RU2082253C1 - Pseudospark-discharge device - Google Patents

Abstract

FIELD: thyratron-type, gaseous-discharge, cold-cathode, low-pressure switching devices. SUBSTANCE: device starter is mounted inside one of main electrodes and is made in the form of metal electrode which is essentially open-end shell insulated from the former and arranged coaxially to it, with its open end facing holes in main electrodes of device. Insulated from shell and placed outside it is hollow metal electrode whose inner side wall is equidistant to internal electrode wall of starter and is spaced from it at distance of several millimeters. Holes are made in mentioned adjacent electrode walls, and additionally introduced high-melting metal rod is placed along starter internal electrode axis on closed end of electrode. Loose end of rod is rounded off and shifted towards holes in ends of main electrodes from point of intersection of center lines of holes in main electrodes of device and those of holes in starter electrodes through distance smaller than radius of rounded-off end of rod. Internal electrode of starter has radial projections on closed end which enter its inner space through slits in inner wall of external electrode. EFFECT: improved design. 5 cl, 5 dwg

Description

 The invention relates to the field of gas-discharge switching devices of a low-pressure thyratron type with cold cathodes and is intended to operate as switching elements in high-voltage pulsed power supply devices for process lasers, plasma-chemical plants, electromagnetic energy generators, etc. long working in the modes characterized by high values and high slew rate of voltage and current in the load, high pulse repetition rate.

 In the known pseudo-spark arrester, a starting device consisting of two electrodes isolated from each other is located inside the cavity of the cathode electrode of the pseudo-spark arrester and activates the arrester with short-wave radiation generated by a spark that occurs during breakdown between the electrodes on the surface of the insulator / 1 /. The pulse resource of such a starting device is significantly lower than the pulse resource of the main discharge gap of the pseudo-spark gap due to the gradual destruction and metallization of the surface of the insulator and the electrodes of the starting device as a result of the formation of cathode spots.

 Closest to the proposed invention in technical essence is a spark gap in which a starting device located inside the cavity of the main electrode is made in the form of a cylindrical cup or a closed cylindrical cavity with an opening / 2 /. With such a configuration of the starting device, a significant effect on the breakdown voltage of the arrester is possible only at small / several millimeters / distances of the starting device from the holes in the main electrodes, because of which, with a small cathode cavity or an increase in the discharge current density, the surface erosion intensity of the main electrodes increases and, accordingly, the service life of the device is reduced.

 The problem to which the invention is directed is to increase the resource of a pseudo-spark arrester. The technical result is to increase the pulse resource of the starting device to a value comparable to or even greater than the pulse resource of the main discharge gap, as well as improving the switching qualities of the spark gap.

 The problem is solved due to the fact that in the arrester containing the main electrodes located in a sealed housing in the form of coaxial hollow cylinders with coaxial holes at adjacent ends and a starting device placed coaxially inside one of the electrodes, made in the form of a metal electrode isolated from it in the form cups with an open end facing the holes in the main electrodes of the arrester, in the starting device, an external metal electrode is isolated from it, an annular metal is placed a hollow electrode, the inner side wall of which is located equidistant to the wall of the internal metal electrode of the starting device at a distance of several millimeters. In this case, in the adjacent walls of the electrodes of the starting device, coaxial holes 3 are made, and at the end of the internal electrode of the starting devices, a central rod of refractory metal is fixed, the free end of which is rounded and shifted towards the holes in the main electrodes of the arrester from the point of intersection of the axis of symmetry of the holes in the main electrodes of the spark gap and the axis of the holes in parallel adjacent walls of the electrodes of the starting device to a distance less than the radius of curvature of the end of the rod. In addition, the inner electrode of the starting device on the end side is provided with radial protrusions, which are inserted into its volume through slots made in the inner wall of the outer electrode of the starting device.

 An increase in the pulse life of the arrester is ensured by the improvement of the starting device, since its action is based on the use of the properties of a pseudo-spark discharge, which can exist without the formation of cathode spots on the electrodes and has a growing current-voltage characteristic, which makes it possible to use such an arrester and its starting device the number of parallel current channels, which provides the necessary electrode wear rate, which allows to realize a given pulse ESOURCES device.

At the same time, high switching qualities of the arrester / short confinement delay time, high turn-on stability, high current rise rate / are achieved due to the appearance of intense high-energy electron beams propagating along the axis of the openings in the electrodes of the start-up device at the time the discharge is turned on. The rounded end of a rod made of metal with a large atomic number, as a result of bombardment by fast electrons, becomes a source of soft x-ray radiation with an intensity
I ₀ ≈10 ^-9 ZV ² I W
/ V and I-energy and current of the mentioned electron beams, expressed in electron volts and amperes, Z-atomic number of the rod material /, which penetrates into the inner space of the main cathode cylinder through the open end of the internal electrode of the starting device, facing the holes in the main electrodes of the spark gap , produces photoionization in its volume and causes photoemission in the region of the current-carrying holes of the arrester, which ensures its high switching properties.

 An additional improvement in the switching properties of the arrester, namely: increasing the synchronism of the development of the discharge in the holes of the electrodes of the starting device when turned on, as well as reducing the delay time for turning on the starting device itself, can be achieved by placing on the outer protrusions on the inner electrode of the starting device, a ring a current-flow solenoid or an annular permanent magnet magnetized in the direction of the axis of symmetry of the main discharge electrodes a source with the help of which a magnetic field of a value of several millitesla is created, while part of the surface of the internal electrode of the starting device opposite the coil is open to the internal volume of the external annular cavity, which facilitates the penetration of the starting electric field into the external cavity, lengthens the ionization paths of the primary electrons, enhances starting inrush current.

 Adjacent walls of the internal and external electrodes of the starting device can be made cylindrical, due to which a high concentration of fast electron fluxes at the end of the said rod and, accordingly, a high intensity of x-ray radiation from its surface are achieved.

 Adjacent parallel walls of the inner and outer electrodes of the starting device can be conical. At the same time, due to the improvement of the conditions for bombarding the end of the mentioned rod with fast electrons, the intensity of the x-ray radiation emerging through the open end of the inner electrode into the inner space of the main electrode of the spark gap increases, which reduces the energy consumption for its inclusion.

 In those cases when, according to the starting pulse source circuit, it is not necessary to isolate the ring electrode of the starting device from the main electrode of the arrester, its volume can be part of the volume of the main electrode, and it is formed by a part of the wall of the starting electrode of the arrester, which greatly simplifies and reduces the cost of the arrester design / due to exceptions from it one sealed metal-ceramic input.

 In FIG. 1 represents a variant of a spark gap in which the adjacent walls of the internal and external electrodes of the starting device are cylindrical.

 In FIG. 2 shows a variant of a spark gap in which the adjacent walls of the inner and outer electrodes are conical.

 In FIG. 3 shows a variant of a spark gap, in which an annular hollow electrode of the starting device is formed by a part of the wall of the main spark gap electrode.

 In FIG. 4 and in FIG. 5 shows cross sections of the cathode part of the spark gap made according to the embodiment of FIG. 2, in the region of the location of the electrodes of the starting device.

 Arrester / Fig. 1, 2, 3 / contains a metal-reinforced hermetic ceramic case 1, inside of which are placed two coaxial main cylindrical electrodes / anode 2 and cathode 3 /, which are hermetically connected to the case 1, in the adjacent ends of which made of molybdenum, coaxial holes 4 are made with a diameter of 3-4 mm. Inside the cathode cylindrical electrode 3, a starting device isolated from it by means of ceramic-metal inputs 5, 6 is introduced, consisting of an internal metal electrode 7 with an open end facing the holes 4 in the main electrodes and a metal annular hollow electrode 8 located outside the electrode 7. When this, in the adjacent walls of the electrodes 7 and 8, the starting device, several pairs of coaxial holes with a diameter of 3-4 mm are made, the axes of which with the axis of symmetry of the holes 4 in the main electrodes of the spark gap e A. At the closed end of the internal electrode 7 starting device provided with radial protrusions 9, which through radial slots in the outer annular electrode 8 introduced in its scope. In addition, a central cylindrical rod 10 made of molybdenum, the free end of which is rounded, is fixed on the axis of the inner electrode 7 of the starting device at the end having the said protrusions. In this case, the rounded end of said rod is shifted towards the holes 4 in the main electrodes of the arrester from the aforementioned point A of the intersection of the axes of the holes 11 in the electrodes of the starting device by a distance smaller than the radius of curvature of the end of the said rod.

 The ceramic-metal inputs 5, 6 are used to supply a high-voltage ignition pulse between the electrodes of the starting device from the generator 12. Opposite the protrusions 9 of the internal electrode of the starting device, an annular solenoid 13, streamlined by current, or an annular permanent magnet can be fixed on its outer side magnetized in the direction of the axis of symmetry of the arrester.

 For the final three-vacuum treatment and soldering of the spark gap, the plug 14 is soldered to the end of the main electrode 2. A disk 15 made of refractory metal / molybdenum, tungsten / is fixed on the inside of the mentioned end face. The leakage 16 and the alternating current source 17 are designed to fill the arrester with working gas / helium, hydrogen /, and adjust the pressure of the gas medium during continuous operation.

 The holes 18 in the main electrodes of the arrester are made to improve the ventilation conditions of the closed cavities of the arrester during thermal vacuum processing and filling with gas.

 In the embodiment of FIG. 3, the outer ring electrode 8 of the arrester starting device is formed by a cylindrical metal partition 19, a cover 20, a part of the surface of the cathode flange 21 and a part of the inner surface of the main cathode electrode 3.

 The arrester operates as follows. After thermal vacuum training and degassing, the shtengel tube 14 is pinched. The leak heater 17 is turned on and the gas pressure in the range of 1.33 is set in the spark gap volume. 13.3 Pa. In the initial state, the voltage applied to the main electrodes of the arrester anode 2 and cathode 3 is applied to the switched circuit into which the arrester is connected. The arrester is switched on when an ignition pulse with a voltage of several kilovolts and a duration of several tens of nanoseconds is supplied to the inputs 5, 6, so that the internal electrode of the starting device 7 has a positive potential relative to the outer ring electrode 8. In this case, a primary volume discharge occurs between the protrusions at the first moment of time 9 and the inner surface of the annular hollow electrode of the starting device. Since the aforementioned discharge gap is shunted by a pseudo-spark discharge gap formed by the holes 11 in the electrodes 7 and 8 of the starting device having a lower impedance during the development of the primary discharge, the discharge current is simultaneously pumped into the holes 11 of this pseudo-spark discharge gap, which is accompanied by the appearance of intense electron beams with energies of several kiloelectrovolts propagating radially at point A on the axis of symmetry of the launcher a. The hit of the said electron beams on the rounded end of the molybdenum rod, placed at the aforementioned point A, is accompanied by a flash of soft x-ray radiation, which penetrates into the inner space through the open end face of the inner electrode 7, facing the main pseudo-spark discharge gap formed by the openings 4 between the electrodes 2 and 3 electrode 3, causes photoionization in the volume of electrode 3 and in holes 4, as well as photoemission from the inner surface of electrode 3 in the region of holes 4, which effectiveness to clear the inclusion of the arrester with minimum time delay with respect to the appearance of X-ray radiation from the open end of the trigger electrode 4 arrester device. The necessary ratio of the impedances of the said gaps of the arrester starting device is regulated by the magnitude of the magnetic field generated by the coil or permanent magnet 13, which has a value of several millitesla. The refractory metal disk 15 prevents the anode from penetrating by an electron beam that briefly arises in the holes 4 of the main electrodes 2 and 3 each time the switched current is turned on, which is possible during continuous, continuous operation of the arrester.

 Since at all stages of the process of switching on the spark gap, as well as at the stage of current passage in the main gap included in the switched circuit, only volumetric discharge forms are realized in the working volume that are not accompanied by the appearance of cathode spots, which is the main reason for the rapid wear of the electrodes and degradation of the internal insulation, limiting the pulse life of the arrester, when using the described technical solution, any arbitrarily long service life can be realized. The increase in wear of the electrodes of the device, if necessary, increase the current load, can be compensated by the number of pairs of holes in the main and starting electrodes of the spark gap. A possible decrease in pressure during the continuous operation of the spark gap caused by irreversible absorption and sorption of gas atoms can be compensated by periodically turning on the heating element of the gas leak.

Claims (5)

 1. A pseudo-spark gap containing the main electrodes located in a sealed enclosure in the form of coaxial hollow cylinders with coaxial holes at adjacent ends and a starting device placed coaxially inside one of the main electrodes, made in the form of a metal electrode isolated in the form of a glass with an open end, facing the holes in the main electrodes of the arrester, characterized in that in the starting device outside the metal electrode, isolated from it, is placed an annular metal a hollow electrode, the inner side wall of which is located equidistant to the wall of the inner metal electrode at a distance of several millimeters, while coaxial holes are made in adjacent walls of the electrodes of the starting device, and a central core of refractory metal is fixed at the end of the inner electrode, the free end of which is rounded and offset in the direction of the holes in the ends of the main electrodes of the arrester from the point of intersection of the axis of symmetry of the holes in the main electrodes the core and the axes of the holes in the electrodes of the starting device to a distance less than the radius of curvature of the end of the rod, in addition, the inner electrode on the side of the end is provided with radial protrusions, which are introduced into its volume through slots made in the inner wall of the outer electrode.  2. The spark gap according to claim 1, characterized in that the adjacent walls of the internal and external electrodes of the starting device are cylindrical.  3. The arrester according to claim 1, characterized in that the adjacent walls of the internal and external electrodes of the starting device are conical.  4. Arrester according to paragraphs. 1 to 3, characterized in that the outer side wall of the annular metal hollow electrode is formed by a part of the wall of the main electrode of the arrester.  5. The arrester according to claim 1, characterized in that opposite to the radial protrusions on the inner electrode of the starting device, on the outer part of the main electrode of the arrester there is an annular solenoid or an annular permanent magnet magnetized in the direction of the axis of symmetry of the main electrodes.

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