SU1143282A1 - Multichannel spark gap - Google Patents

Abstract

1. A multichannel arrester containing a resisting solid electrode and an electrode with holes, in which pre-energizing electrodes are connected to one of the terminals of the corresponding starting capacitors, the other terminals of which are connected through a common switch to the electrode with holes, auxiliary electrodes located in the gap between the solid electrode and the electrode with openings opposite the ignition electrodes and electrically connected to the solid electrode by means of conductors, covering ferromagnetic cores through which a short-circuited winding is passed, resistors, each connected to one of the conclusions with a corresponding ignition electrode, and a power source, characterized in that, in order to increase the reliability of the multichannel operation, it is equipped with a pulse transformer, the primary winding of which is connected to the indicated source power supply, and the secondary winding is connected between the solid electrode and the electrode with holes and is made with two intermediate leads, one of which connected to other terminals of these resistors, and another connected through an additionally introduced inductor to the common connection point of said starting capacitors and switch, with the firing electrodes protruding into the gap between the solid electrode and the electrode with holes equal to or less than the distances the gaps between the ignition electrodes and the electrode with holes. . 2. A discharge device according to claim 1, which is supplied with 00 with an additional short-circuited winding, which is passed through ferromagnetic cores and is connected in opposite to the specified short-circuited winding.

Description

The invention relates to high-voltage impulse technology and is intended for switching impulse currents of a mega-ampere range of nanosecond duration in the mode of pulse repetition frequency, limited by the gas deionization time and the recovery time of its electrical strength. A multichannel spark discharge is known, which contains a solid electrode and an electrode with holes, in which igniting electrodes are installed, and auxiliary electrodes, each connected by two conductors with a solid electrode at points located on the axes of adjacent auxiliary electrodes. In this discharge, by re-magnetising the ferromagnetic cores enclosing the conductors with the current of each spark channel and inducing voltage on the neighboring spark gaps, conditions are created to evenly divide the current between the channels. In the event that the currents of the spark channels are equal, the inductive resistance caused by the presence of ferromagnetic cores is close to zero. The disadvantage of this bit is the insufficiently high stability of the multichannel operation. A multichannel spark gap is also known, containing a resisting solid electrode with auxiliary electrodes connected to it by means of conductors enveloped by ferromagnetic cores with short-circuited windings, and an electrode with holes in which ignition electrodes are installed, surrounded by additional electrodes B of this type. due to the presence of additional electrodes, the electric field of the electrode with a hole is distorted and the average electrical voltage decreases. r field in the spark gaps that reduces individuals speed development of avalanches and the formation of streamers, in the final ito n, limits the number of channels in pa p arrestor. In addition, in this gap, every two adjacent ferromagnetic cores are connected by a short-circuited winding, which worsens the conditions for the spark gap and current division in the channels due to the pair symmetry of the neighboring auxiliary electrodes. The closest known technical solution to the invention is a multichannel glitter containing an opposing solid electrode and an electrode with holes in which ignition electrodes are connected with one of the terminals of the corresponding starting capacitors, the other terminals of which are connected through a common switch to the electrode. with holes, auxiliary electrodes located in the gap between the solid electrode and the electrode with holes opposite the ignition of the electrodes and and connected to a solid electrode by means of conductors covered by ferromagnetic cores, through which a short-circuited winding is passed, resistors, each connected by one of the leads to a corresponding ignition electrode, and a power source. The presence of a short-circuited winding passed through all the ferromagnetic cores makes it possible to reliably regulate the distribution of the current in the discharge channels. The disadvantage of this bit is that the multichannel triggering conditions are performed in a very narrow range of variation of a given voltage and slightly improve with increasing control power, which reduces the reliability of the multichannel triggering. The practically measured values of the range of the arrester's response voltage are 3%. The purpose of the invention is to increase the reliability of multichannel operation. This is achieved by the fact that a well-known multichannel arrester containing opposing solid electrode and electrode with holes, in which, with a gap, are installed ignition electrodes connected to one of the terminals of the corresponding starting capacitors, the other terminals of which are connected holes, auxiliary electrodes located in the gap between the solid electrode and the electrode with holes opposite

igniting electrodes and electrically connected to solid electrons by means of conductors covered by ferromagnetic cores, through which a short-circuited winding is omitted, resistors, each connected to one of the leads with a corresponding ignition electrode, the power supply according to this invention is equipped with a pulse transformer j the primary winding is connected to the specified power supply, the secondary winding of which is connected between the flat electrode and the hole electrode and with two intermediate pins, one of which is connected to the other terminals of these resistors, and the other of which is connected through an additionally introduced inductor to the common connection point of these starting capacitors and switch, and the ignition electrodes protrude into the gap between the solid electrode and the holes distances equal to or smaller than the gaps between the ignition electrodes and the electrode with the holes.

In a preferred embodiment, the discharge is performed with an additional short-circuited winding, which is passed through ferromagnetic cores and is connected in opposition to said short-circuited winding.

FIG. 1 shows an electrical circuit for switching on a multi-channel arrester; in fig. 2 — Temporary voltage plots on the forming line (curve A), voltage on the starting capacitor (curve B), voltage on the firing electrode (curve C) and voltage on the storage capacitor (curve G).

The discharge contains (Fig. 1) a solid electrode 1, auxiliary electrodes 2 connected to a solid electrode 1 by conductors encircled by ferromagnetic cores 3 with two short-circuited counter-connected windings 4, and an electrode 5 with openings with igniting electrodes 6 protruding above the electrode surface 5 by a magnitude d equal to or smaller than the size of the gap between the electrodes 5 and 6. Each firing electrode 6 is connected to the electrode 5 by means of a series-connected starting capacitor 7 and a common switch 8. K Electrodes 1 and 5 are connected to a secondary winding 9 of a pulse transformer, the intermediate terminals of which are connected respectively via resistors 10 to igniting electrodes 6 and through an inductor 11k to a common connection point of starting capacitors 7 and switch 8. Primary winding 12 of a pulse transformer is connected to a power source containing a storage

C a capacitor 13, a thyristor 14, a choke 15 and a source of constant voltage (not shown); pa-. . parallel to the secondary winding 9 of a pulse transformer included

0 serially connected forming line 16 and load 17.

Structurally, the multi-channel glitter is made symmetrically with respect to the conclusions of the forming line 16

5 and the load 17 with the location of the spark gaps between the electrodes 2 and 5 around the circumference. In this case, electrode 1 is combined with the potential electrode of the coaxial forming

0 lines of the bluml type This design of the arrester provides the smallest inductance, and its suitability for switching currents of the megaamper band at the nanosecond duration of operation.

The discharge works as follows.

In the initial state cumulative

Q capacitor 13 is charged from a constant voltage source to the required voltage U. When a control pulse is applied to the thyristor 14, the storage capacitor 13 starts

do not discharge in oscillatory mode through the primary winding 12 of the pulse transformer (see Fig. 2, curve D). Induced in the secondary winding 9 Pulse transformer

The Q electromotive force (EMF) charges the forming line 16 and the starting capacitors 7. At the same time, the ignition electrodes 6 are supplied with the voltage of the same polarity and form, but smaller amplitude as the auxiliary electrodes 2. This reduces distortion the electric field at electrode 5, caused by the introduction of ignition electrodes 6 into

spark gaps, and increase the intensity of the electric field in the gaps of the spark gaps. The resistances of the resistors 10 and the inductance of coil 11 are chosen based on the condition that the current of the transformer is limited during the subsequent closure of the switch 8, and are small enough to allow the capacitors 7 to be charged with practically no energy loss in the charging circuit, since their current is close to sinusoidal form.

At time t, the voltage on the forming line 16 (Fig. 2, curve

A) reaches a value of U. which is sufficient for the spark gap to be broken between electrodes 2 and 6 in the event that electrodes 6 had

. The potential of the electrode 5. In the presence of a potential on the ignition electrodes 6, the forming line 16 is charged to a voltage close to U and the spark gaps between the electrodes 2 and 6, which are limited by the strength, under these conditions of voltage variation on them. At time t, the switch 8 closes and the voltage of the starting capacitors 7 (FIG. 2, curve B) is applied to the gaps between the ignition electrodes 6 and the electrode 5. The voltage U, on the forming line 16 (FIG. 2, curve A) at this the moment is close to the maximum voltage U, and

burning electrode (Fig. 2, curve

B) reaches the value of U. In this case, the voltage on the ignition electrodes 6 decreases sharply, changes sign and tends to reach the voltage on the capacitors 7. This causes a spark to develop between the ignition electrodes 6 and the auxiliary electrodes 2 ,. When the voltage across the gaps between electrodes b and electrode 5 is reached, an additional illumination of the developing spark channel between the ignition 6 and auxiliary 2 electrodes occurs. Such ignition conditions are maintained in the time interval t, -t with an appropriate ratio of &values; , and, and for a given length of the spark gap and allow you to have a guaranteed control zone of the moment of ignition of the spark channels. Since in the considered discharge channel breakdown begins and

may occur even before the voltage sign on the ignition electrode 6 is changed, then much less energy is needed to illuminate the spark gap, and therefore it is much easier to provide a short front pulse to the electrode 6.

If the breakdown between electrodes 2 and 5 occurs simultaneously and the current in

equal to the gap, then in the short-circuited windings 4 a current equal to the current of one spark channel is established, and the ferromagnetic cores 3 are re-magnetized under

the action of a voltage equal to the voltage drop across a short-circuited winding distributed over all the cores, and the self-inductance of the system is small. At the end of the pulse

current in the short-circuited windings 4 attenuates and demagnetizes the cores.

If one or several gaps break down, the ferromagnetic cores 3 and the electrodes 2 form saturation inductors and the current in the channels is limited by the magnitude of the magnetization reversal of the cores. At the same time on the windings 4.

EMF is induced, which is applied due to the mutual inductive coupling to the interelectrode gaps of the non-switched spark channels, preventing the discharge of the interelectrode

when more than half of the discharge gaps are turned on, it additionally charges it, thus improving the conditions for the development of channels in non-switched spark gaps.

Thus, in the event of failure of one gap, the EMF of the windings 4 is additionally attached to it, equal to the sum of the two voltages induced by the magnetizing cores. causes it to force a breakdown. Prior to the breakdown of the last gap, the current of all spark channels is limited by the alternating magnetization current of the cores, and since its magnitude is much less than the switched current by the formation of line 16, almost the entire voltage of the forming line A is applied to electrodes 1 and 5, which is balanced by the saturation points formed by ferromagnetic cores 3. Similarly, the current between the channels is divided. If the current in the individual channels exceeds the current established in the winding 4, then the ferromagnetic cores 3 begin to oscillate, an additional inductive voltage drop occurs, which prevents the current from increasing and at the same time is induced by the auxiliary electrodes 2 with a lower current, increasing the current in them. The use of two oppositely connected short-circuited windings 4, covering all ferromagnetic cores, makes it possible to obtain a current in these windings, which in the intervals between the channels is directed oppositely. By making these sections of the windings in the form of lines, for example, of the strip type, the intrinsic inductance of the windings is significantly reduced. In addition, the current in each winding becomes two times less than in one winding. This allows you to reduce the time of establishment of currents in these windings, the sum of which is equal to the current switched by one channel of the discharge, and thereby improve the shape of the front of the current pulse in the load 17. 2 In this multichannel discharge all conditions for working in the frequency mode , and it combines the best properties of arresters with the distortion of the floor and trigatron type, namely: it provides the conditions of multichannel operation of all spark gaps due to additional overvoltage from both the negative electrode and positive if non-simultaneous actuation of the spark channel to their full incorporation, provides illumination of the spark gap, and provides a plasma near the negative electrode; provides reliable current separation between individual channels with current imbalance in individual channels, limited at the level of alternating magnetization current of the ferromagnetic core; It has a simple design and synchronization system. These factors allow switching high impulse currents with low losses in the freewheeling mode with a pulse following frequency limited by the parameters of the gaseous medium.

Claims (2)

1, A multichannel discharger containing an opposing solid electrode and an electrode with holes, in which ignition electrodes are connected with a gap, connected to one of the terminals of the corresponding starting capacitors, the other terminals of which are connected via a common switch to the electrode with holes, auxiliary electrodes located in the gap between the solid electrode and the electrode with holes opposite the ignition electrodes and electrically connected to a solid electrode with the help of conductors covered by ferromagnetic cores, through which a short-circuited winding, resistors each connected by one of the leads to a corresponding ignition electrode, and a power source, characterized in that, in order to improve the reliability of the multichannel operation, it is equipped with a pulse transformer, the primary winding of which is connected to the specified power source, and the secondary winding is turned on between a solid electrode and an electrode with holes and is made with two intermediate terminals, one of which is connected to the other terminals of these resistors, and the other Connected through an additionally introduced inductor to the common point of connection of these starting capacitors and switch, the ignition electrodes protrude into the gap between the solid electrode and the electrode with holes a distance equal to or smaller than the gap between the ignition electrodes and the electrode with holes. . 2. Discharger on π. 1, characterized in that it is provided with an additional short-circuited winding, which is passed through the ferromagnetic cores and is included in the opposite short-circuited winding. 1143282 one 1143282 2