RU2185506C2 - Electrohydropulsing downhole device - Google Patents

Abstract

FIELD: equipment for stimulation of bottom-hole zones of oil-gas-water bearing wells and grouting slurry for forcing into well annulus. SUBSTANCE: electrohydropulsing device has a hollow body serving as negative electrode with windows covered by circular membrane and filled with working fluid. The body accommodates throttle, check valve and positive electrode with insulator. Positive electrode is electrically connected with pulse currents generator. Working surfaces of positive and negative electrodes are made with high resistance to electrochemical corrosion, for instance, from technical copper. Working fluid is used in the form of solution of salt with alkaline properties in water with pH above 10, for instance, solution of soda ash in water with concentration of 0.1-0.3 g/l. EFFECT: provided parameters of pressure pulses at initial level in producing discharges generated by electrohydropulsing device during entire cycle of well treatment. 4 cl, 3 dwg, 1 tbl

Description

 The invention relates to electrohydropulse devices for influencing the bottom-hole zone of oil and gas wells with the aim of cleaning the perforation zones, well filters and increasing the permeability of the reservoir during the production of oil, gas, water and other minerals, as well as for acting through the casing to the grouting cement after it sales to the annulus to improve the quality of casing cementing in the well.

 Known electrohydropulse downhole device according to the author's certificate of the USSR 1457489, MKI 4, E 21 V 43/24, which contains a hollow body filled with dielectric fluid and made with windows covered by an annular membrane, a central electrode with an insulator placed in the body, a pulse current generator, electrically connected to the central electrode, while in the housing there are output channels located in the upper part of the cavity formed by the membrane and overlapped on the outer surface by an elastic ring.

 Signs that coincide with the essential features of the claimed invention are the following: a hollow body, which is a negative electrode, filled with liquid and made with windows covered by an annular membrane, and with an output channel, a central electrode with an insulator placed in the body, a pulse current generator, electrically connected with a central electrode.

 The reasons that impede the achievement of the required technical result in this device include the fact that during the reproduction of discharges in a dielectric liquid filling a closed discharge chamber, its conductivity increases due to the appearance of charged particles (ions) in the liquid volume under the influence of high pressures and temperatures in the discharge channel and electrochemical corrosion of the electrode material. An increase in the electrical conductivity of the fluid leads to an increase in pre-breakdown energy losses, a change in the parameters generated during the reproduction of shock waves in the direction of decreasing the amplitude of the pulse and, accordingly, reducing the effectiveness of the impact on the formation. A gradual increase in pre-breakdown losses of electric energy in each subsequent discharge due to an increase in the conductivity of the working fluid can continue until breakdown discharges are not accompanied by the appearance of pressure waves. At the same time, the resource number of pulses planned for one tripping operation is also reduced.

 An electrohydropulse downhole device (according to application 94033234 dated 03/09/94, MKI 5 E 21 V 43/24, publ. BI: Promislova Vlasst, 2, 1997, p. 2.52) containing a hollow body, which is a negative electrode, was selected as a prototype. made with windows overlapped by an annular membrane and with an output channel, a central electrode with an insulator, a pulse current generator electrically connected to the central positive electrode, and equipped with a check valve and an inductor, and the cavity formed by the hollow body and the annular membrane is filled with p with liquid.

 Signs that coincide with the essential features of the claimed invention are the following: a hollow body, which is a negative electrode, filled with a working fluid and made with windows covered by an annular membrane, a central positive electrode with an insulator placed in the housing, a pulse current generator electrically connected to the central positive electrode, check valve and throttle.

 The reasons that impede the achievement of the required technical result include the fact that, as electric discharges are reproduced in the working fluid filling the cavity formed by the hollow body with windows covered by an annular membrane, the electrical conductivity of the fluid increases due to the formation and accumulation of conducting particles in it, formed in the plasma of the discharge channel, the amount of which increases when metal electrodes of complex chemical composition, for example, steels, are used. Chemical additives in metals, such as sulfur, react during the discharge under conditions of high pressures and temperatures in the discharge channel, forming sulfuric acid. In the same way, nitric acid can form when reacted with air nitrogen (Malyushevsky P. P., Godovannaya I. N., Vishnevsky V. B. et al. Changes in the electrical conductivity of distilled water under the influence of an electric explosion. Electronic processing of materials, 1987.- 5 , p. 62-64) and other acids.

 An increase in the electrical conductivity of the liquid filling the discharge chamber leads to an unstable operation of the device due to an increase in the breakdown losses of electric energy and, accordingly, to a decrease in the amplitude of the emitted pressure waves and a reduction in the resource number of breakdown discharges reproduced per one tripping device. The increase in the conductivity of the working fluid is greater, the more energy was released in a unit volume of the discharge chamber. That is, an increase in electrical conductivity is most significant for closed-type small-volume discharge chambers (P.P. Malyushevsky, Z.K. Krivitskaya, A.Z. Nemirovsky, etc. On the effect of high-energy discharges in water on the resistivity of the working medium of discharge chambers - Electronic processing of materials. 1978. - 4.-p.40-45).

 The basis of the invention is the task to improve the electrohydropulse downhole device, which will ensure the stability of the parameters of the pulses of the pressure waves generated during operation of the device, and thereby increase the efficiency of the device.

 The essence of the invention lies in the fact that in an electrohydropulse downhole device containing a hollow body, which is a negative electrode, made with windows covered by an annular membrane, and filled with a working fluid, in which a throttle, a non-return valve and a central positive electrode with an insulator are placed, electrically connected to pulse current generator, according to the invention, the working surfaces of the positive and negative electrodes are made of metal with high resistance to electrochemical tion of corrosion, for example of copper technology. As a working fluid, a salt solution with alkaline properties in water with a pH of more than 10 was used, for example, a solution of soda ash in water. A solution of soda ash in water may have a concentration of 0.1-0.3 g / l.

 Revealing the causal relationship between the essential features of the claimed device and the technical result, the following should be noted.

 Distinctive features of the invention: the implementation of the working surfaces of the positive and negative electrodes of metal with high resistance to electrochemical corrosion and the use as a working fluid of a salt solution with alkaline properties in water with a pH of more than 10 in combination with the known features of the device ensure the removal of the process fluid from the working fluid the operation of the device of conductive particles. The electrical conductivity of the working fluid does not increase, pre-breakdown losses of electrical energy do not increase, due to which stable parameters of pressure pulses generated during operation of the device are ensured.

 The invention is illustrated by drawings. Figure 1 presents a General view of the submersible part of the electrohydropulse downhole device; figure 2 shows the lower part of the device; figure 3 is a radial section of the lower part of the device.

 Electrohydropulse downhole device contains a sealed detachable housing consisting of upper 1 and lower 2 parts. The upper part 1 of the housing is connected to the ground part by a wireline cable (not shown), which provides the device to be raised and lowered in the well, as well as to supply power to it. The positive electrode 3 is placed in the insulators 4. In the lower part 2 of the casing, which is the negative electrode, there are windows 5 located along the perimeter opposite the working part of the positive electrode 3. The casing generatrix in this zone is made in the form of an annular elastic membrane 6 overlapping the windows 5.

 The positive electrode 3 is located in the sealed cavity 7 filled with the working fluid, formed by the lower part 2 of the casing with windows 5 covered by an annular membrane 6. In the lower part 2 of the casing, an additional cavity 8 is made above the cavity 7. It has a check valve 9. The upper part of the additional cavity 8 above the check valve 9 communicates with the cavity 7 through the throttle 10.

 The working surfaces 11 and 12 of the central positive electrode 3 and the negative electrode - the lower part 2 of the housing are made of metal with high resistance to electrochemical corrosion, for example, technical copper.

 The cavity 7 is filled with a working fluid in the form of a salt solution with alkaline properties in water with a pH greater than 10, for which, for example, a solution of soda ash in water with a concentration of 0.1-0.3 g / l can be used.

The device operates as follows. When applying high voltage from the pulse current generator to the electrodes, the discharge develops from the working surface 11 of the positive electrode 3 in the direction of the working surface 12 of the negative electrode - the lower part 2 of the housing. Moreover, the working surfaces of the electrodes 11 and 12 are made, for example, of technical copper. Acids are formed in the working fluid during discharges, with respect to which copper is neutral. Soda ash, which is part of the working fluid, reacts with the acids formed during the operation of the device, reacts with them with the formation of unstable carbonic acid, which decomposes into gaseous products of CO ₂ and H ₂ , which helps to remove conductive particles from the solution. The amount of soda dissolved in water should be sufficient to neutralize the acids formed during the discharge. The electrical conductivity of the working fluid does not increase and the breakdown losses of electrical energy do not increase, which ensures the stability of the parameters of the generated pressure waves.

 Further, the shock wave generated during the discharge propagates in the fluid filling the cavity 7 and passes through the membrane 6 into the external medium. The expanding post-discharge cavity causes fluid movement in the cavity 7 and beyond, since the elastic membrane 6 practically does not affect the hydrodynamic processes. Thus, the elastic membrane 6 provides for the transmission of intense shock waves to the bottomhole with stable discharge-to-discharge maximum parameters for the given initial characteristics of the pulse current generator, which allows to increase the efficiency of the device when the hydraulic flows affect the walls of the well and formation.

The results of experiments conducted in laboratory conditions are shown in the table. In this case, the electrodes were made of technical copper. The working fluid in the first case was a solution of sodium chloride NaCl in distilled water with a concentration that provided an initial optimum conductivity of the working fluid of 0.025-0.05 S / m (according to Ukrainian patent 18912 A, IPC 5 E 21 B 43/25. The electrode system for electro-hydraulic stimulation of the formation / Trofimova L.P., Poklonov G.G., Zhekul V.G. - Submission date 09.24.93), and in the second, in accordance with the invention, a solution of soda ash Na ₂ CO ₃ in distilled water with a concentration of 0.1-0.3 g / l, also about 0.025-0.05 espechivayuschey conductivity S / m.

 If the concentration of the initial solution providing the initial conductivity of the working fluid is less than 0.1 g / l, then the required amount of soda in the solution is not enough to neutralize the acids formed during the discharges, and the conductivity of the working fluid during the discharges will increase, which will lead to an increase in the breakdown losses energy and, accordingly, to reduce the efficiency of the device.

 If the concentration of the soda ash solution is more than 0.3 g / l, then the initial electrical conductivity of the working fluid will be greater than the electrical conductivity (σ == 0.05 S / m), which is necessary for discharges with the lowest breakdown losses of electrical energy, which also leads to a decrease in efficiency device operation.

In this case, the electric capacitance was C = 1.6 μF, the charging voltage U ₀ = 30 kV. The experiments were carried out at normal temperature.

 After 1000 discharges, the conductivity of the working fluid was measured. The measurement results showed that in the first case, the electrical conductivity of the liquid increased by 22%. Whereas the second remained almost unchanged.

 Thus, the implementation of both electrodes of industrial copper, and the working fluid in the form of a solution of soda ash, leads to the fact that the conductivity of the working fluid during discharges practically does not increase, thereby ensuring minimal loss of electrical energy at the prebreakdown stage throughout the entire cycle of reproduction of discharges. This ensures that the parameters of the pressure pulses are maintained at the initial level and, ultimately, increases the efficiency of well treatment with electrohydropulse devices.

Claims (4)

 1. Electrohydropulse downhole device containing a hollow body, which is a negative electrode, made with windows covered by an annular membrane, and filled with a working fluid, which contains a choke, check valve and a positive electrode with an insulator, electrically connected to a pulse current generator, characterized in that the working surfaces of the positive and negative electrodes are made of metal with high resistance to electrochemical corrosion, and using salt solution with alkaline properties in water with pH greater than 10.  2. The device according to claim 1, characterized in that the working surfaces of the electrodes are made of technical copper.  3. The device according to claim 1, characterized in that a solution of soda ash in water is used as the working fluid.  4. The device according to p. 3, characterized in that the solution of soda ash in water has a concentration of 0.1-0.3 g / L.

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