RU171371U1 - VACUUM DISCHARGE - Google Patents

Abstract

The utility model relates to electrical engineering and high-current electronics, is a controllable vacuum arrester and can be used for switching high-current high-voltage electrical systems. The vacuum spark gap includes a sealed dielectric sheath containing a coaxial electrode system consisting of a cathode and anode, and an optically transparent window for introducing control pulsed optical radiation along the axis of symmetry of the spark gap. The anode is made with a through hole for passing control radiation in the direction of the cathode. Inside the shell, on the axis of symmetry of the arrester, a ceramic target is located on the cathode surface. An optical element located outside the sealed enclosure focuses the control radiation at the cathode. The technical result is to reduce the intensity of the control radiation and the stability of the arrester. 2 s.p. f-ly, 2 ill.

Description

Controlled vacuum arresters are used as switching elements when creating pulse current generators. A special class is occupied by sealed controlled vacuum arresters. They are compact, have a high-voltage and high-current field of application, have a significant response resource, depending on the electrical energy in the switched circuit. Vacuum arresters have certain positive qualities: the absence of incandescent circuits (as opposed to thyratrons) and, as a result, constant readiness for work, the vacuum inside the arrester allows using it in devices in the presence of radiation fields. These advantages of vacuum arresters make it possible to successfully use them in applied tasks when creating high-speed high-current automation systems.

A known laser-controlled spark gap in which the breakdown of the spark gap occurs when the laser pulse is focused on the cathode, which causes strong local heating of the cathode surface at the focus of the lens, as a result, the emission of thermoelectrons initiating the discharge under the action of an applied electric field, a primary electron avalanche arises, passing then into a fast streamer closing the discharge gap. L.N. Bykhovskaya et al. Study of the characteristics of high-speed sealed-off arresters ignited by laser radiation // Quantum Electronics, 1977, v. 4, No. 8, p. 1708. The disadvantage of this method is the need for the presence of a gas medium of a sufficiently high density for the occurrence of primary electronic avalanches; which makes it possible to operate under the influence of penetrating ionizing radiation.

A known laser-controlled arrester comprising a housing in which two opposing electrodes are mounted, one of the electrodes has a through hole in which a transparent window for introducing the laser beam is installed on the path of the laser beam. The window is covered with a metallized film to create an avalanche flow. USSR author's certificate No. 1641161, IPC H01T 1/20, 04/15/1994. The disadvantage of this arrester is the need to heat to a high temperature a metal layer deposited on a film made of non-refractory organic material, which causes its rapid destruction and reduces the resource of the arrester.

A controllable discharger in a two-electrode design is known, located in a pumped-out case, in which the cathode is made of VNB-3 alloy, a transparent window for inputting a laser beam is installed in the case, the anode is made with a hole, and a tip is formed in the center of the cathode of VNB-3 alloy. Utility Model Patent RU 119935, IPC H01J 17/64, 05.25.2012. This technical solution was made as a prototype. The disadvantage of this device is that the presence of a tip significantly reduces the electric strength of the interelectrode gap and makes it sensitive to the surface quality of the tip, which will modify its shape during operation, which reduces the reliability of the device.

The technical result of the utility model is to increase the reliability of the spark gap.

It is known that the minimum value of the laser pulse energy required to ignite the spark gap is determined by the thermodynamic parameters of the cathode material (Davydov SG and others. The process of switching a vacuum electric discharge gap by a laser plasma // Applied Physics, 2014, No. 6, p. 32). According to the obtained experimental data, the level of the minimum laser pulse energy required to ignite the spark gap depends on the value of the parameter α = T ³ _melt / χμ, where T _melt (K) is the melting temperature of the target material on the Kelvin scale, (kg / mol) is the molar mass of the target material , χ (m ² / s⋅K) is the thermal diffusivity, equal to χ = λ / ρс, where λ (W / m⋅K) is the thermal conductivity, ρ (kg / m ³ ) is the density and s (J / kg) - specific heat of the target material. The nature of the dependence is reflected in FIG. 1. In general, with an increase in the parameter α, the minimum value of the laser pulse energy required for igniting the spark gap decreases. More precisely, the value of the minimum laser pulse energy required to ignite the spark gap is inversely proportional to α ^1/2 , i.e. square root of the parameter α. The smallest value of the minimum laser pulse energy needed to ignite a spark gap among experimentally studied target materials is graphite (carbon in terms of elemental composition). A corresponding calculation and comparative analysis show that the ratio of the coefficient α for graphite (α _s ), zirconium oxide (α _ZrO2 ) and corundum (α _Al2O3 ) testifies to the use of ceramics as a target material in a laser-controlled vacuum discharge device:

αZrO ₂ / α _c = 3.3

α _Al2O3 / α _c = 3.5.

The use of targets made of ceramics will reduce the minimum laser pulse energy required for igniting a spark gap by approximately (α _ZrO2 / α _s ) ^1/2 ≈ (α _Al2O3 / α _s ) ^1/2 ≈1.8 times compared to previously studied materials.

The technical result is achieved by the fact that in a vacuum spark gap comprising a sealed dielectric sheath containing a coaxial electrode system consisting of two electrodes and an optically transparent window for introducing control pulsed optical radiation along the axis of symmetry of the spark gap, as well as an optical element located outside the hermetic sheath focusing the control radiation at the cathode, and the anode is made with a through hole for passing control radiation in the direction of the cathode, inside the shell hibernation on the symmetry axis of the arrester on the surface of the cathode target is made of ceramics.

The target can be made of corundum (Al ₂ O ₃ ) or zirconia (ZrO ₂ ).

The proposed technical solution is illustrated by drawings.

In FIG. Figure 1 shows the distribution diagram of the materials used to fabricate the cathode, according to the minimum value necessary for initiating a discharge of energy in a laser pulse (E _LP ) _min , and the parameter (T ³ _melt / χμ) ^1/2 .

In FIG. 2 shows a diagram of a laser-controlled vacuum spark gap, where 1 is a pulsed laser, 2 is an optical element, 3 is an input optical window, 4 is a dielectric evacuated housing of a spark gap, 5 is an anode, 6 is a cathode, 7 is a target.

The vacuum arrester controlled by the radiation of a pulsed laser consists of a coaxial electrode system enclosed inside a sealed dielectric housing pumped out to high vacuum 4. The electrode system contains two electrodes: anode 5, in which there is a through hole for passing control radiation in the direction of a flat target 7, made made of ceramic and placed on the surface of the cathode 6. In the sealed dielectric casing of the arrester 4 there is an optically transparent window 3, the purpose of which is to Ensuring the transport of control radiation focused on the surface of the target 7 from a pulsed laser 1 into the housing 4 along the axis of symmetry of the spark gap. The control radiation is focused using an optical element 2, for example a collecting lens. It was experimentally established that with a gap between the anode and cathode of the order of 1 mm in the evacuated interelectrode gap, the operating voltage of the arrester reaches 10 kV.

The arrester operates as follows. The radiation of the optical range emitted by an external pulsed source is focused on the surface of the target. The focusing spot obtained using a collecting lens with a focal length of the order of several centimeters will have a diameter of several tenths of a square millimeter (Yu.P. Raizer, Gas Discharge Physics. 2nd ed. Revised and enlarged. - M .: Nauka. Gl. Ed. Phys.-Math. Lit., 1992 .-- 536 p. - P.239). When the radiation energy is 10 ^-3 -10 ^-2 J in a pulse of 10 ^-9 -10 ^-8 s duration, which is provided by commercially available compact solid-state optical quantum oscillators with LED pumping, the radiation energy flux density on the target can be brought up to the level of 10 ⁸ - 10 ¹⁰ W / cm ² . At such a level of intensity of the radiation incident on the target at the target surface, i.e. a plasma torch forms at the cathode surface, propagating in the direction of the anode under the influence of an applied electric field. The interelectrode space is filled with a conductive medium and the arrester trips.

The use of targets made of ceramics will make it possible to reduce the minimum laser pulse energy required for igniting a spark gap in comparison with previously studied materials. Therefore, random fluctuations in the energy of laser radiation, leading to a decrease in the energy and, accordingly, the intensity of laser radiation below the average level, are less dangerous.

The lower the energy and intensity of the laser radiation incident on a target made of a certain material, the lower the mass and the lower the temperature of the plasma formed under the action of laser radiation, the greater the likelihood that when it propagates from the cathode to the anode, it cools down and turns into a neutral non-conducting Wednesday, i.e. there will be no closure of the interelectrode gap and the operation of the arrester.

Thus, the use of a ceramic target, which leads to a decrease in the minimum laser pulse energy required for igniting a spark gap, reduces the probability of a spark gap failure, i.e. increases the reliability of the arrester operation at a given laser radiation energy used to ignite the arrester: the energy of the radiation used obviously exceeds the level of the minimum laser pulse energy required to ignite the arrester, and the lower the minimum level of the laser pulse energy required to ignite the arrester at a given laser radiation energy, the the greater the specified excess and the higher the reliability of operation.

Claims (3)

1. A vacuum arrester comprising a sealed dielectric sheath containing a coaxial electrode system consisting of two electrodes and an optically transparent window for introducing control pulsed optical radiation along the axis of symmetry of the arrester, as well as an optical element located outside the sealed sheath, while the optical element focuses control radiation at the cathode, the anode is made with a through hole for passing control radiation in the direction of the cathode, characterized in that inside pins on the axis of symmetry of the spark gap on the surface of the cathode is a ceramic target. 2. The vacuum spark gap according to claim 1, characterized in that the target is made of corundum Al ₂ O ₃ . 3. The vacuum spark gap according to claim 1, characterized in that the target is made of zirconium oxide ZrO ₂ .

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