EA017024B1 - Gas-filled discharger - Google Patents

Abstract

The gas-filled discharger applies to the pulsed high-voltage technology, specifically to the devices of the high current pulsed gas-filled dischargers, intended for use as switching unit in the borehole electrohydraulic equipment. Technical result: decrease of the length, weight and own inductance of discharge while maintaining its electrical strength. The essence of invention: a gas-filled discharger comprising a metal hermetic case and two electrodes with the current lead-outs installed opposite each other on the insulators fixed at the end protrusions of the case. The novelty is that on the side of the internal volume of the discharger the insulators are made in the form of a truncated cone, and on the outside of the dischargerthe insulators are of tubular shape. Additionally, current lead-outs are fixed from the possibility of their rotation in the insulators, the insulators are fixed from the possibility of their rotation in the case; outside of the discharge the surfaces of the insulators are adjacent to the casing and/or to the current lead-outs; the gas filling system of the discharge is installed inside at least one of the current lead-outs and electrodes.

Description

The invention relates to high-voltage pulse engineering, in particular to devices of high-current pulsed gas-filled dischargers, intended for use as switches in downhole electro-hydraulic installations.

Prior art

The gas-filled discharger is known (see R.A. Rafikov and A.A. Gerasimov, USSR Academy of Sciences No. 1402187, class IPC H01 1 17/00, published in BI No. 32, 1990), containing electrodes installed opposite another in a metal case, and insulators in the form of hollow truncated cones, on smaller bases of which electrodes are fixed, and large bases of insulators are fixed on the ends of the case.

The disadvantage of analog is the small length of the generatrix of hollow conical insulators, which leads to low electrical strength of the outer surface of the insulators when placing the discharger in air without excessive pressure; To increase the electrical strength, it is necessary to increase the diameter of the spark gap, however, the diameter of the downhole devices is strictly limited to the diameter of the casing string.

The closest in technical essence to the claimed device is an uncontrollable gas-filled discharger for downhole electro-hydraulic devices, developed at the Institute of Pulse Processes and Technologies (Nikolaev, Ukraine, see the article by K.W. Oiouspko. Wi.G Kitakyko, T11s Guide, Eighsiop spb TekIpd οί and S1Okshd 8khyIs11 ίοτ Sotras! E1es1psa1 Oshsyatde 1pbik1p1 Udshrschep !, 11-ΐΠ 1ЕЕЕ Si1keb Ro Ro \\\ eSteteps, VaShshote, Matyapb, 1997, p.

The discharger contains a metal sealed enclosure and two electrodes with current leads, mounted coaxially opposite each other on insulators mounted on the end protrusions of the enclosure. The gap between the electrodes is 12-13 mm. Electrodes and current leads from them are made of stainless steel or molybdenum and are isolated from the case with the help of long insulators with a developed corrugated surface. Insulators are fixed at the ends of the metal case in their middle part in such a way that the current leads and insulators project approximately half of their length beyond the ends of the case. The discharger housing is filled with nitrogen at atmospheric pressure.

Discharger diameter 90 mm, length 685 mm, inductance 500 nH. The discharger operates at an external hydrostatic pressure of up to 50 MPa (500 atm), temperatures up to 100 ° C, the discharge voltage of the discharger lies in the range 27-31 kV.

The disadvantages of the spark gap of the prototype are the large length of the spark gap, which leads to an increase in the mass and inductance of the spark gap. The high inductance of the arrester, in turn, causes a decrease in the rate of energy input into the discharge channel in the electric discharge chamber and a decrease in the amplitude of the shock wave on the wall of the casing.

Summary of Invention

When creating this invention solved the problem of developing a discharger with insulators of such a configuration that would reduce its length, mass and inductance while maintaining its dielectric strength compared with the prototype.

The technical result of the invention is to reduce the length, mass and self-inductance of the discharger while maintaining its electrical strength.

This technical result is achieved by the fact that compared to the known gas-filled discharger containing a metal sealed enclosure, two electrodes with current leads mounted coaxially opposite each other on insulators mounted on the end projections of the enclosure are new: insulators are made from the internal volume of the discharger in the form of truncated cones, and on the outer side of the arrester insulators have a tubular shape.

In addition, the current terminals are fixed from the possibility of their turning in insulators, and the insulators are fixed from the possibility of their turning in the case; insulators on the outer side of the discharger are adjacent, with their surfaces, to the housing and / or to the current leads; A gas filling system is installed inside at least one of the toggles and electrodes.

The implementation of insulators from the internal volume of the discharger in the form of truncated cones allows you to:

significantly (at least twice) to reduce the electric field on the inner surface of the insulators and increase the electric strength of the spark gap;

at the same time, halve the length of the inner sections of the insulators and, accordingly, halve the length, mass and inductance of the arrester.

To confirm this conclusion, calculations of the electric fields of the claimed arrester and the arrester of the prototype were carried out using contour models made according to the drawings of both arresters (see Fig. 1 and Fig. 3, respectively). It was assumed that a voltage of 35 kV was applied to the electrodes 2 of both dischargers, and the opposite electrodes 3 had a zero potential. The calculations were carried out in the field of an insulator under high voltage.

The results of the calculations are presented in the form of patterns of the distribution of lines of equal potential and the values of the electric field strength at specified points (shown in Fig. 4 and 5 for the prototype discharge gap and in Fig. 6 and 7 for the claimed spark gap).

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It is seen that in the discharger prototype (see Figs. 4 and 5) there is a condensation of lines of equal potential (which corresponds to a high field strength) near the seal of the insulator into the housing and on the radial projections of the corrugated surface of the insulator. In these places, the field strength reaches 3 kV / mm, which is almost equal to the value of the breakdown field strength in the working electrode gap of 3.5 kV / mm. This leads to corona currents and partial discharges on the surface of the insulator, which can further lead to the breakdown of the entire insulator, and therefore it is necessary to unnecessarily increase the length of the insulator to ensure its reliable operation. Those. the arrester - a prototype with long corrugated insulators will work well in the open air, but it is of little use for working inside a tubular metal body that protects the arrester from high hydrostatic pressures in the well.

In the inventive spark gap, the use of insulators in the form of truncated cones on the side of the internal volume made it possible to achieve an almost uniform electric field (see Fig. 6 and 7) with a maximum value of tension at the boundary between the insulator and the gas of only 1.6 kV / mm with the value of breakdown field strength working interelectrode gap of 7 kV / mm. This means that the corona discharges will not develop over the surface of the insulators, although the length of the insulators of the proposed arrester is half the length of the insulators of the arrester of the prototype. Those. The conical shape of the insulators on the side of the internal (gas) volume of the arrester ensures high electrical strength and reliable operation of the invented arrester.

The implementation of insulators on the outer side of the discharger tubular and adjacent, for example, to the housing and / or to the current leads allows you to develop the length of the insulating surface and reduce the length of the outer portion of the insulator of the discharger during axial coupling with other blocks (capacitor module and electric discharge chamber) downhole electrohydraulic installation, which also helps to reduce the length, weight and inductance of the arrester while maintaining its electrical strength;

cover the metal surfaces of a grounded housing and / or high-voltage current leads with a dielectric, which, even if a corona appears on a high-voltage current lead, is an obstacle (barrier) to the electron avalanche path and reduces the likelihood of electrical breakdown between the high-voltage current output and the grounded arrester.

The fixing of the current leads from the possibility of their turning in insulators, and the insulators from the possibility of their turning inside the case, for example, using pins installed in the end holes of the current leads and insulators, insulators and the case ensures the safety of the rubber seals and reduces the likelihood of a depressurization of the spark gap.

Installing at least one of the current leads and electrodes of the gas filling system allows pumping into the internal volume of the spark gap electrical gas, such as nitrogen or gas, relieving the gas pressure inside the spark gap and reconfiguring the spark gap to another operating voltage, blowing the spark gap and cleaning its internal volume from decomposition products. In this case, the location of the gas-filling system in the internal cavity of tubular current leads, where the electric field strength is zero, in no way impairs the electric strength and does not reduce the trigger voltage of the spark gap.

The list of figures drawings and other materials

FIG. 1 shows a sectional view of the inventive gas-filled discharger. FIG. 2 shows a photograph of the insulator of the claimed arrester. FIG. 3 is a schematic sectional view of the spark gap prototype. FIG. 4 and 5 show patterns of the distribution of lines of equal potential and a graph of the electric field strength along the surface of the corrugated insulator in the prototype discharger. FIG. 6 and 7 show patterns of the distribution of lines of equal potential and a graph of the electric field strength along the generator of the conical insulator in the claimed spark gap.

Information confirming the possibility of carrying out the invention

The gas-filled discharger of FIG. 1 contains a metal sealed enclosure 1, two electrodes 2 and 3 with the current leads 4 and 5, mounted coaxially opposite each other on insulators 6 and 7, mounted on the end projections of the housing 1.

On the side of the internal volume of the arrester, the insulators are made in the form of truncated cones (the conical sections of the insulators are indicated by pos. 8 and 9). On the outer side of the arrester, insulators are made in the form of tubes 10 and 11. Tubular ends (sections) 10 and 11 of insulators 6 and 7 are located on the middle radius between the terminals 4 and 5 and the housing 1. Tubular ends 10 and 11 of insulators 6 and 7 can also be pressed to the surfaces of the current leads 4 and 5 or the housing 1 (the diameter of the tubes 10 and 11 may be equal to the outer diameter of the current leads 4 and 5 or the internal diameter of the housing 1).

The gas filling of the discharger is carried out through a thin pipe (pingel) 12 located inside at least one of the current leads 4 or 5 and the holes in the corresponding electrode 2 or 3. After filling the internal volume of the discharger with working gas to the required pressure (for example, up to 0.5 MPa ) the pingel 12 is clamped and hermetically sealed. Alternatively, the gas discharge system of the discharger can also be made similar to the tire inflation system (not shown in Fig. 1).

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The current leads 4 and 5 are fixed by pins 13 and 14 from the possibility of turning inside insulators 6 and 7 when assembling the discharger and docking it to adjacent blocks of the downhole electrohydraulic installation. Insulators 6 and 7 are fixed against rotation inside the housing 1 by nuts 15 and 16.

On the current leads 4 and 5 and the insulators 6 and 7 are installed rubber or fluoroplastic seals 17, 18 and 19, 20, which ensure the tightness of the internal (gas) volume of the spark gap.

The housing 1 has connecting elements at the ends in the form of threaded sections, which allow the arrester to be joined with other electro-hydraulic installation units.

The internal volume of the spark gap is filled with nitrogen under an overpressure of 0.3-0.5 MPa (3-5 atm).

In a prototype of a spark gap, a section of which is shown in FIG. 1, case 1 is made of steel 45 or 30ХГСА and has connecting threads М95х2 at the ends. The thickness and material of the housing 1 are selected sufficient to ensure the mechanical strength of the housing when exposed to an external hydrostatic pressure of 30 MPa (300 atm.). Electrodes 2 and 3 are made of tungsten alloy VNZh7-3, current leads 4 and 5 are made of brass or stainless steel, insulators 6 and 7 are made of caprolon (polyamide) grade PA6 or diflon. Discharger diameter 102 mm, length 340 mm, inductance 52 nH, weight 7 kg.

When assembling, the claimed discharger using threaded sections in the housing is connected on the one hand to the capacitor module of the downhole electrohydraulic installation, and on the other hand to the electric discharge chamber, while the case of the arrester constitutes a fragment of the case of the downhole electrohydraulic installation, and the terminals are electrically connected to the corresponding terminals of the above modules electrohydraulic installation.

When the downhole electrohydraulic installation is in operation, the arrester plays the role of a high-speed electric key. Before actuation of the discharger, the electrode 2 and the current terminal 4 connected to the capacitor module are at a high voltage equal to the charge voltage of the capacitor module, and the electrode 3 and the corresponding current terminal 5 electrically connected to the electric discharge chamber are at a zero potential. When the voltage of the charge of the capacitor module reaches the breakdown voltage of the interelectrode gap of the discharger, the latter is triggered and in a short time (10-20 ns) connects the capacitor module to the electric discharge chamber. In this case, a breakdown of the fluid gap occurs in the chamber, which is accompanied by a hydraulic shock transmitted to the wall of the casing.

The authors manufactured and tested several gas-filled arresters with declared distinguishing features. All dischargers have withstood hydraulic tests (external pressure up to 40 MPa (400 atm)) and tests for heating up to 105 ° C. Electrical tests were also conducted in which a voltage up to 42 kV was applied to the discharger, and the amplitude of the current through the discharger reached 30 kA. In the process of all the tests, the arrester insulators worked without breakdowns on their surface.

Thus, in the claimed spark gap, compared with the prototype, the length is reduced by about 2 times (from 685 to 340 mm), the inductance is 10 times (from 500 to 52 nH) and 2.3 times the weight (from 16.1 to 7 kg ) while maintaining its electrical strength at the level of 40-42 kV.

Claims (5)

1. A gas-filled spark gap containing a metal sealed housing, two electrodes with current leads mounted coaxially opposite each other on insulators mounted on the end protrusions of the housing, characterized in that the insulators are made in the form of truncated cones on the inside of the spark gap and on the outside of the spark gap insulators are tubular. 2. Gas-filled spark gap according to claim 1, characterized in that the current leads are fixed from the possibility of their rotation in insulators. 3. Gas-filled spark gap according to claim 1, characterized in that the insulators are fixed from the possibility of their rotation inside the housing. 4. Gas-filled spark gap according to claim 1, characterized in that the insulators on the outer side of the spark gap adjacent their surfaces to the housing and / or to the current leads. 5. The gas-filled spark gap according to claim 1, characterized in that a gas-filling system is installed inside at least one of the current leads and electrodes.