, consisting of capacitor C, resistors Wl and W2 and the internal resistance of tube R. This equalizing process running with the time constant T 2 is interrupted at time f 5 by the trailing edge of the pulse Pl (continued by the dash-dotted line L2), which shifts the voltage Ua by the amount of the pulse voltage. Since the base of the pulse Pl was based on the running voltage Ub , this time (in contrast to the pulse Pz) the back flank of the pulse Pl reached a much lower voltage below the extinguishing voltage Ul , to which a "same" voltage again time constant T2 certain balancing operation is connected. however, as this compensation process starting from a voltage which is considerably below the erase voltage Ul, the voltage Ua can no longer within the deionization reach the erase voltage Ul, so that the tube is extinguished. the deionization time te is following the time 15, the trailing edge of the pulse Pl, is entered. As can be seen, the equalizing process following the trailing edge of the pulse Pl does not yet reach the extinction voltage Ul within the period te , so that, as I said, the tube is extinguished.

When the tube goes out, i.e. after the deionization time te has elapsed, another time constant is decisive for the equalization process, namely the time constant T1 (the equalization process determined by the original time constant is continued by the dash-dotted line L 3). According to this time constant Tl , the voltage Ua tends to return to the initial state, namely the battery voltage Uo, when the tube is extinguished. (In order to shorten the drawing, a jump point has been drawn in in this equalization process.) The circuit has now resumed its initial state and the tube can be re-ignited by a pulse.

From the above it follows that with the help of pulses of the same polarity, the at the same point, namely at the anode of a gas discharge tube, they are ignited and can be deleted. The pulses must have at least such a distance that the subsequent balancing processes have practically subsided.

The same length of the pulses selected in the embodiment discussed above is as already mentioned, not a mandatory requirement. The duration of the impulses only has to be chosen so that that the equalizing process following the trailing edge of a pulse igniting the tube the voltage at the tube does not drop below the erasing voltage or only for a shorter time than the deionization time. On the other hand, the equalizing process, which is carried out on the trailing edge of one of the ignited tubes Pulse, the voltage on the tube beyond the deionization time below hold the extinguishing voltage.

If it is possible to use impulses of different duration, it will be useful to use the The shorter pulse ignites the tube and the longer one extinguishes it. In this case it is possible to use a Lowering of the voltage on the tube with the trailing edge of the igniting pulse below the extinguishing voltage

to prevent iiung Ul at all. This offers the advantage of greater security.

In the exemplary embodiment discussed above, the time constant T 1 that is decisive when the tube is extinguished is large compared to the pulse duration and is appropriately an order of magnitude higher than the time constant Γ2 that is decisive when the tube is ignited. This has the advantage that the equalizing process that begins with the ignition of the tube at time * 2 (FIG. 3) follows practically the full voltage achieved by the leading edge of the igniting pulse Pz , so that a correspondingly low voltage Lowering takes place through the trailing edge of the same pulse below the erase voltage Ul .

FIG. 2 shows an exemplary embodiment corresponding to the circuit according to FIG. 1, in which the pulse generator PG feeds the pulses supplied by it into the circuit of the tube by means of a transformer U. The time constants relevant for the extinguished and ignited state of the tube in this circuit are the time constant of the transformer itself and the time constant of the transformer loaded with resistors W1, W 2 and the internal resistance of the tube R. The diagram shown in FIG. 3 also applies to this circuit. Reference can therefore be made to the explanations given for this figure in order to understand the mode of operation of the circuit according to FIG.

Claims (4)

Patent claims: 1. Circuit arrangement for igniting and extinguishing a gas discharge tube with the aid of Pulses of the same polarity, which are transmitted via a differentiating element at the same point in the be fed through the tube leading circuit, characterized in that the ignited and erased tube, the time constants of the differentiating element and the pulse duration are decisive are coordinated in such a way that as a result of the differentiation of the pulses by the trailing edge of an ignition pulse supplied to the extinguished tube, which balances the voltage at the now ignited tube The tube does not fall below the extinguishing voltage or only for a shorter time than the deionization time, during the further pulse applied by the trailing edge of one of the ignited tubes resulting equalization process the voltage on the tube beyond the deionization time holds below the erasing voltage, so that the tube is erased again. 2. Circuit arrangement according to claim 1, characterized in that the extinguished tube The resulting time constant is large compared to the pulse duration and about an order of magnitude is higher than the decisive time constant when the tube is ignited. 3. Circuit arrangement according to claims 1 and 2, characterized in that the pulses be fed via a capacitor into the circuit leading through the tube, wherein the differentiator when the tube is extinguished, one from this capacitor and one in the circuit lying resistance, with an ignited tube on the other hand one from the capacitor and the parallel connection of the mentioned resistance with the internal resistance of the tube and another to the tube in series resistance has the resulting time constant. 4. Circuit arrangement according to claims 1 and 2, characterized in that the pulses be fed via a transformer into the circuit leading through the tube, whereby when the tube is extinguished, the differentiating element has the same time constant as the transformer itself, when the tube is ignited Tube, on the other hand, is that of the one with the series connection of the one that leads over the tube Electric circuit lying resistances loaded transformer. Considered publications:
U.S. Patents Nos. 2,624,866, 2,638,564,
636145, 2 645 742, 2 642 548, 2 651740, 2 617 066. 1 sheet of drawings © 809 727/403 12.58