DE1171090B - Device for terminating a spark gap containing only two electrodes to trigger the discharge of a storage capacitor via the spark gap - Google Patents

Description

Device for igniting a spark gap containing only two electrodes to trigger the discharge of a storage capacitor via the spark gap The task of igniting a diode at a given point in time occurs when spark gaps are ignited, both those that serve as switching means as well as even those whose purpose is to emit a light pulse. A spark gap of this type to ignite, one normally uses a third electrode or often even a plurality of electrodes' which are arranged along the two main electrodes around or between them or both. Between these auxiliary electrodes and the main electrodes, which cause the actual capacitor discharge or the switching process, an ignition pulse voltage is given which partially or completely bridges the gaps or the only gap between the two main electrodes, so that the main discharge can follow.

This conventional arrangement has the disadvantage that the ignition electrodes have to be adjusted, which makes such discharge lamps or spark gap systems complicated and expensive in terms of their construction. At the same time, however, there is another disadvantage, which is that the light emission of a spark is greater, the higher the distance of the spark and the number of ionized atoms for a given voltage and capacity of a discharge capacitor. This could be achieved by increasing the distance between the main electrodes and increasing the gas pressure, if this did not increase the ignition voltage at the same time, because in this case the previous spark gap systems are only able to force a flashover to a limited extent. May z. If, for example, the breakdown voltage of a spark gap is 10 kV at a given distance, it is generally only possible to lower this voltage to about 7 kV by using suitable ignition electrodes and ignition sparks. The correct setting of voltage, electrode spacing and gas pressure is then very critical, so that the triggering of the ignition remains very uncertain. If it were possible to continue to lower the voltage with the same gas pressure and electrode spacing, the efficiency of the spark, the ratio between light emission and electrical energy fed in, would increase considerably.

The object of the invention is to cause the ignition of a spark gap without the aid of ignition electrodes in such a way that the efficiency of the light emission and the reliability of the ignition initiation increase at the same time. The invention relates to a device for igniting a spark gap containing only two electrodes for triggering the discharge of a storage capacitor via the spark gap and is characterized in that part of the current conductor of the inherently low-inductance capacitor discharge circuit, which leads from the storage capacitor (5) to the spark gap (1), is ferritic Material is enclosed, which has a high initial capacity, but is already saturated with low excitation, and that to initiate the capacitor discharge an ignition pulse with a steep rising edge is fed directly to the two electrodes of the spark gap, for which the capacitor discharge circuit due to its high inductance through the ferritic material offers such a high inductive resistance that the ignition pulse leads to a sparkover in the spark gap, which initiates the discharge of the storage capacitor, while the high current flowing through the conductor causes the capacitor discharge ng generates such a high magnetic field around the conductor that the ferritic material surrounding the conductor is saturated and thus becomes ineffective for the inductance of the discharge circuit. '# G The invention is in the R i. 1 and 2 shown. The task is to discharge the discharge capacitor 5, charged from the charging unit 6 , in a high-current spark 2 by means of a low-induction discharge circuit 4 via the spark gap 1, the two electrodes of which are enclosed in the cylinder or the casing 3. In the context of the invention, some of the supply lines 4 are enclosed by ferritic rings or a ferritic cylinder, using a material with a very high initial blocking capability. There are materials available on the market today that have initial permeabilities between 2,000 and 10,000 . When such rings are pushed onto the supply line system, the inductance increases extremely strongly, e.g. B. from an amount of 0.1 uH, which may be the sole property of the supply line, to an amount of 50 / tH. A steeply rising voltage pulse is now applied to the electrode system for ignition. As a result of the high inductance of the ferritic rings, this ignition voltage pulse has a very high inductive resistance in the main discharge circuit, so that this ignition pulse triggers a sparkover between the two electrodes. This simultaneously initiates the discharge of the capacitor5 by the voltage pulse. For an extremely short time interval, for example 0.1 psec, the current of the main discharge now swells to a few hundred amperes and thus generates such a high magnetic field around the conductor 4 that the ferritic rings surrounding it are completely magnetically saturated and thus only still have an effective perineability of 1 , so that they are magnetically ineffective with regard to the effect on the inductance of the discharge circuit. The further course of the discharge of the capacitor 5 is therefore unimpeded, and the same peak currents are formed as if only the line 4 itself were present.

To the left of the dashed line A , the example of a pulse generator of conventional design is given, as it is useful for igniting such spark gap systems. The capacitor 11 is charged from a small auxiliary voltage unit 10. For the purpose of ignition, this capacitor is via a switching means 12 which, for. B. may consist of a spark gap, a thyratron or an electron tube or a contact, discharged into the primary winding 13 a of a small auxiliary transformer, the iron core of which is indicated by the reference numeral 13 b and which has the secondary winding 13 c. This secondary winding charges the auxiliary capacitor 14, which thus has reached the breakdown voltage of the auxiliary spark gap 16 within a few microseconds, depending on the design of the arrangement. The right electrode of this auxiliary spark gap 16 and the left plate of the capacitor 15 are expediently connected to the ground potential via the resistor 17. Then, in the normal case, before the pulse generator is triggered, the same voltage is present across the capacitor 15 that is also applied to the spark gap 1-1 itself before the ignition, while both electrodes of the auxiliary spark gap 16 are at ground potential. Immediately before the ignition, the voltage on the capacitor 14 rises until it has reached the ignition voltage of the auxiliary spark gap 16 . At this moment the two capacitors 14 and 15 are connected in series via the auxiliary spark gap 16 , so a steep voltage pulse appears at the spark gap 1-1 , the height of which results from the addition of the voltages on the two capacitors 14 and 15 . This voltage pulse leads to a spontaneous and safe ignition of the spark gap 1-1. The switching spark gap 16 can also advantageously be surrounded by a cylinder which tightly encloses the balls of this spark gap, as a result of which the spark in 16 is designed to rise particularly steeply. The switching spark gap 16 can also be filled in a known manner with a non-oxidizing gas such as nitrogen, so that it has a long service life without a tendency to oxidize.

Of course, it is also possible to use any other pulse generator in place of the one drawn to the left of line A, e.g. B. Marx voltage multiplier circuits or the like.

In the curve of FIG. 1 a, the ordinate of which is the discharge current I and the abscissa of which is the time 1 , the dashed curve indicates the course of the discharge current as it would be without the use of a ferritic material including a piece of line. When using the ferritic rings within the meaning of the invention, the current runs according to the solid curve. During a short start-up time to, the current is somewhat delayed up to point P. From there on, the further course of the curve is of the same shape as that without ferritic rings. Depending on the discharge system, the time to results from a metrological point of view of about 5 to 10 nanoseconds and is negligibly small for most switching purposes. But you can also correct this negligible influence in a known manner by suitable pre-delay and other circuit measurement elements, so that, for. B. the position of the maximum of the current is temporally where it would be found without the rings. For this one would z. B. have to train the intrinsic delay time of the circuit to be particularly small, so that one has a kind of time specification.

Without being restricted to this measure, FIG. 1 b shows a circuit arrangement that uses the Marx circuit known per se. In this case, a number of auxiliary capacitors, shown as 9a, 9b, 9c, 9d , are drawn from the voltage across the electrodes 1-1 via the auxiliary resistors 8 a, 8 b, 8 c, 8 d, 8e, 8f, 8g, 8h, 8i , 9e, charged. Chokes can of course also be used instead of the resistors 8 a to 8 i. The capacitors can now be switched in series through the auxiliary spark gaps 16a, 16b, 16c, 16d, 16e , the start being effected by a switching device which is designated by the reference symbol 12a. If, according to this figure, for. B. used a thyratron or an electron tube as a switching means, you can cause the start of the entire spark gap arrangement to a few nanoseconds in a known manner with almost no inertia, so that the spark gap system is ignited without the aid of an external voltage. By the switching measure of the F i g. 1 b one avoids switching on the slower pulse transformers.

When using a thyratron or an electron tube as a switch 12a of the Gitterableitwiderstand 12 b and the coupling capacitor 12 c and the input capacitor 12 e-known with the bleeder resistor 12d switching means. The charging resistor 12g and the filter capacitor 121 keep the cathode of the tube 12a at a potential that is constant over time.

One embodiment of the invention in removable lamps is shown in FIG . 2 The spark gap electrode system 11 rests on shafts la, the implementation is with the insulator lb hergesteUt, and the mounting plates are listed ld at position 1 and c. The spark gap is now enclosed by a transparent cylinder 3 , which is pressed together by means of retaining bolts 3 a between the mounting plates 1 c and 1 d with the aid of SiEkonrings 3 b. The feed system of this discharge occurs from the capacitor 5 via the feed line 4 with a portion of the supply line, as drawn in the figure, either cylindrical rings 7 a or 7 b or c enclosed by an elongated cylindrical piece. 7 Of course, rectangular or other cross-sections can also be used in place of the ferritic locking pieces shown here as round. The enclosing pieces could also have a gap. However, it is particularly advantageous to use individual rings according to FIG. 7a or 7b because a voltage surge occurs along the high inductance formed by these rings, which could lead to a breakdown or flashover between these ferritic, mostly semiconducting rings. Therefore, it is advantageous to individual rings which, as drawn in Figures 7a and 7b, 7e are isolated from each other by insulating used. These disks are also ring-shaped and expediently kept somewhat larger in their outer diameter than the diameter of the ferritic rings. It goes without saying that the ferrite rings must also be placed on the supply lines in an insulated manner, so that no sparks arise from the compensation of potential differences that could damage the material. The ignition of the system according to FIG. 2 is now carried out again by an ignition pulse generator, as it is to be thought on the right of the dashed line A and the z. B. as in FIG. 1 shown can be executed.

For the mechanical structure, it is usually particularly advantageous Pull several rings over the lines 4 to achieve the desired initial inductance to reach. In principle, however, it is also possible to utilize the invention to pull the leads 4 several times through the same ring, so the number of turns increase from one to any number per ring. Also in this case it sinks the effective inductance for the main discharge after the magnetic saturation of the Ring material around the value of the initial permeability.

It is particularly useful, as shown in FIG. 3 indicated to unite the rings 7 with the discharge capacitor 5 in the same housing, ie to pull the rings 7 over the part of the lines 4 in the housing 18 of the capacitor 5 itself, as shown in FIG. 3 indicated.

The invention is particularly useful with photographic flash lamps to be used as well as when using spark gaps for cloud height gauges, Visibility meters or fog warning devices as well as other photographic or signaling devices Devices that work with light pulses. But you can also use the arrangement well Use ignition of spark gaps in so-called pinch discharges, always the problem is an extremely precise ignition with a simple electrode structure to ensure. Because the arrangement allows a high repetition frequency to be used, are also electrical switching devices that use spark gaps as switching means, with or without overpressure in the spark gap medium, useful application objects of this Procedure.

Claims (2)

Patent claims: 1. Device for igniting a spark gap containing only two electrodes for triggering the discharge of a storage capacitor via the spark gap, characterized in that part of the current conductor of the low-inductance capacitor discharge circuit leading from the storage capacitor (5) to the spark gap (1.) is ferritic Material is enclosed, which has a high initial capacity, but is saturated even with low excitation, and that to initiate the capacitor discharge, an ignition pulse with a steep rising edge is fed directly to the two electrodes of the spark gap, for which the capacitor discharge circuit due to its high inductance through the ferritic material offers such a high inductive resistance that the ignition pulse leads to a sparkover in the spark gap, which initiates the discharge of the storage capacitor, while the high current flowing through the conductor of the capacitor discharge around the current mleiter generates such a high magnetic field that the ferritic material surrounding the conductor is saturated and thus becomes ineffective for the inductance of the discharge circuit. 2. Device according to claim 1, characterized in that when demountable spark chambers are used, the part of the conductor enclosed by the ferritic material simultaneously represents the retaining bolts of the system (F i g. 2). 3. Device according spoke 1 or 2, characterized in that ferritic rings are used for Umschheßung the conductor, which are isolated from each other and from the conductor itself. 4. Device according to claim 1 or the following, characterized in that one with an initial permeability of at least 2,000 is used as the ferritic material. 5. Device according to claim 1 to 4, characterized in that instead of the ferritic material, highly permeable sheet metal material is wound around the conductor in a thinly rolled form. 6. Device according to claim 3 or 4, characterized in that the ferritic rings enclose that part of the lines of the main discharge circuit which is located within the housing of the storage capacitor (5) (F i g. 3). 7. Device according to claim 3, 4 or 6, characterized in that the ferritic rings have a gap. 8. Device according to claim 3, 4, 6 or 7, characterized in that the lines of the main discharge circuit are drawn several times through the same ferritic ring. 9. Circuit arrangement for generating an ignition pulse for a device according to spoke 1 or the following, characterized in that for ignition a capacitor discharge via a switching spark gap (16), which is preferably surrounded to achieve a steep pulse with a closely surrounding insulating cylinder, on the electrodes the main spark gap (1) is conducted ( Fig. 1). 10. Circuit arrangement according to claim 9, characterized in that a pulse transformer (13 a, 13 b, 13 c) is used to charge the ignition capacitor (14), which is excited in a known manner on the primary side by a switching means (12) by means of a capacitor discharge becomes ( Fig. 1). 11. Circuit arrangement according to claim 10, characterized in that to increase the voltage of the ignition pulse, the switching spark gap lying in the supply line from the ignition circuit to the main spark gap (1) with its end facing the main spark gap via an auxiliary capacitor (15) with one electrode of the spark gap (1) and is connected via a high value resistor (17) to the other electrode of the spark gap (1), such that the voltage of the ignition pulse is added to the past on the main spark gap (1) static tension upon occurrence of the ignition pulse and the breakdown of the switching spark gap (16). 12. Circuit arrangement according to spoke 9 with a plurality of ignition capacitors discharging at rest, characterized in that the charging of the ignition capacitors takes place from the charging voltage of the main spark gap and the discharge is effected via a Marx multiple cascade circuit through a large number of spark gaps (F i g. 1 b).