RU2208142C2 - Electrohydraulic percussi device for activation of oil and gas-bearing formation and method of device power supply - Google Patents

Abstract

FIELD: oil and gas producing industry; applicable in stimulation of producing wells and increase of injectivity of injection wells and increase of recovery from producing formations of gas- condensate and oil and other deposits of liquid and gaseous minerals. SUBSTANCE: electrohydraulic percussion device consists of air and fluid dischargers. Adjacent to one of air discharger electrodes is air electric conducting duct. The other electrode is connected to casing string which has internal and external electric insulation coatings. Fluid discharger consists of two electrodes. Positive electrode serves as filter, and negative electrode is grounded and made in form of metal rod secured on insulators in filter. Provided above well in close to ground layer of atmosphere is air electric conducting duct for supply with power and provision of operation of electrohydraulic percussion device. Air electric conducting duct is made in form of metal conductor lifted and supported in atmosphere layer close to ground, or duct formed by laser beam or directed bunch of charged particles. Said duct is used for trapping and transfer of atmospheric charges to air discharger. Pulses of high-voltage current formed on air discharger are transmitted to fluid discharger. Electric break-down of fluid gap take place between filter and rod. As a result, formed hydraulic shock wave produces dynamic or other action on filter zone of producing formation. EFFECT: provided use of atmospheric electricity for stimulation of oil-gas formation, extended technical potentialities of device, and its simplified design. 2 cl, 1 dwg

Description

 The present invention relates to the field of production of liquid and gaseous minerals from boreholes, and in particular to technical means for activating and stimulating wells by an electrohydroshock method, and can be used to stimulate production and increase the injectivity of injection wells and increase the return of productive formations of gas condensate-oil and other liquid oil fields and gaseous minerals.

 To date, a number of methods have been developed to influence the oil, gas condensate and water wells, including physical, mechanical, hydraulic, chemical, thermal, and others, on the filter zone. Of particular interest are methods of dynamic (shock) impact on the reservoir, since these methods certain geological conditions are less energy intensive and technically more efficient.

 One of such methods is the electrohydroshock method based on the electrohydraulic effect of Utkin [1]. The electro-hydraulic effect (hereinafter EGE) has found quite widespread use in industry, including mining [2]. With regard to the activation of oil and gas bearing aquifers, the stimulation of production and increasing the injectivity of injection wells during electro-hydraulic shock in the prefilter zone of the productive formation, rock particles are destroyed, displaced and removed from the cracks and pore channels, old ones are expanded and new microcracks are formed, the filter is decolmated, and it comes into vibrational motion in-situ fluid. In addition, the electromagnetic and thermal radiation that occurs during electrical exposure of the oil and gas bearing formation melt the asphaltene-paraffin deposits, which also contributes to enhanced oil recovery.

 Several types of downhole electrohydro-shock devices are known [3-5]. An electric shock unit for enhancing oil recovery [3] is a borehole generator of electro-hydraulic pulses (a pulse current generator or GIT), lowered into the well on a cable-rope by means of a lifting and lifting device. The electro-hydraulic generator contains the following blocks: a transformer-rectifier block, a block of high voltage capacitors, a control arrester with a start block, and two discharge electrodes, one of which is movable. The downhole generator has a diameter of 114 mm, is designed for a pressure of 25 MPa and is powered by a current source with a voltage of 127 V (discharge voltage 30 kV).

 The disadvantages of the unit are the complexity of the design of the generator of electro-hydraulic pulses, the difficulties of its operation.

 Known installations for restoring and increasing the flow rate of water wells by electrohydraulic shock [4, 5].

 A typical installation [5] - a prototype located on a vehicle platform, contains a GIT and a lifting winch with a high-voltage cable, at the end of which a liquid (working) spark gap is fixed. GIT consists of a charger, a capacitor bank and an air (forming) spark gap. A coaxial cable RK-50 with an operating voltage of 50-80 kV is used as a current lead for transmitting high-voltage current pulses from a gas generator to a liquid discharger. The charger is powered by a voltage source of 220-380 V. The output voltage of the GIT is 30-60 kV.

 The disadvantages of an electrohydroshock installation with a surface GIT location are limited technical capabilities (the depth of the treated wells does not exceed 100-150 m), the relative complexity of the design.

 The most critical unit of electrohydroshock installations is a liquid discharger, lowered into the filter part of the well together with the downhole pumping unit on a low-voltage cable, or on a high-voltage cable, which acts as a conductor for transmitting high-voltage pulses. To date, a number of designs of liquid dischargers have been developed. For example, arresters with a tip-plane electrode system and ring electrodes consist of a steel housing, inside of which a cable is located in an insulating tube of vacuum rubber [4]. The latter is connected to a positive electrode, which is a metal rod or tube mounted inside a fiberglass insulator. The prototype device has a liquid discharger with a disk-shaped base of the negative electrode [5]. The arrester consists of a positive electrode attached to a coaxial high-voltage cable, an insulator and a negative electrode.

 There is only one way of supplying electro-shock installations with electric current - from industrial current sources with a voltage of 127-380 V via a low-voltage cable. In this case, there are two methods for transmitting high-voltage current pulses from the GIT to a liquid discharger. According to the first of them, the high-voltage pulses generated by the borehole GIT, here, through a metal conductor, enter a liquid discharger located in the immediate vicinity of the air discharger [3]. According to the second method, from the GIT located on the surface of the earth, high-voltage pulses are transmitted to a liquid discharger via a high-voltage electric cable [5].

 The disadvantages of existing methods of transmitting high voltage current pulses are as follows. During the generation of current pulses directly in the well, the design and operation of the electrohydroshock installation is complicated. When transmitting high-voltage current pulses into the well from the surface of the earth, a high-voltage cable is required, the active and inductive resistances of which significantly reduce the transmission efficiency of electric energy and, accordingly, reduce the technical efficiency of the electro-shock installation.

 A known method of using a metal lightning rod for channeling an electric current into a coal or oil formation in the bowels of the earth (US 5417282). This method can be implemented if thunderstorm activity occurs in close proximity to the surface of the earth, since a low lightning rod has low efficiency.

 The task is to simplify the design of the electro-impact device and increase its technical capabilities.

 This problem is solved by using a natural source of electric energy, namely atmospheric electricity, channeled into the bowels of the earth through an air-conducting channel for processing the oil-and-gas stratum of the oil and gas bearing zone.

 The essence of the proposed technical solutions is as follows.

 The electrohydropercussion device consists of two arresters - air, located on the surface in the immediate vicinity of the wellhead, and liquid, which is located in the filter part of the production casing. One of the electrodes of the air gap is in contact with the air conductive channel (lightning rod), the other electrode is connected by a conductor to an electrically insulated production casing, which serves as a current lead for high voltage pulses taken from the air gap and transferred to the liquid gap. A liquid discharger consists of two electrodes - a positive one, which is used as a filter, and a negative one, made in the form of a metal rod and fixed on the insulators in the filter.

 A method of powering an electro-impact device with electricity is as follows.

 An electrically conductive channel is created above the borehole in the atmospheric surface layer, made in the form of a metal conductor, raised and supported in the atmospheric surface layer, or a channel created by a laser beam or a directed beam of charged particles. This channel carries out the overflow of atmospheric electric charges, from which high-voltage current pulses are generated and transmitted through the production string to the downhole filter, which is the positive electrode of the liquid discharger.

 Further, the essence of the invention is illustrated by the drawing, which shows the design of the gas condensate-oil well and the wiring diagram of the electro-impact device.

Before explaining the essence and procedure for implementing the proposed technical solution, it is necessary to clarify the following. It is well known that a lightning electrical discharge (lightning) has a fairly large power. It is known that the strength of the discharge current is 10 ² -10 ⁵ A, and the electric field strength reaches a value of 15 kV • m ^-1 . It was experimentally established that with a direct lightning strike into a borehole, the maximum current density at the casing string can reach 30 A • m ^-2 [6]. This value of the discharge current is quite sufficient to create a powerful hydroshock wave during an electric discharge in a liquid. There are also known methods of sewage atmospheric electric charges at a given point on the surface of the earth [7]. This method is carried out by creating an artificial air conductive channel. All this is a proof of the technical feasibility of using atmospheric electricity for testing an electrohydroshock installation when activating and exciting oil and gas bearing strata of a gas condensate field.

 Electrohydrodynamic device for activating the oil and gas bearing formation consists of two arresters - air 1 and liquid 2. Air discharger 1 is located in the immediate vicinity of the wellhead or fixed to the casing 3. One of the electrodes 4 of the air discharger is in contact with the air conductive channel (lightning rod) 5, the other electrode 6 is connected by a conductor 7 to the production casing 3. The production casing 3 has an inner and outer electrical protective coating 8 (to exclude with insulating properties leakage current) and cemented in the technical casing 9 grout 10 (to prevent electrical breakdown at the technical column). In turn, the technical column 9 is cemented in the conductor 11. The liquid discharger consists of a positive electrode, whose role is played by a filter 12, and a negative electrode 13. The electrode 13 is made in the form of a metal rod or pipe fixed axially in the filter 12 by means of insulators 14. It has long enough to ensure reliable contact with the rock and minimal electrical grounding resistance.

 An air-conducting channel 5 can be a metal conductor that is lifted and supported in the surface layer of the atmosphere by an aircraft, for example, a balloon, a radio-controlled model. Channel 5 can be created by a laser beam or a directed beam of charged particles, such as electrons or protons.

 Power electrohydraulic impact device and its operation is as follows.

 When approaching the oil and gas field of a thunderstorm front, depending on the height of the maximum electrical discharges in the atmosphere, an air-conducting channel 5 is created above the well in the surface layer of the atmosphere. It can be formed by a laser beam directed by a beam of charged particles (electrons, protons) or metal a conductor lifted in the surface layer of the atmosphere by an aircraft, such as a balloon. Electric charges flow down from the surrounding atmospheric layers through this channel and electricity is transferred to the air gap 1. When a certain potential difference is reached between the electrodes 4 and 6 of the spark gap, an electrical breakdown of the air gap 15 occurs and a high-voltage electric current pulse is transmitted through conductor 7 to casing production string 3. Moving along the string, the current pulse reaches the positive electrode - filter 12, where the electric the battle of the liquid interelectrode gap 16. The hydraulic shock wave that occurs during breakdown acts on the oil and gas reservoir 17, exciting it and stimulating oil and gas recovery. After a series of studies, the well is tested and, with unsatisfactory results, the development is repeated.

 The proposed technical solutions during implementation give the following advantages: "free" natural electric energy is used, the design of the electro-hydropercussion device is simplified (due to the exclusion of GIT and electric cables), the technical capabilities of the installation are increased (due to the reduction of active and inductive losses, the formation of more powerful current pulses and etc.).

Sources of information
1. Yutkin L.A. Electro-hydraulic effect. M.-L, Mashgiz, 1955.

 2. Yutkin L. A. Electro-hydraulic effect and its application in industry. L., "Engineering", 1986.

 3. Sereda N. G. and others. Sputnik oilman and gasman. Directory. M., "The bowels", 1986.

 4. Gavrilko V. M., Alekseev V. S. Drill hole filters. M., "The bowels", 1985.

 5. Bashkatov D. N. and others. Special work in the drilling and equipping of wells for water. Directory. M., "The bowels", 1988.

 6. Karjakin P.N. Lightning protection properties of casing boreholes. Industrial Energy, 7, 1998.

 7. Kachurin L.G. The physical basis of exposure to atmospheric processes. Experimental physics of the atmosphere. L., "Hydrometeoizdat", 1990.

Claims (2)

 1. Electrohydrodynamic device for activating an oil and gas bearing formation, including a source of electricity, connected through an air gap to a conductive pipe with a liquid discharge located in the filter section of the well, characterized in that the lead is made in the form of an isolated casing production string, an air conducting channel is adjacent to one electrode of the air gap for communication with a source of electricity, and the other electrode of the air gap is connected by a conductor to an electrically insulated casing production string, while the positive electrode of the liquid gap is a filter, the negative electrode of the liquid gap is grounded and made in the form of a metal rod mounted on insulators inside the filter.  2. A method of supplying electricity to an electric shock device for activating an oil and gas bearing formation, comprising receiving an electric current from an electricity source, generating high voltage current pulses from an electric current using an air gap and transmitting them through a current path to a liquid discharge to conduct an electric discharge in the well, characterized in that atmospheric electric charges are used as a source of electricity, obtaining electric current and forming High-voltage current pulses are transferred from it by transferring atmospheric electric charges to the air gap by creating an air-conducting channel above the borehole in the surface layer of the atmosphere, made in the form of a metal conductor, raised and supported in the surface layer of the atmosphere, or a channel created by a laser beam or a directed beam charged particles, and a casing string is used as a current lead.