RU2415257C1 - Procedure for stimulation of oil output and equipment for its realisation - Google Patents

Abstract

FIELD: gas-and-oil producing industry.

SUBSTANCE: according to procedure payout bed is effected with electro-magnetic resonance by means of sources of electro-magnetic oscillation immersed into wells. These oscillations are excited with electric dipoles arranged in each pressure and producing wells. Inputs of all electric dipoles of pressure wells are connected to one circular feeding cable. Electric dipoles placed in each producing well are connected to another circular feeding cable. Also, during the first time half-cycle voltage supplied to input of dipoles installed in the pressure wells is of higher amplitude and opposite polarity, than voltage supplied to input of dipoles in producers during the second time half-cycle. The said circular cables are fed in pairs as oil is extracted from volume of the bed enveloped with working inter-well circular electric dipole. Feeding voltage is switched to a following pair of circular electric dipoles. Supply of power of said intra-well circular electric dipoles is coordinated with extracted summary output of producers; when it decreases, power consumption of operating circular electric dipole is increased maintaining output within maximal limits.

EFFECT: raised oil output of bed due to controlled different-pulse electro-magnetic effect to intra-well space facilitating flow of residual oil to side of producers.

8 cl, 8 dwg

Description

The invention relates to methods for the development of oil and gas condensate fields and devices for their implementation and can be used in the oil industry, as well as during electrical exploration in geology, geophysics, mining.

A known method for the development of oil and gas condensate fields, in which wells are usually arranged in rows arranged along the oil contour and the supply circuit. Therefore, the number of simultaneously operating rows of wells rarely creates more than two or three, and subsequent rows include as the oil contour approaches. When the water has approached the first row, it is turned off and one of the following rows is turned on, etc. The disadvantage of this method is the uncontrolled movement of the oil circuit, as well as the lack of the possibility of influencing its movement (Charny I.A. Underground gas and gas dynamics. State Scientific and Technical Publishing House of Oil and Mining and Fuel Literature, Moscow: 1963, pp. 110-111, 186 -193).

There is also known a method of developing an oil and gas condensate field by determining the field contour along the boundary of oil-water contact, drilling rows of production and injection wells, pumping water through injection wells, extracting formation fluids through production wells and performing wave action on the water-oil part of the formation from ground-based wave energy sources, according to which additionally simultaneously with the wave action they act with electromagnetic waves from electromagnetic generators. In this case, electromagnetic generators are placed beyond the contour of the field and the magnitude and amplitude of electromagnetic waves is determined for each generator. By exposure to electromagnetic waves, they create a driving force in the formation directed to the producing well, and monitor the progress of the oil-water contact and maintain its similarity to the initial position (RU patent No. 2049912, E21B 43/20, 43/18, G01V 3/12, prototype for equipment).

Equipment for implementing this method of developing an oil and gas condensate field includes ground-based wave energy sources located inside the field circuit, geophones and geophones located near wellheads, flow meters and actuators. In addition, beyond the field contour, the indicated equipment is equipped with electromagnetic wave generators located on vehicles and a central automated data processing center. Each electromagnetic wave generator is made in the form of a conical body suspended on a ball bearing, a stepped conical dielectric frame mounted inside the body, dipoles in pairs located on the frame steps, the diameters of which are commensurate with the diameters of the steps, a conical energy concentrator installed in the center of the steps, and a flange placed on its movable axis. At the same time, geophysical stations, geophones, flowmeters, executive bodies of wells, electromagnetic wave generators and vehicles are connected with a central automated data processing center. The latter manages the electromagnetic radiation of the formation, receives, processes incoming information during field development, transfers commands to the executive bodies of vehicles, generators, production and injection wells and geophones. The treatment of the oil reservoir is carried out taking into account the increase in the controlled flow rate of Q wells. When Q decreases below a predetermined value, the corresponding actuator issues commands to search for the current value and the oscillation frequency of the electromagnetic oscillation generator, which process the oil reservoir with an increase in flow rate to its possible maximum and hold at this achieved level.

The disadvantages of the indicated method and equipment include unproductive energy losses during the passage of electromagnetic waves through the rock thickness of about 3 km or more to an oil-containing formation.

There is also known a method of intensifying oil production and resuscitation of idle wells by electromagnetic resonance effects on the reservoir, in which using resonant-wave generators located on the surface or submerged in the well, electromagnetic oscillations are created in the reservoir, which superimpose the natural frequency of vibrations of hydrocarbon fluids formation, forming resonant electromagnetic waves, and control the resonant waves using placed on the surface equipment. At the same time, modulated electromagnetic oscillations of the same frequency are generated in the reservoir, directed from the producing well and counter to at least one producing well. Resonant electromagnetic vibrations are generated, causing vibrations of molecules and atoms of a hydrocarbon fluid with a peak resonant amplitude in a vertical, horizontal or other plane (RF patent application No. 2008128076, decision to grant a patent of 08/20/09, prototype). Initially, the wave flow from the producing well is set to a power significantly exceeding the power of each of the oncoming flows, and then it is reduced with a simultaneous proportional smooth increase in the power of the oncoming wave flows. The method is carried out using electromagnetic wave generators, placing them above the wellhead or directly in the perforation zone of producing and injection wells. These generators create counter-directional oscillatory flows in the reservoir. The control equipment and the generator-receiver of scanning oscillations are located on the surface.

The disadvantages of this technical solution include the fact that it is most effective for isotropic environments of occurrence of an oil reservoir, whereas under natural conditions of occurrence of an oil reservoir, a pronounced anisotropy of its properties can be observed. In this case, counterpropagating waves, choosing directions with the least resistance to movement, will propagate in different directions and the peak resonance of moving fluids may not occur and the desired increase in oil recovery will not be obtained, which will lead to a decrease in the efficiency of the method, including due to overhead costs of electricity.

The objective of the invention is to increase the efficiency of the method.

The technical result of the invention is the enhancement of oil recovery due to the organization of a regulated, multi-pulse electromagnetic effect on the interwell space, which effectively ensures the movement of residual oil in the direction of producing wells.

The specified technical result is achieved due to the fact that in the method of intensifying oil production, in which an electromagnetic resonance effect is applied to the reservoir using sources of electromagnetic waves immersed in the wells, electromagnetic waves are generated in the reservoir, which are superimposed on the natural vibration frequency of the hydrocarbon fluid , these electromagnetic waves create directed from the producing well and counter, at least from one of the nearest the neighboring well in the direction of the producing well, control the indicated electromagnetic oscillations with the help of equipment located on the surface, monitor the progress of the oil-water contact and preserve its similarity to the initial position, according to the invention, these electromagnetic oscillations are excited using electric dipoles, which are placed in each of the injection and producing wells, the inputs of all of these electric dipoles of injection wells are connected to one annular supply a cable to it, electric dipoles placed in each production well are connected to another annular supply cable, and a voltage of a higher amplitude is applied to the input of dipoles installed in the injection wells in the first time half-period than in the second time half to the input of dipoles installed in the production wells, and of opposite polarity, said annular cable is fed in pairs, wherein each of the n _i pair consisting of said circumferential cables arranged around the perimeter of extractive and naked etatelnyh wells when submitted to them a supply voltage, operates as n; covering the corresponding interwell annular space of the interwell annular electric dipoles generating electromagnetic pulses that act on the oil ions in the direction of their movement towards the producing wells, as oil is produced from the reservoir volume covered by the working interwell annular electric dipole, the supply voltage is switched to the next pair of annular electrical loads, while the electric dipoles of each subsequent row of production wells are fed as electric Pressure dipoles of injection wells, and electric dipoles of each subsequent row of production wells as electric dipoles of the current row of production wells, the power supply of these interwell annular electric dipoles is coordinated with the resulting total production rate of production wells, while decreasing the energy consumption of a working ring electric dipole is increased, maintaining the flow rate to the maximum extent.

It is also advisable to additionally place concentric relative to the rows of production and injection wells equipped with devices for controlling the frequency of the oscillation and the amplitude of the mechanical impulse of the force acting on the reference earth’s area, mechanical multi-pulse vibrators, with the help of which additional compression waves are applied to the oil reservoir in resonance with electromagnetic action and rarefaction at an angle to the surface of the oil-containing formation, the planes of which are on ravleny radially toward the injection well, the magnitude of said angles is selected constructively with the greatest possible force projection on the upper surface of the processed wave resonance action of the oil reservoir, wherein said mechanical vibrators include raznoimpulsnye after the electromagnetic generators or simultaneously with them.

In addition, in each production well, a device is installed to create multi-pulse hydraulic vibrations, with which a vacuum is created in the near-well zone of the oil reservoir.

The indicated technical result is also achieved by the fact that in the equipment for the intensification of oil production, including a mobile power supply unit, sources of electromagnetic waves installed in injection and production wells, connected by radio communication with a flow control unit and with generators-receivers of reflected electromagnetic waves mounted on the day surface automated data center, according to the invention, these sources of electromagnetic waves you filled in the form of electric dipoles, which are placed in each of at least two rows of injection and production wells concentrically located along the perimeter of the oil-water contact, the bushings of all these electric dipoles of injection wells are connected to one ring supply cable, electric dipoles placed in each production well, connected to another power cable, these ring cables are connected to the outputs of the power switch unit, the first and second inputs of which are connected respectively indirectly with the outputs of the power supply unit for dipoles of injection wells and the power supply unit for dipoles of production wells, the control input of the power key unit is connected to the output of the control unit for flow rate, the first and second inputs of each of these power supply units for dipoles of injection and production wells are connected with the first and second power and first and the second control outputs of the power energy distribution unit, while the first input of the power energy distribution unit is connected to the output of the mobile power supply unit, and the second outlet flow rate control unit.

Moreover, the power energy distribution unit includes a control unit and power transformers connected to a three-phase mobile power supply unit, the secondary windings of which are connected to the first inputs of the dipole power supply units of injection and production wells, made as two controlled beam thyristor half-bridges on power controlled thyristors, the specified control unit contains phase synchronizing transformers at the input, the secondary windings of which are connected with the corresponding inputs of the fixed-block Rowan control angle α the thyristors of said power supply units of injection and production wells are connected to first inputs of switch units of said angles α, wherein the second inputs of said switching signal generating unit of said angle α associated with the output flow rate control unit.

An electric dipole placed in the wells includes a cylindrical casing, consisting of two electrically conductive parts isolated from each other and from the external environment, each of these parts of the casing includes electrical inputs that are sealed in them, and one of these parts is provided with an eye in its terminal part .

In addition, the equipment according to the invention mainly includes located on the earth’s surface concentrically relative to the rows of production and injection wells equipped with devices for controlling the frequency of the oscillation and the amplitude of the mechanical impulse acting on the reference earth’s surface, different-pulse mechanical vibrators mounted at an angle to the earth’s surface, while the planes of these angles the inclination is directed radially towards the injection wells.

Additionally, the equipment according to the invention may include devices for generating multi-pulse hydraulic vibrations installed in each production well.

The invention is illustrated by drawings:

figure 1 presents a General view illustrating the arrangement of equipment for implementing the method according to the invention, a top view; figure 2 is a section along aa in figure 1; figure 3 - block diagram of the equipment according to the invention; figure 4 shows the structural diagram of the block 19 control the flow rate of oil; 5 is a block diagram of a power channel selector; 6 is a structural diagram of a power energy distribution unit and power supply units for dipoles of injection and producing wells; figure 7 presents a design variant of the borehole dipole; Fig. 8 illustrates the shape of the current supplying downhole dipoles.

The oil reservoir 1 of the field from which oil is produced by producing wells 2 by pumping water into injection wells 3 is limited to the oil-water contact 4 (Fig.1, 2). In the General case, the oil reservoir 1 is inclined to the horizontal plane at a certain angle. The oil-water contact 4 in the general case is also somewhat inclined to the horizon and is (a top view) a closed curve approximated conditionally by some smoother closed line, circle or ellipse. The initial deviations of the points of oil-water contact from these smooth closed curves can be minimized. Along the oil-water contact 4 in the injection wells 3, electric dipoles 5 are installed against the middle of the perforation interval of their casing strings, and in the production wells 2, electric dipoles 5 'are installed. These dipoles 5 and 5 ', identical in design, are connected to the ground cables 6 and 6' supplying them, stretched from well to well and forming the corresponding open rings. The above ground cables 6 and 6 'are connected to a supply voltage generated by a mobile power supply (WPT) source 7. Inside the area 8 of the field, generators-receivers of 9 reflected electromagnetic waves are evenly installed. The hydrocarbon field is provided by a central automated data processing center 10 having radio communication with individual units of equipment, including receiver-generators 9, power supply 7, downhole devices (flowmeters, executive bodies, not shown). Additionally, mechanical, different-pulse vibrators 11 are placed concentrically with respect to the area of the hydrocarbon deposit concentrically relative to the contours of injection 3 and production wells 2. These generators 11 can be structurally designed as described, for example, Ryashentsev NP, Ashchepkov Yu.S., Yushkin V. F. and others. Controlled seismic impact on oil deposits. Preprint IGD SB AS USSR, No. 31. Novosibirsk, 1989, p.12, 20-22, as well as Afinogenov Yu.A. A stand for determining the oil and gas recovery of rock samples, a vibration exciter for this stand and the results of its tests. // Dynamics of the continuous medium: Sat. scientific tr / USSR Academy of Sciences. Sib. rest Institute of hydrodynamics. 1997. Issue 112, pp. 19-21.

The specified power supply source 7, generator-receivers 9, vibrators 11 are equipped with vehicles 12.

The power supply source 7 includes a power supply unit 13, for example, a mobile power station, the output of which is connected to a power energy unit (TSB) 14, which is a thyristor converter with natural cooling and power control, for example TNP-1015, with a capacity of up to 500,000 kW (Fig. 3). From the output of the power energy unit 14, the three-phase supply voltage is supplied to the power energy distribution unit (BRES) 15, the outputs of which are connected to the power supply dipole supply unit 16 (BPDNS) and the production well dipole supply unit 17 (BPDDS). The outputs of the indicated block 16 and block 17 through the block 18 of the power channel switching (BSPK) are connected by ground supply cables forming open rings 6, 6 ', respectively, with dipoles 5, 5' installed in wells 2 and 3.

The flow rate Q of production wells 2 is controlled in the same way as it is organized in the above analogue, performed in a known manner by the flow rate control unit 19 of the flow rate Q, which allows controlling the current flow rate values and comparing it with the set values (Fig. 4). For example, this debit control unit 19 may include a unit 20 for storing the current total debit values, a unit 21 for measuring new values of the current debit, a unit 22 for comparing the indicated debit values with each other and with the established boundary values of the debit increase by the central automated data processing center 10 over the air. The output of the comparison unit 22 is the output of the unit 19 and is connected with the control inputs of the power distribution unit 15 and the power switching unit 18 of the channels.

The power channel switching unit 18 (Fig. 5) includes a group of power relays 23, the control windings (K1-K5) of which through the channel pair selection unit 24, made, for example, as a binary counter, are connected to the output of the flow rate control unit 19. Managed pairs of contacts 23 '(I-IV) of said power relays 23 by ground cables 6, 6' are connected to the corresponding dipoles 5 and 5 'installed in injection 3 and production 2 wells. For example, with four rows of wells, the following options are possible: state 1 - channels I-II are active, state 2 - channels II-III are active, state 3 - channels III-IV are active, state 4 - channels IV-V are active. Initially, Channel I is connected to the first row of injection wells 5, Channel II is connected to the first row of production wells 5, Channel III is connected to the second row of production wells, Channel IV is connected to the third row of production wells, Channel V is connected to the central production well of the field hydrocarbons (MUV).

The first input of the power channel switching unit 18, associated with the first contacts of each group of contacts of the relay 23, is connected to the output of the power supply unit 16 of the dipoles 5 injection wells, from which the positive half-wave of the supply voltage (+) comes. The second input of the block 18 is connected to the second contacts of each group of contacts of the relay 23 and is connected to the output of the power supply unit 17 of the dipoles 5 'of the producing wells, from which the voltage of negative polarity (-) is supplied.

The specified power energy distribution unit 15 (FIG. 6) includes power transformers 25 connected to the power energy unit 14 and the power transformers 25 included in each phase of the supply voltage, the secondary windings of which are made with a midpoint and connected to the first inputs of the power supply units 16 and 17 of the dipoles 5 and 5 ' . The indicated blocks 16 and 17 are made as two controlled thyristor half-bridges on power controlled thyristors 26 and 27. In this case, the inputs of the indicated thyristors from the transformers 25 are supplied with antiphase voltages, and their control inputs are connected to the control unit 28 for controlling the opening angles α of the opening of the indicated thyristors 26, 27. The specified control unit 28 contains synchronization transformers 29, the primary windings of which are associated with the corresponding phase of the three-phase supply voltage. The secondary windings of these synchronizing transformers 29 are connected to the corresponding blocks 30 of the formation of fixed angles α ₁ ÷ α _{6 of the} opening of the thyristors 26, 27, the outputs of which are connected to the inputs of the blocks 31 of the formation of the signals of the switching signals of the switching angles α of the opening of the thyristors 26, 27. The second inputs of the blocks 31 are connected with the control output of the flow control unit 19.

Blocks 30 of the formation signals of fixed angles α for opening the thyristors 26, 27 are known phase converters of the phase synchronizing phase voltage into a pulse train of rectangular shape, the duration of which corresponds to the specified intervals of the angles α _i turn on the thyristors 26, 27.

In blocks 31, which are known coincidence schemes and counters of binary codes, the signals from blocks 30 are compared with the codes for setting angles α coming from the flow rate control unit 19 of the flow rate control Q connected to the central automated data processing center 10.

Figure 7 presents the design (vertical section) placed in the injection and production wells of electric dipoles 5, 5 '. The electric dipole 5 (5 ') includes a housing containing the upper 32 and the lower 33 metal (electrically conductive) parts, which are interconnected by a stud 34 of dielectric material and insulated from each other by rings 35 of dielectric material, intended to supply voltage of opposite polarity . These bipolar portions 32 and 33 are placed in containers 36 and 36 'made of dielectric material and connected to each other by a tapered thread, the outer edge of which is reliably sealed with oil and oil-resistant sealant 37. The upper part 32 includes a hermetically sealed electrical input 38, intended for supplying to it positive electric charge (+), to the indicated lower part 33 using a similar hermetically sealed electric input 39, an electric charge of opposite polarity (-) is supplied. The indicated design of the dipole is intended for use in a liquid aggressive environment under hydrostatic pressure of the order of 30.0-35.0 MPa and above and at an elevated temperature of about 80 ÷ 90 ° C. The upper tank 36 is made with an eyelet 40, designed to connect a cable or rod connected with a mechanical or hydraulic working element oscillating along the wellbore, which is not shown here. It should be noted that the operation of dipoles 5 (5 ') will be more effective if the part of the casing, falling on the thickness of the developed formation, will be made of insulating material and equipped with perforations. In addition, to increase the radiation power, the electrically conductive parts 32, 33 of dipoles 5 (5 ') can be made in the form of several layers of a two-layer foil wound on a dielectric frame, one side of which is made of copper and the other is non-conductive.

When the supply voltage is supplied through the ring cables 6 and 6 'to the borehole dipoles 5 and 5', the resulting system begins to function as an annular cross-hole dipole. In the presence of two rows of sequentially injection and two rows of sequentially producing wells located around the central well (Fig. 3), the equipment according to the invention will include four annular cross-hole dipoles D1-D4, which are shown in Fig. 3 and designated as items 41-44 . These dipoles 41-44, working, as will be shown below, sequentially act on dipoles 45 of oil molecules (DMN), which are connected to the device 46 for measuring the total flow rate Q associated with the input of the block 19 control the growth rate.

The method of intensifying oil production according to the invention is as follows.

Oil reservoir 1 is developed according to the well-known, widely used technology by the method of water flooding, supplying water to injection wells 3, producing freely moving oil through production wells 2. At the same time, the contour of the oil-water contact 4 of free oil is shifted towards the production wells 2. Along the water-oil contact (WOC) 4, in the injection wells 3, electric dipoles 5 are installed (Fig. 7), each of which is connected to a supplying ground cable 6, extended from the well to the well, forming an open ring. In a similar way, dipoles 5 ′ of all production wells 2 are connected, forming another open ring 6 ′, as well as of all subsequent wells located on the area of the field. Cables 6, 6 'are connected to the outputs of the power key block 18, connected to power sources 16 and 17 of injection and production wells (Fig. 3).

Inside the field 8 of the field, for example, three generators-receivers 9 of reflected electromagnetic waves, arranged evenly in the middle part of the hydrocarbon field, or a greater number of them, are installed on the respective vehicles 12 for scanning the moving contour 4 of the WOC.

The receiver-generators 9 replace the seismic stations with geophones, operating on the reception of reflected elastic sound waves.

The control system for the operation of injection 3 and production wells 2 is based on monitoring by the automated information and computing center of 10 operating modes of all executive bodies serving the development of a hydrocarbon field, focusing on a total flow rate close to the maximum possible.

To do this, use the AD8R-21992 universal device for collecting and processing information from Analog Devices (Electronic Components Catalog 4.0, ELTEX) using the Mic RF001 Micrel OwlRadio Microwave Integrated Circuit, p. 46 (The same catalog).

The specified center 10 controls the total production rate of production wells 2 depending on the impact of the equipment used, ground-based and located in wells 2 and 3, monitoring the movement of the oil-gas supply circuit and maintaining the total hydrocarbon production at an optimum level close to the maximum. The contribution of each exposure factor to the specified center 10 is estimated by the total flow rate before and after its exposure. These factors include the total volume of water injected into the injection wells 3, the pressure drop Δp between the pressures in the injection and production wells, the frequency and amplitude of the oscillations of the ground mechanical multi-pulse generators, the angle γ of the inclination of the axes of the ground wave generators relative to the vertical, their developed power, frequency and amplitude different-pulse electromagnetic oscillations supplied to the oil reservoir by electric dipoles 5, 5 'placed in injection and production wells, current strength and power awn supplied to said electric dipoles 5, 5 ', by respective annular cables 6, 6' (1, 2).

The power from the source 7 of the mobile power supply (WPT) through the power unit 14 (TSB) is supplied to the power distribution unit 15 (BRES). From the block 15, containing thyristor circuits for regulating the power of the supply pulses supplied to the dipoles 5, 5 ', the supply voltage is supplied to the block 16 of the power dipoles of injection wells (BPDNS) and to the block 17 of the power dipoles of production wells (BPDDS). These power supplies 16 and 17 ensure the operation and alternate operation of the annular pairs of dipoles 5 and 5 'of the injection and production wells. The current (Fig. 8) at the output of the thyristors 26 and 27 of the power supplies 16, 17 is regulated by changing the phase angles α _i in accordance with the signals from the flow control unit 19.

Power electric pulses of positive polarity (+) are fed through an annular cable 6, which is connected to dipoles 5 of injection wells, and power electric pulses of negative polarity (-) are fed into an annular cable 6 ', which is connected to dipoles 5' of production wells. The result is a single electric dipole 41, acting on the underground volume of the oil-containing formation, located between the injection 3 working in the first pair and the production wells 2. At the same time, by supplying large amplitude pulses to the larger injection wells 3 in the I half-cycle and less - in a smaller circuit of production wells 2 in the II time half-period of electromagnetic exposure, provides a different pulse of respectively excited electromagnetic waves, and the amplitude and the impact of vibrations from the side of injection wells 3 is higher than the amplitude of the counter vibrations from the side of production wells 2. Such vibrations have a vibrotransporting effect in the field of their influence on the ions of the residual oil, as a result of which the residual oil shifts towards the producing wells.

The intensification process (oil flow) is monitored by a central automated data processing center 10, connected by radio communication to a flow control unit 19, by a signal from which a signal is generated in the control unit 28 of the power distribution unit 15 to switch control angles α _{i of the} thyristors 26 , 27 power supplies 16 and 17. In this case, a new value of the angle α is set, in the direction of its decrease, corresponding to a larger current strength and a larger value of the input power to the working dipole Yu. The response is an increase in the total flow rate Q until the old value Q _c is equal to the new value Q _n , after which the signal about switching the control angle α to block 15 again comes from block 19, increasing the supplied electric power to working dipoles. In this case, the flow rate of the wells is mainly controlled by switching the opening angle α of the thyristors 26, 27 within, for example, 10 ° ÷ 60 ° discretely by sorting out the best flow rate in the production wells. The moments of switching angles α are fixed in the absence of an increase in the total flow rate. The described processes occur during the operation of each pair of dipoles 5 and 5 'connected to the supply voltage and, accordingly, interwell annular dipoles 41-44 acting on the oil reservoir.

With a maximum set decrease in the total production rate of operating production wells 3 by the signals from the flow control unit 19 to the power channel switching unit 18, the corresponding switching (disconnecting the previous winding and connecting the subsequent winding) of the power relay 23 of the channel power switching unit 18 is carried out (Fig. 5). In this case, the supply voltage is disconnected from the first row of injection wells 3, the next (previously unused) row of wells is connected to the power source of the producing wells 17 and the polarity of the supply voltage supplied to the cable 6 is changed by connecting it to the source of power 16 of the injection wells. Thus, as the oil-water contact circuit 4 moves from the first row of injection wells 2 to the first row of production wells 3 while the cross-hole dipole 41 is operating, the latter become injection wells by connecting a power source 16 of the injection wells to them. In this case, the next row of wells becomes the producing row of wells, into which electric power will be supplied through channel III from the power source of 17 producing wells. Next, a similar process of switching working pairs of rows of wells will be repeated until the interwell dipole 44 is formed, which is formed by a series of injection wells fed through channel IV with positive polarity voltage (+) and dipole 5 'installed in the central production well and fed through channel V with negative voltage polarity (-).

To increase the efficiency of the method on the earth's surface inside the contour of the field at an angle to the horizontal plane of the field, ground-based mechanical multi-pulse vibrators 11 are installed, equipped with devices for controlling the frequency of the oscillations and the amplitude of the mechanical impulse of the force acting on the reference ground area. Moreover, these vibrators 11 are placed concentrically relative to the moving contour of the military-industrial complex and the contour of the producing wells and are turned on together with electromagnetic generators or separately, after switching on the latter. Using these vibrators 11 resonantly with electromagnetic action, an additional effect on the oil reservoir is generated by compression and rarefaction waves at an angle to the surface of the oil-containing reservoir. The plane of the angles of inclination of these vibrators 11 relative to the horizontal plane are directed radially towards the injection wells. The magnitude of these angles is chosen constructively, taking into account the maximum possible projection of the force onto the upper surface of the oil reservoir being treated by the resonant wave action. In the case of small flow rates, both sources of vibration affecting the oil reservoir are included. The transition from one mode to another is carried out as the maximum total flow rate is reached. For mechanical terrestrial multi-pulse vibrators, an important factor in their operating mode is the magnitude of the maximum projection of the force amplitude on the surface of the formation, which is possible by controlling the angle of inclination of the axis of the vibrator bodies 11 relative to the vertical. Angle control for each mechanical vibrator can directly provide enhanced oil recovery.

In addition to ground vibrators 11, each borehole can be additionally equipped with multi-pulse hydraulic vibrators that create an additional inflow into the wells. Their design is known and is not given in this application (see, for example, Yu.A. Afinogenov, AF Belenkov. Device for creating hydraulic pulses in a well. Continuous fluid dynamics. Novosibirsk, 2001. Issue 117. Acoustics of inhomogeneous media, pp. 94-97. USSR author's certificate No. 1175205. "Device for creating hydraulic pulses in the well." Yu.A. Afinogenov, A.F. Belenkov).

The proposed method of intensifying oil production and equipment for its implementation to the maximum eliminate unproductive energy consumption when exposed to the formation of electromagnetic radiation of different pulses, which creates real economic conditions for its implementation in oil production practice. The distance between the rows of injection and production wells during field development is selected in the range from 300 to 600 m, i.e. the rock layer covered by electromagnetic exposure does not exceed 600 m, which is significantly less than the thickness of the rock layer 3 ÷ 3.5 km above the oil reservoir when it is processed by electromagnetic radiation from the Earth's surface according to the above analogue. The proposed method eliminates oncoming hydraulic waves induced in injection and production wells according to the prototype, when their probability of encounter is close to zero in anisotropic environments. Instead of hydraulic counterpropagating waves, we propose electromagnetic half-waves of different polarity, the meeting of which is unavoidable in any porous oil-saturated medium with a probability equal to unity, resulting in a shift of the residual oil ions towards the producing wells.

Claims (8)

1. A method of intensifying oil production, in which an electromagnetic resonant effect is applied to the reservoir using sources of electromagnetic waves immersed in the wells, while electromagnetic waves are generated in the reservoir, which are superimposed on the natural frequency of the hydrocarbon fluid, these electromagnetic waves are directed away from the producer wells and counter to at least one of the nearest neighboring wells in the direction of the producing well, control the pointer by electromagnetic oscillations using the equipment located on the surface, they control the progress of the oil-water contact and maintain its similarity to the initial position, characterized in that the said electromagnetic oscillations are excited with the help of electric dipoles, which are placed in each of the injection and production wells, the inputs of all these electric dipoles of injection wells are connected to one ring supply cable, electric dipoles located in each production to her well, they are connected to another ring supply cable, and a voltage of a larger amplitude is applied to the input of dipoles installed in the injection wells in the first half-time period than indicated in the second half-time to the input of dipoles installed in the production wells and of opposite polarity feed in pairs, with each of n _i pairs consisting of these ring cables located along the perimeter of production and injection wells, with the applied voltage applied to them, fu functions as n _i covering the corresponding interwell annular space of the interwell annular electric dipoles creating electromagnetic pulses that act on the oil ions in the direction of their movement to the producing wells, as oil is produced from the reservoir volume covered by the working interwell annular electric dipole, the supply voltage is switched to the next pair of ring electrical loads, while the electric dipoles of each subsequent row of production wells they are fed as electric dipoles of injection wells, and electric dipoles of each subsequent row of production wells — as electric dipoles of the current row of production wells, the power supply of these interwell annular electric dipoles is coordinated with the resulting total production rate of production wells, with a decrease in which the energy consumption of a working ring electric dipole is increased, keeping flow rates as high as possible. 2. The method according to claim 1, characterized in that, in addition, resonantly with electromagnetic effects, they act on the oil reservoir by compression and rarefaction waves at an angle to the surface of the oil-containing reservoir, for which they are provided with frequency control devices concentrically relative to the rows of production and injection wells oscillations and amplitudes of the mechanical impulse of the force acting on the supporting ground area, mechanical different-pulse vibrators, the planes of which are directed p dially toward the injection well, the magnitude of said angles is selected constructively with the greatest possible force projection on the upper surface of the processed wave resonance action of the oil reservoir, wherein said mechanical vibrators include raznoimpulsnye after the electromagnetic generators or simultaneously with them. 3. The method according to claim 1, characterized in that in each production well, a device is installed to create multi-pulse hydraulic vibrations, with which a vacuum is created in the near-well zone of the oil reservoir. 4. Equipment for the intensification of oil production, including a mobile power supply unit, sources of electromagnetic waves installed in injection and production wells, connected by radio communication with a flow control unit and with generators - receivers of reflected electromagnetic waves mounted on the day surface - a central automated data processing center, characterized the fact that these sources of electromagnetic waves are made in the form of electric dipoles, which are placed in each of at least two rows of injection and production wells concentrically located along the water-oil contact perimeter, the inputs of all the indicated electric dipoles of injection wells are connected to one annular supply cable, the electric dipoles located in each production well are connected to another supply cable, indicated ring cables are connected to the outputs of the power switch unit, the first and second inputs of which are connected respectively to the outputs of the power supply unit of the dipoles of injection with the importants and power supply unit for dipoles of production wells, the control input of the power key unit is connected to the output of the flow control unit, the first and second inputs of each of these power supply units of dipoles of injection and production wells are connected to the first and second power and first and second control outputs of the power distribution unit, respectively energy, while the first input of the power distribution unit is connected to the output of the mobile power supply unit, and the second to the output of the flow control unit. 5. The equipment according to claim 4, characterized in that the power energy distribution unit includes a control unit and power transformers connected to the three-phase mobile power supply unit, the secondary windings of which are connected to the first inputs of the dipole supply units of injection and production wells, made as two controlled beam thyristor half-bridge on power controlled thyristors, the specified control unit contains phase synchronizing transformers at the input, the secondary windings of which are connected with the corresponding the inputs of the fixed-angle forming units α for controlling the power thyristors of the indicated power units for injection and producing wells connected to the first inputs of the switching units of the indicated angles α, while the second inputs of the indicated units for generating the switching signals of the indicated angles α are connected to the output of the flow control unit. 6. The equipment according to claim 4, characterized in that the electric dipole placed in the wells includes a cylindrical body, consisting of two electrically conductive parts isolated from each other and from the external environment, each of these parts of the body includes hermetically sealed electrical inputs, however, one of these parts in its terminal part is provided with an eye. 7. The equipment according to claim 4, characterized in that it includes concentric relative to the rows of production and injection wells equipped with devices for controlling the frequency of oscillation and the amplitude of the mechanical pulse acting on the reference ground area, mechanical multi-pulse vibrators installed at an angle to the ground surface, while the plane of the indicated inclination angles are directed radially towards the injection wells. 8. The equipment according to claim 4, characterized in that it includes devices for generating hydraulic pulsations of different pulses that are additionally installed in each production well.

Images