RU2362244C2 - Gas-filled discharger - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to high-voltage pulse engineering, particularly to high-current pulse gas-filled dischargers, meant for use as switches in well electrohydraulic installations. The gas-filled discharger has electrodes with terminals, fitted opposite each other in a metal case, and insulators in form of flattened cones, the smaller bases of which are attached to the electrodes, and the larger bases to the butt-ends of the case. The discharger is placed inside a protective metallic shield. The terminals are separated from the case and the protective shield by additional insulators. At least one terminal has a spring element. Also the protective shield has on its ends joining elements in form of a thread or flange. The additional insulators cover the entire length of the terminals. The terminals and the additional insulators cannot turn about each other and the protective shield. The spring element in the terminal is made from a spring, bellows element or coaxial cable sheath. Between the case and the protective shield there is a shock pad.

EFFECT: increased resistance of the discharger to high hydrostatic pressure and impact mechanical load.

8 cl, 4 dwg

Description

The invention relates to high-voltage pulse technology, namely, high-current pulsed gas-filled arresters, intended for use as switches in downhole electro-hydraulic installations.

At the Institute of Impulse Processes and Technologies (Nikolaev, Ukraine, see article KVDubovenko, Yu.I. Kurashko, "The Design, Fabrication end Testing of a Closing Switch for Compact Electrical Discharge Industrial Equipment", 11 th IEEE Pulsed Power Conference , Baltimore, Maryland, 1997, pp.868-874) an uncontrolled gas-filled spark gap was developed for borehole electro-hydraulic devices operating in rather severe conditions: external hydrostatic pressure up to 50 MPa, temperature up to + 100 ° С, operating voltage 27-31 kV. The arrester contains an outer metal housing and two working internal electrodes located along the axis of the housing with a gap of 12-13 mm relative to each other. The electrodes are made of stainless steel or molybdenum and are isolated from the housing using long corrugated insulators mounted on the ends of the housing. The electrodes have rod down conductors. The casing is filled with nitrogen at atmospheric pressure. The diameter of the spark gap is 90 mm.

The disadvantages of the arrester are a large length of 685 mm and an inductance of 500 nH. In addition, the profile of the electrodes and the gas medium do not provide high stability of operation (the spread of the operating voltage reaches 4-5 kV) and the resource of the arrester.

Closest to the claimed device, the prototype is a gas-filled spark gap (see Avilov E.A., Kartelev A.Ya., Yuryev A.L., RF patent No. 2093917, IPC ⁶ H01J 17/00, publ. 20.10.97, in BI No. 32), containing electrodes mounted against each other in a metal casing, and insulators in the form of truncated cones, the smaller bases of which are fixed to the electrodes, and the larger ones - at the ends of the casing, while the length of the generatrix of the insulator operating under pulsed voltage is made equal to 0.4-0.6 of the length of the generatrix of the insulator operating under static voltage eniyom.

The arrester case is thin-walled cylindrical, made of stainless steel, the electrodes are aligned and consist of a working part of a spherical shape, a non-working part of a cylindrical shape and an electrode leg - down conductor. Conical insulators are made of ceramics and have different generatrix lengths: an electrode with a shortened insulator is connected to the load, and an electrode with an elongated insulator is connected to a capacitor bank and operates under high static voltage. The arrester is filled with technical hydrogen. The spark gap diameter is 84 mm, length 128 mm. The material consumption and inductance of the arrester is approximately 5 times less than that of the analog.

The disadvantage of the prototype arrester is its inability to work as part of a borehole electro-hydraulic installation (with high hydrostatic pressure and pulsed shock loads) due to the small thickness of the housing and the rigid connection of the electrodes to ceramic insulators.

When creating this invention, the problem was solved to ensure reliable working conditions of the inventive spark gap as part of borehole electro-hydraulic installations, where a large hydrostatic pressure of up to 300-500 atm acts on the installation and where the current-carrying and insulating elements of the installation are subjected to shock waves with an amplitude of up to each electrical discharge in the borehole fluid 1000 atm.

The technical result of the invention is to increase the resistance of the arrester to increased hydrostatic pressures and pulsed shock loads.

The specified technical result is achieved in that, in comparison with the known gas-filled spark gap, containing working electrodes with current leads, mounted against each other in a metal case, and insulators in the form of truncated cones, the smaller bases of which are fixed to the electrodes, and the larger ones - at the ends of the case, with a new is that the arrester is placed in a protective metal casing, the current leads are separated from the housing and the protective casing by additional insulators, at least one of the current leads contains an elastic ment.

In addition, the protective casing has connecting elements at the ends in the form of a thread or a flange; additional insulators overlap the current leads along their entire length; current leads and additional insulators are made with the possibility of non-rotation relative to each other and the protective casing; the elastic element in the current output is made of a spring, bellows or braid of the coaxial cable; a shock-absorbing pad is installed between the housing and the protective casing.

The installation of an external protective casing on a gas-filled spark gap eliminates the hydrostatic crushing of the spark gap when the borehole electro-hydraulic installation is located at a great depth. In addition, the outer casing provides protection for the main and additional insulators of the arrester against dirt, oil, water, and accordingly, the electric strength of the arrester does not decrease.

The connection of the working electrodes of a gas-filled spark gap with current leads including elastic elements provides:

- damping of axial mechanical forces arising when a spark gap is connected to a capacitor module and an electric-discharge chamber of a borehole electro-hydraulic installation, and the exclusion of the transmission of axial forces - deformations to electrodes and ceramic insulators of a gas-filled spark gap;

- attenuation of powerful pulsed shocks, which is subjected to the current output of the spark gap connected to the anode of the electric discharge chamber, during electric discharges in the well fluid;

- weakening of the shock load on the vacuum junctions between the working electrodes and the main ceramic insulators of the arrester, which is very important when filling the arrester with hydrogen (the most superfluid gas).

The installation of additional insulators on the current leads reduces the electric field between the current leads and the housing, the external protective casing of the spark gap and eliminates the occurrence of shunting electrical breakdowns between them.

The implementation of current outputs and additional insulators with the possibility of non-rotation relative to each other contributes to the fact that when docking (screwing up) a spark gap with a capacitor module and an electric discharge chamber of a borehole electro-hydraulic installation, the rotation force, which is transmitted through collets to the current leads of the spark gap, is not transmitted further to working electrodes and main ceramic gas-filled spark gap insulators and vacuum junctions between them. Accordingly, there is no destruction of the main ceramic insulators and soldering points and the arrester is not depressurized.

The execution of the ends (ends) of the external protective casing with connecting elements, for example, threads or flanges, simplifies the connection of the spark gap to the capacitor module and the electric discharge chamber of the borehole electro-hydraulic installation and, at the same time, provides good contact conditions for the central current leads and the outer shell of the spark gap with the anodes and casings of the capacitor module and electric discharge chamber of a borehole electro-hydraulic installation.

The installation of a shock-absorbing pad between the arrester housing and the outer protective casing provides increased stability of the gas-filled arrester to external mechanical shocks, which are observed during ground transportation of the downhole electro-hydraulic installation units and during its quick descent directly into the oil well, as well as during accidental drops of the arrester.

Thus, the combination of new distinctive features ensures the performance of the arrester at high hydrostatic pressures, high operating stresses and mechanical shocks.

Figures 1 and 2 show a sectional view of the design of the inventive gas-filled spark gap for a range of operating voltages of 5-6 kV and 30-35 kV, respectively.

Figure 3 shows a photograph of a current lead with an elastic element in the form of a bellows.

Figure 4 shows a General view of the inventive spark gap in a protective casing.

A gas-filled spark gap for a range of operating voltages of 5-6 kV (see Fig. 1) contains electrodes 1 and 2, mounted against each other in a metal case 3, the main insulators 4 and 5 in the form of truncated cones, the smaller bases of which are fixed to the electrodes 1 and 2, and large - at the ends of the housing 3. The working cavity of the arrester is filled with technical hydrogen under a pressure of 3-5 atm. The diameter of the casing 3 of the arrester is 84 mm, length 128 mm. Electrodes 1 and 2 are made of VNZH tungsten alloy, the main insulators 4 and 5 are made of VK94-1 type ceramics.

The arrester is placed in an external steel protective casing 6 with connecting threads at the ends. The thickness and material of the outer casing 6 are selected from a condition of opposing an external hydrostatic pressure of 500 atm. Between the arrester casing 3 and the outer protective casing 6, an elastic gasket 7 is installed. The diameter of the outer protective casing of the arrester is 102 mm, the length of the protective casing is 340 mm.

To the electrodes 1 and 2 of the arrester, cylindrical current leads 10 and 11 are connected through elastic elements (inserts) 8 and 9. The elastic elements (inserts) 8 and 9 are made of thin-walled steel bellows (see figure 3). The cylindrical current leads 10 and 11 are made of brass. The elastic elements (inserts) 8 and 9 are connected to the current leads 10 and 11 by welding.

The current leads 10 and 11 are separated from the housing 3 and the protective casing 6 using additional insulators 12 and 13 made of caprolon. In addition, the current leads 10 and 11 and the insulators 12 and 13 are fixed from rotation relative to each other and the external protective casing 6.

In a gas-filled arrester for a range of operating voltages of 30-35 kV (see Fig. 2), the main parts of items 1-11 are made as in the arrester of Fig. 1, but the additional insulators 12 and 13 are elongated and overlap the current leads 10 and 11 throughout their length. This increases the electrical strength (breakdown voltage) between the current leads 10 and 11 and the housing 3 and the protective casing 6.

Due to the presence at the ends of the protective casing 6 of the arrester of the connecting threads, as well as the fixing of the current leads 10 and 11 and the additional insulators 12 and 13 relative to each other and the external protective casing 6, the arrester is easily connected (screwed) on one side to the condenser module of the borehole electro-hydraulic installation, and with on the other hand, an electric discharge chamber is screwed to it, communicating with the borehole fluid, while the external protective cover of the spark gap is connected to the casing elements of the borehole ovki, and the current outputs of the arrester with a high-voltage current output of the capacitor and the anode of the electric discharge chamber.

During the operation of a borehole electro-hydraulic installation, the spark gap performs the role of a quick-acting short-circuit electric key. The outer casing and one of the spark gap electrodes connected to the anode of the electric discharge chamber are at zero potential during charging of the capacitor module. Another spark gap electrode connected to the high voltage terminal of the capacitor module is under high static voltage. When a static voltage equal to the breakdown voltage for a given interelectrode gap and gas pressure, for example 30 kV, is reached at the high-voltage electrode of the spark gap, a rapid increase in the number of electron avalanches and the formation of a spark channel in the spark gap occur. The result of these processes is the shorting of less than 10 nanoseconds of the electrode gap of the spark gap and the connection of the capacitor module to the electric discharge chamber of the borehole electro-hydraulic installation. Further, the energy from the capacitor module of the installation through the spark gap is transferred within 5-7 μs to the electric discharge chamber, where it is converted into a powerful electro-hydraulic shock (into a shock wave and high-speed hydraulic flow).

The authors designed and manufactured a batch of 10 pcs. gas-filled arresters with the claimed and shown in figure 3, 4 and 5 distinctive features. All arresters passed hydrostatic (up to 300 atm) and thermal (up to + 105 ° C) tests on the basis of the All-Russian Research Institute of Geophysical Well Research (Oktyabrsky, Bashkiria), as well as electrical (up to 42 kV) tests on the basis of the All-Russian Research Institute of Experimental Physics (g. Sarov, Nizhny Novgorod region). Currently, arresters are transferred to pilot operation.

Thus, the claimed spark gap, in comparison with the prototype, satisfies the working conditions in the composition of the borehole electro-hydraulic installations. Compared with the analog, the claimed spark gap has 2 times less length, weight and inductance.

Claims (8)

1. A gas-filled spark gap containing electrodes with current leads mounted against each other in a metal casing, and insulators in the form of truncated cones, smaller bases of which are fixed to the electrodes, and large bases - at the ends of the casing, characterized in that the spark gap is placed in a protective metal casing , the current leads are separated from the housing and the protective casing by additional insulators, at least one of the current leads contains an elastic element. 2. The arrester according to claim 1, characterized in that the protective casing has connecting elements at the ends in the form of a thread or a flange. 3. The arrester according to claim 1, characterized in that the additional insulators overlap the current leads along their entire length. 4. The arrester according to claim 1, characterized in that the current leads and additional insulators are made with the possibility of non-rotation relative to each other and the protective casing. 5. The spark gap according to claim 1, characterized in that the elastic element in the current output is made in the form of a spring. 6. The spark gap according to claim 1, characterized in that the elastic element in the current output is made in the form of a bellows. 7. The spark gap according to claim 1, characterized in that the elastic element in the current output is made in the form of a braid of a coaxial cable. 8. The arrester according to claim 1, characterized in that a shock-absorbing pad is installed between the housing and the protective casing.

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