RU2520672C2 - Production simulation method in oil wells and device for its implementation - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention is related to the field of oil and gas industry, mainly to production of viscous and superviscous oil, and it may be used for production stimulation of oil with viscous components and deposits. High-frequency impulse current is generated by a group HF surge-current generators in a group of twin-transmission power lines in a group of wells and consisting of two isolated conductors or one isolated conductor and used as the second metal conductor of pipelines in the group of wells. The impact is made by an electromagnetic high-frequency pulsed field generated by high-frequency impulse current of conductors in the groups of twin-transmission power lines to the metal surface of pipelines in the group of wells. Thermal and acoustic impact is made on intratubal liquid in the well group and through it on the oil deposit by heating and mechanical vibration of the pipeline metal which occurs at passage of high-frequency impulse current through the twin-transmission power line. Additional thermal and acoustic impact is made on intratubal liquid in the well group and through it on the oil deposit by heating and pressure fluctuations which occur at the end of the twin-transmission power line in result of high-frequency impulse charge through intratubal liquid. At that the HF surge-current generators are set so that they generate high-frequency current pulses with identical pulse length and repetition.

EFFECT: increase of oil production stimulation.

22 cl, 3 dwg

Description

The technical field to which the invention relates.

The invention relates to the field of oil and gas industry, mainly to the production of viscous and viscous oil, and can also be used to intensify oil production, complicated by viscous components and deposits, to increase productivity and reduce watering of low-production wells in order to prevent their decommissioning.

The level of technology.

A large number of production stimulation methods are known for the aforementioned field of application, in which various physical impact methods are used to increase oil inflow in production wells, however, those are considered here in which impacts can potentially affect not only the bottom-hole formation zone, but also the formation itself or even the entire productive reservoir.

Most of them use thermal and wave energy from a variety of sources.

Known wave treatment of wells, covering the whole formation, in which the emitter of wave energy is installed in one of the wells, and with its help the wave vibromechanical energy is pumped into the formation. The disadvantage of this method is that, on the principle of obtaining wave energy, it is critical to selecting a candidate well (it is required that there is no obstacle to the propagation of waves around), as well as the absence or weak thermal effect (Kuznetsov R.Yu. Construction and operation of oil and gas wells by open bottom using wave technologies: problems, theoretical solutions, field experience. Ufa: abstract of the dissertation of the doctor of technical sciences. Ufa, 2010. 53 p.).

To intensify the production of highly viscous and bituminous oil, it is necessary to combine both thermal and wave mechanical effects, such as, for example, in a method that uses both vibromechanical and thermal effects using steam cycling with areal steam injection in combination with acoustic wave exposure, for example, with the frequency of ultrasound (Deposits of high-viscosity oils and bitumen from the Timan-Pechersk province and the prospects for their development using modern integrated technologies. Materials of the 8th Inter regional geological conference. November 17-18, 2010. Edited by A.M. Shammazov and others Scientific editor and composer A.V. Petukhov. Ufa. 2010. P.192). Lack of technology: it is not possible to obtain acceptable technical and economic indicators due to breakthroughs of the coolant through highly permeable channels, karst cavities and caverns, and in the fields that were in operation, and breakthroughs into old wells and mine workings

In order to further save energy, other methods use electric energy to obtain thermal and wave effects.

A known method of intensification of production, in which the thermal effect is carried out using heating cables using a contact mechanism for transferring thermal energy from a thermal element to a heated medium, and this method can be used in combination with other types of influences.

Devices for implementing the method differ from each other in the design of the fuel element. In Raychem cables, the heating element is a polymer-coal powder between the cable cores, which has the property of self-regulation of the heating temperature when current is passed through it (Raychem heating cable (http://mtraychem.ru/nagrevatelnyj-kabel-raychem, accessed 07/19/2012). In other designs, for example, in RF patent 2167008, IPC В08В, author and patent holder Samgin Yu.S. METHOD FOR PURIFICATION OF OIL AND GAS PIPELINES FROM PARAFFIN DEPOSITS AND CORK EDUCATION AND DEVICE FOR ITS IMPLEMENTATION. 200. 05. e properties of the cable core itself. The materials also offer a cable-ferromagnetic tube resistive induction system using the skin effect of the reverse current in the ferromagnetic tube. The current concentration on the inner surface of the tube is, in turn, due to field induction created by alternating single-phase current of the cable located inside the tube ("skin system"). Although these systems are proposed as innovative in materials, they are known in the art.

A common disadvantage of the described methods when using cable heating systems is that they affect only the well’s lift, and their limited effect on the viscosity of the medium not only in the bottomhole zone, but also at a sufficient depth of the well (more than 1 km).

When using "skin systems", the disadvantage is the need to connect a powerful single-phase load to a three-phase network through a no less powerful balancing installation (substation), which distributes the current evenly across all phases. Other disadvantages are: low power factor, the dependence of the operating mode on the diameter of the tube, its material and non-linear temperature dependence.

Known high-frequency electromagnetic treatment of wells, covering the whole formation, for which it is opened by at least one injection and one production well, in which the emitter of wave electromagnetic energy, which is used to pump wave energy into the formation, is installed in one of the wells. The disadvantage of this method is that, in contrast to the previous method, it increases the mobility of the formation fluid due to predominantly heating and practically does not have a vibromechanical (acoustic) effect, which is perhaps the most important for increasing the permeability of the formation (RF patent No. 2139415. Mining of useful minerals Authors Sayakhov FL et al. Patent holder Bashkir State University, Scientific Engineering Center of the oil company Lukoil. Publish. 10.10.1989). Another disadvantage is the complexity of technical devices of this frequency range, in which the absorbing properties of the borehole medium are manifested, and large losses of energy both in the transmission path of this energy and in the emitter itself.

There is a method of influencing the bottomhole formation zone in the process of oil production, including low-frequency and high-frequency vibroacoustic, as well as thermal exposure, characterized in that they carry out two-frequency vibroacoustic and thermal effects in the oil production process, for which the vibroacoustic source and thermal emitter are placed under the electric drive of the submersible pump in the perforation interval, and the impact control is carried out via the power cable of the electric drive of the submersible pump and the cable suspension, a vibroacoustic source and a thermal emitter with an electric drive of a submersible pump, the effect being carried out during the operation of the submersible pump (patent application of the Russian Federation 2003116271, IPC 7 E21B 43/25. Publ. 20.12.2004).

Close is the method of combined high-frequency (HF) and low-frequency (LF) exposure in the range of resonant frequencies of the near zone and dominant frequencies of the far zone according to the maximum acoustic response in the HF and LF ranges, in which a borehole acoustic transducer is excited by pulsed electrical signals of a number of frequencies in the technological range . The energy of pulsed electrical signals is converted into the energy of radiation pulses of acoustic vibrations of the technological range of frequencies acting on the near productive zone of the well, and into the energy of acoustic oscillations of the Raman differential frequencies acting on the far productive zone of the well. The device contains a serially connected master oscillator, a multichannel generator device and a matching device, also containing a geophysical cable connected to the downhole acoustic transducer, also containing a power supply device connected to the input by the power supply busbars (RF patent 2309247, IPC E21B 43/16, E21B 43 / 25. METHOD OF ACOUSTIC INFLUENCE ON A PRODUCTIVE WELL AREA ON PERFORATION INTERVALS AND A DEVICE FOR ITS IMPLEMENTATION Authors Aleksandrov VA and others. new State Unitary Enterprise "Central Scientific Research Institute" Morphizpribor ". Published on 10.27.2007).

The disadvantage of both methods is the need to select a whole spectrum of frequencies individually for all zones of the formation if it is necessary to overlap its entire volume (as in the case of viscous oil production), which is technically impossible, as well as low efficiency of wave action.

Known methods for stimulating production, which also use an electric method for delivering energy to the bottom of the well and converting it into the form necessary for this, for example, in the form of a high-voltage pulse discharge that excites cyclic compression waves, a pulsating vapor-gas cavity (US Patent US4345650, IPC Е21В 36/04, Е21В 43/00, Е21В 43/24. PROCESS AND APPARATUS FOR ELECTROHYDRAULIC RECOVERY OF CRUDE OIL. Author Wesley Richard H., patent holder Wesley Richard H. Published on 08.24.1982). The disadvantage of this method is the weak thermal effect and low frequency of exposure, preventing the penetration of energy into the reservoir due to rapid attenuation.

A known method of intensification of production, in which they act by elastic sound waves of the oscillation source and separately by electric heating by passing current through a previously isolated part of the column from the electric cable (RF patent No. 2097544, IPC E21B 43/25, E21B 28/00, E21B 36/04. METHOD FOR INCREASING OIL PRODUCTION FROM OIL COLLECTOR AND DEVICE FOR ITS IMPLEMENTATION Authors Olav Ellingsen et al. Patent holders Petroleo Brasileiro SA-Petrobras (BR), Ellingsen and Associates AS (NO). Publ.

There is a method known to be similar to the previous one to intensify production by means of a gas-dynamic wave action on the formation, in which a hollow rod with magnetostrictive properties is used and due to the transmission of high-frequency current from the cable inside the hollow rod, it creates ultrasonic and thermal effects and simultaneously affects the blast wave from the charges placed at the end of the rod. (RF patent No. 2298090. METHOD AND DEVICE FOR GAS-DYNAMIC INFLUENCE ON THE PLAST. IPC (2006.01) E21B 43/263. Authors Paderin MG et al. Patent holders Paderin MG et al. Publ. 04/27/2007). A common disadvantage of these methods is low efficiency due to the weakness of ultrasonic exposure and limited application (only for the bottomhole formation zone in some types of wells).

There is also known a method in which the formation is subjected to a complex of ultrasonic vibrations from a separate source and low-frequency from an electric discharge (RF patent 2392422. METHOD FOR OIL PRODUCTION USING ELASTIC VIBRATION ENERGY AND INSTALLATION FOR ITS IMPLEMENTATION. IPC (2006.01) E21B16/16/16 A.V. et al. Patentee Limited Liability Company SoNovita. Published on April 28, 2009). However, the disadvantage of this method is the local impact in the bottom-hole formation zone and the impossibility of influencing the oil to be lifted in the well’s elevator, which limits their use in the developed fields with the formation of a large number of asphalt-resinous, paraffin and emulsion deposits in the production process, as well as in fields with high viscosity and bituminous oil.

In all the above methods, the wave action is carried out by sources of varying degrees of intensity, but according to the principle of action, they are all local, i.e. implemented in the form of any emitters of a certain design, immersed in the well. A common drawback: large losses and dispersion of wave energy in the initial portion of the radiation, large frequency spread and non-synchronism of wave effects with multipoint exposure, which does not allow to obtain a sufficiently effective effect on the entire formation.

A known method of wave action on the reservoir or the entire reservoir, in which to some extent eliminates the above disadvantages, namely, that on the surface or in vertical, and / or inclined, and / or horizontal, and / or branched wells are placed sources of wave oscillations . Using longitudinal wave sources, they create both longitudinal and transverse waves. Using these waves, they carry out a wave action on a medium with a hydrocarbon reservoir. According to the invention, a wave action is effected on the medium with a hydrocarbon deposit by interference wave fields with fronts of a given configuration formed by excitation of longitudinal and transverse waves at the points of the hydrocarbon deposit with time delays proportional to the distance from the point of wave excitation to each given point of the reservoir. In this case, the wave action is focused on the area of the deposit with fixed and inactive hydrocarbon reserves and a synchronized multipoint wave action is implemented that provides the static effect of summing the energy of the wave pulses (RF Patent 2361070, IPC (2006.01) E21B 43/16. Ivanov SI Patent holder Limited Liability Company "Volga-Ural Scientific Research and Design Institute of Oil and Gas". Publish. July 10, 2009). The disadvantage of this method is that the wave action is carried out by the shock (pulsed) method, in which only the leading edge of the generated pulses is significant, since the wave oscillations in the pulse itself have an arbitrary frequency, and when these oscillations are superimposed in the formation, as in the previously considered ways, does not give an energy effect. In this case, the common-mode superposition of the oscillation fronts, which, in fact, give the amplification effect due to interference, occur in an extremely limited volume of the formation. Another disadvantage of this method is the lack of technical means to provide a focused effect in the desired zone of the formation.

The closest in technical essence is a method of intensifying oil production in oil and gas wells by eliminating deposits and increasing the viscosity of viscous hydrocarbons in the well and the bottomhole formation zone, carried out using a high-frequency generator and electric power transmission line in the form of a cable immersed in the well to the depth of formation of deposits, in which generate a high-frequency electric current in the transmission line, act on the surface of the pipe by the high-frequency electromagnetic field created by this current wires and through this carry out thermal due to induction high-frequency heating and acoustic due to electrodynamic forces acting on the pipe string, at the same time carry out a direct thermo-acoustic effect on the well fluid by closing a high-frequency current through it at the end of the cable, while determining the frequency range at which the maximum thermal and acoustic power both in the pipe string and in the well fluid itself from high-frequency line currents and in well fluid (Patent RU No. 2248442, IPC E21B 37/00, E21B 36/04. METHOD AND DEVICE FOR LIQUIDATION AND PREVENTION OF FORMATION OF DEPOSITS AND TUBES IN OIL AND GAS-PRODUCING WELLS. The author V. Melnikov Patentee V. Melnikov, Publ. March 20, 2005).

To enhance the thermal and acoustic effects in the described method, high-frequency energy is used in a pulsed mode, which contributes to the creation of shock mechanical vibrations in the pipe string along the depth of the well and the creation of shock waves in the well itself due to the fact that in the pulsed mode the high-frequency current in the fluid acquires discharge characteristics (Badamshin R.A., Melnikov V.I. Experimental downhole equipment for treating the bottom-hole formation zone and eliminating deposits throughout their depth Ia. The successes of modern science. 2004-№5. S.35-38).

A distinctive feature of this method is that it converts a pipe string and a certain volume of well fluid in the near-well zone of the well into distributed heaters and acoustic microwave emitters.

A device for implementing the method comprises pulsed high-frequency current generators consisting of capacitive energy storage devices, which are used in the prototype as spiral strip lines, a discharge circuit based on a semiconductor key, in the circuit of which an electric energy transmission line is included. The device also contains a charge module for capacitive storage in the form of a DC filter connected through a rectifier to a three-phase alternating current network (Badamshin R.A., Melnikov V.I. Experimental downhole equipment for processing the bottom-hole formation zone and eliminating deposits throughout the depth of their formation. Achievements of modern natural sciences. 2004-№5. S.35-38).

The disadvantage of this method is the lack of optimal technological parameters that ensure the maximum share of the flow into the formation from all the generated thermal and acoustic energy, and the coverage, as a result, of the entire formation by complex (thermal and acoustic) effects. To a greater extent, this method is effective for eliminating viscous deposits and reducing the viscosity of heavy oil in the elevator and bottomhole zone of wells. Moreover, the method, as described in the patent of the Russian Federation 2361070 (IPC (2006.01) E21B 43/16. METHOD OF WAVE IMPACTS ON A HYDROCARBON DEPOSIT. Authors SI Ivanov Patent holder Limited Liability Company "Volga-Ural Scientific Research and Design Institute of Petroleum and gas ". Publish. July 10, 2009), can be used for simultaneous processing of a group of wells, but the above drawback remains. The disadvantage of devices for implementing the method in batch processing is the difficulty of ensuring their power supply and, in some cases, additional losses in the cables leading to the devices.

Disclosure of the invention.

In one aspect of the claimed invention, a method for intensifying oil production is disclosed, in which a high-frequency pulse current is generated in a group of two-wire electric power transmission lines located in a group of wells and consisting of two insulated conductors or one insulated conductor and used as a second metal conductor of the pipelines of a group of wells through a group of generators of high-frequency pulsed current and act with a high-frequency pulsed electromagnetic field, creating by applied high-frequency pulse current of conductors of a group of two-wire transmission lines to the metal surface of a group of pipelines of a well group; carry out thermal and acoustic effects on the in-pipe fluid in the group of wells and through it onto the oil reservoir by heating and mechanical vibrations of the metal of the pipelines that occur when a high-frequency pulse current passes through a two-wire electric energy transmission line; carry out additional thermal and acoustic effects on the in-pipe fluid in the group of wells and through it on the oil reservoir by heating and pressure fluctuations arising at the end of the two-wire transmission line as a result of high-frequency pulse discharge through the in-pipe fluid; moreover, the high-frequency pulse current generators are tuned to create high-frequency pulse current pulses with the same duration and repetition rate.

In another aspect of the claimed invention, a device for intensifying oil production is disclosed, comprising a group of high-frequency pulse current generators, containing capacitive energy storage devices and a discharge circuit based on semiconductor switches, as well as electric energy transmission lines connected to the discharge circuit of the said generators, located in each well from the group wells configured to conduct high-frequency pulsed currents along pipelines and thereby create vibromechanical f fluctuation and perform the heating pipes in the entire length of the arrangement of said transmission lines; moreover, the high-frequency pulse current generators are located near the transmission line and are configured to create high-frequency pulse current pulses with the same duration and repetition rate.

The problems solved by the claimed invention are the intensification of the production of viscous or complicated oil in oil and gas wells by increasing the integrated flow of thermal and acoustic energy from the wells into the reservoir volume, increasing the degree of coverage by the wave (vibromechanical) effect of the entire volume of the oil reservoir, as well as increasing the energy efficiency of work devices for intensifying production and simplifying their power supply system, increasing mobility and versatility.

The essence of the invention lies in the fact that the known method in which to influence the reservoir of an oil deposit creates a high-frequency pulse current in a group of two-wire electric energy transmission lines located in a group of wells and consisting of two insulated conductors or one insulated conductor and used as the second metal conductor pipelines of a group of wells, through a group of generators of high-frequency pulsed current act high-frequency pulsed electromagnet the final field created by the high-frequency pulsed current of the conductors of the group of two-wire transmission lines to the surface of the metal of the pipelines of the group of wells and carry out thermal and acoustic effects on the in-pipe fluid in the group of wells and through it on the reservoir of the oil reservoir by heating and mechanical vibrations of the metal of the pipelines arising from the passage high-frequency pulse current through a two-wire transmission line of electric energy, and also carry out additional thermal and acus The effect on the in-pipe liquid in the group of wells and through it on the oil reservoir by heating and pressure fluctuations arising at the end of the two-wire transmission line as a result of a high-frequency pulse discharge through the in-pipe liquid is a new operation: high-frequency pulse current generators are set up to create pulses of high-frequency pulse current with the same duration and repetition rate.

This new operation allows us to obtain a technical result consisting in the creation of multipoint emitters using well groups of shock waves in the reservoir, the in-phase application of which in the reservoir, due to the same frequency of their repetition and duration, sharply increases the intensity of their impact in its volume, which allows to increase the production intensity oil.

In the method, in which the pulse repetition rate of the high-frequency pulse current is further increased until forced oscillations of the metal of the pipelines of the group of wells occur with a frequency equal to the pulse repetition rate of the high-frequency pulse current, and obtaining a group of wells in the fluid volume, as a result, coherent sound waves, allows receiving the latter and their interference will further increase the intensity of sound waves both inside the wells and in the formation itself.

An increase in the efficiency of the new result is also achieved in a method in which an increase in the intensity of coherent sound waves in the volume of a liquid of a group of wells is achieved by heating this volume with a high-frequency pulse current to a temperature above the melting temperature of the viscous components of the in-pipe liquid in the surface zone of the pipeline metal

A method in which, in addition to the previous one, heating the volume of the in-pipe fluid is carried out to a temperature of lowering the viscosity to values that maximally reduce the absorption of sound waves in this fluid in the group of wells, it is possible to obtain another new result, which consists in the appearance of new properties: the ability of wells in their volume to concentrate wave energy from all its distributed sources located both inside the well and outside it, as well as the ability to direct this concentrated (accumulated w) wave energy into the formation.

Moreover, the method in which the ratio of the heating power of the metal and the power of mechanical vibrations in the pipelines is controlled by changing the ratio of the current frequency of the high-frequency pulse current and the pulse duration of the high-frequency pulse current allows you to optimize these properties.

These properties are also used by a method in which flow, injection, pressure and prefabricated pipelines are hydrodynamically connected to a given group of wells using a group of high-frequency pulsed current generators and a group of two-wire electric energy transmission lines located on a ground surface near these pipelines that are thermally and acoustically exposed. , or on their outer surface, or inside them. The new result is the exchange of wave energy both between wells and onshore pipelines and between the wells of the entire group of wells through onshore pipelines and, as a result, an increase in the flow of wave energy into the reservoir.

A method in which pulses of high-frequency pulse current are synchronized in flow, injection, pressure and prefabricated pipelines by pulse duration and frequency of their repetition with similar pulses in a group of two-wire transmission lines located in the pipelines of each well of a group of wells that are hydrodynamically connected with them, allows to obtain another new property due to the properties of coherence of sound waves in all involved surface and underground pipelines, namely the property of a sound laser in the form of gun-scale sound radiating into the formation through the wells group.

A method in which the waveguide and directing properties of pipelines filled with liquid or gas are used to accumulate and enhance the intensity of wave energy in a group of wells created by high-frequency pulse current in all electric energy transmission lines distributed over land and borehole pipelines, and by the optimal selection of a group of wells Based on geological and geophysical surveys, they cover the entire oil reservoir by impact, and, due to the optimal control of the wave flow, energy into the oil reservoir, to maximize the use of this new property.

The development of the last variant of the method also has a super effect, in which part of the wells from the group of wells are used to pump coolant into the formation due to the nonlinear interaction of thermal and acoustic energy in the formation.

The most economical method is that in which the heated well fluid from other wells of the group is used as a heat carrier.

The above task is also achieved by a device for intensifying oil production, containing a group of high-frequency pulse current generators containing capacitive energy storage devices and a discharge circuit based on semiconductor switches, as well as electric power transmission lines connected to the discharge circuit of the said generators, located in each well from the group wells configured to conduct high-frequency pulsed currents along pipelines and thereby create vibromechanical vibrations and to carry out heating in pipelines along the entire length of the placement of the mentioned transmission lines; moreover, the high-frequency pulse current generators are located near the transmission line and are configured to create high-frequency pulse current pulses with the same duration and repetition rate.

A device in which high-frequency current generators are additionally combined by a common charge circuit of capacitive storage devices connected through a DC filter to a network rectifier has a new property that provides the same pulse duration.

The implementation of the transmission line device in the form of two insulated metal conductors installed on the surface of pipelines with a longitudinal displacement relative to each other, provides on the short ground pipelines the same parameters of the pulses by the frequency of the current in the pulse, as well as in deep pipelines.

A device in which the metal conductors of the energy transmission line are installed inside the pipelines and additionally at the end opposite from the end of the connection of the generators, contain electrodes made with the possibility of high-frequency pulse discharge through the liquid of the pipelines.

A device in which, in addition, each metal conductor of the energy transmission line is a distributed heating source, the result is an increase in the specific thermal power per unit length of the energy transmission line.

A device in which each metal conductor of the energy transmission line is a distributed source of mechanical vibrations, due to, for example, free fastening, flexible and at the same time elastic construction, results in an increase in acoustic power per unit length of the transmission line.

To implement the method of intensifying oil production, in the most preferred embodiment, a device is designed in which energy transmission lines are located in each well from a group of wells and on flow, injection, prefabricated and pressure pipelines, hydrodynamically connected with this group of wells.

At the same time, a device in which the insulated metal conductors of the energy transmission line are additionally configured to conduct such high-frequency pulsed currents in order to heat the oil to temperatures of viscosity reduction to values that reduce the absorption of mechanical vibrations.

A device in which the insulated metal conductors of the energy transmission line are additionally configured to heat oil to a temperature of decreasing viscosity to values that reduce the absorption of mechanical vibrations, as a result, it provides an implementation of the method with the complete transfer of wave energy from all its ground and underground sources to the formation.

A brief description of the drawings.

Figure 1 shows a General view of a device for intensifying the production of viscous and viscous oil.

Figure 2 shows a detailed view of the placement of cables.

Figure 3 shows the charge-discharge circuit of the generators.

The implementation of the invention.

Until recently, thermal methods for enhancing oil recovery had no alternative when developing oil fields containing highly viscous oil. The most studied and widespread among the thermal methods is the paracyclic effect on the formation. However, the irreparable disadvantage of this technology is the rapid flooding of the reservoir, because 2.5-5 tons of steam are converted into water to extract tons of bitumen. Strong watering makes mining unprofitable. After extracting about 20% of the bitumen reserves, the amount of water in the formation becomes close to the amount of oil. Therefore, at present, methods of heating using electric heaters are more promising.

But in addition to thermal methods for increasing oil recovery, there are also methods of wave action on the reservoir. Wave methods can be divided into pulsed single-action, low-frequency and acoustic effects, including ultrasonic. The most widely used methods of exposure to the bottomhole zone are powder gases, electro-hydraulic shocks, instant depressions, as well as vibration and acoustic effects.

In the claimed invention, in the most general method, a wave action is applied to the formation, and in the preferred embodiment, both wave and thermal effects are performed.

In one embodiment, the method is implemented as follows. First, a group of wells having a hydrodynamic and, as a consequence, acoustic connection with the oil reservoir is determined. An energy transmission line in the form of a single-wire (single-core) geophysical cable, equipped at the end with a bare electrode with protective insulating rings, eliminating direct contact with the pipeline metal, is immersed in each well of a group of wells equipped with the installation of a sucker rod pump USHGN or screw USHVN. As the second conductor, the metal of the pipelines itself was used directly. In the surface part (mouth) of the well, the transmission line is made in the form of two insulated conductors laid on the surface of the surface part of the pipeline, one of which is connected to the core (conductor) of the geophysical cable, and the other to the metal of the pipeline of the well. The two-wire transmission line at the other ends is connected to the discharge circuit of one of the generators. The conductor core of the geophysical cable at its deepest end is connected to an electrode having guard insulating rings, which ensures the closure of the high-frequency current by pulsed high-frequency discharge through the borehole fluid to the metal of the well pipelines. To control the operating mode of pulsed high-frequency current generators, the storage capacities of the generators are combined by a common charging circuit, which allows one to obtain the same charge rate and voltage on the drives, and by selecting the values of their capacities, the frequency of the wave discharge process in the pulse can be adjusted taking into account different lengths of cables connected to the generators.

For open-hole wells, a special pipe string is used (better than a flexible design, for use in horizontal wells, most often used for the production of viscous oil) with a pre-mounted transmission line and fixed to the outer or inner surface of the pipe. For greater efficiency in this case, it is better to use a transmission line of two insulated conductors fixed to the surface with a longitudinal displacement relative to each other. In this case, the efficiency is increased by increasing the magnetic flux acting on the surface of the pipe string. At the same time, the use of a single-wire cable for the above wells (USHVN, USHGN) is justified by the fact that it can be installed (suspended) in the well without setting up a repair team, i.e. without picking up pipes.

Further, the method is implemented as follows: when generating pulses in a cable line of energy transfer, their transmission from the generator to the end of the line is relative to the time of the mechanical vibrations they create almost instantly (with the speed of an electromagnetic wave), and, therefore, all distributed mechanical effects on the metal surface throughout cable length can be considered synchronous. At the low frequency of pulses in the metal of the wells, damped oscillations occur, coinciding in time along the leading edge and not necessarily in frequency, since the natural resonance frequency in sections of the column may differ.

However, with an increase in the pulse repetition rate, the generator-cable-well system will inevitably come into the region of a change in the quality of this system with a characteristic feature in the form of a sharp and multiple increase in the intensity of the generated sound wave. This occurs in the frequency domain, when the regime changes from almost free mechanical vibrations to the regime of forced vibrations with a frequency that coincides with the pulse repetition rate. This frequency range is not known in advance; therefore, it is determined experimentally in the proposed method, i.e. a sound vibration sensor is placed at the mouth of each well, and by gradually increasing the frequency, this range is determined by a sharp increase in intensity in all wells. It should be noted that you need to determine this range only once during the initial setup. The effect of sharp amplification of the sound wave is explained by the fact that the forced mechanical vibrations of the pipe string sections in the well in this range create coherent sound waves, and the effect itself is directly determined by their properties. Among these properties, we note the following:

1) upon application and interference of two coherent waves, a resulting wave of the same frequency is formed, but its intensity is two times higher than the sum of the intensities of these waves;

2) the interference of many waves (more than two) during addition leads to a clearer interference pattern due to an increase in the amplitude, and the intensity of the resulting wave exceeds the sum of the intensities of the component waves by n times, where n is the number of sources.

Thus, the resulting sound wave as a result of reflections and overlays from sources distributed over the entire surface of the well pipelines will have a local intensity (proportional to the square of the amplitude of the overpressure), many times higher than the total intensity of the sound waves from all sources. At the same time, the fronts of such waves with an increase in the volume of sources will be steeper, and the waves themselves will approach the properties of shock waves. When implementing the method, all wells involved in the method create coherent resulting waves, and those, in turn, mutually amplify due to interference in the formation. Thus, the gain of the intensity of the wave action in the reservoir is proportional to the total length of the emitter pipelines for all wells. At the same time, in each well, the volume of fluid falling under the action of high-frequency pulsed discharges from the electrode tip of the cable is also a source of sound waves that are coherent with the main waves. Since a pulsed high-frequency discharge in this frequency range is due to volume polarization (known in physics as E-discharge) and the generated compression-rarefaction waves are caused by a sharp change in the density of the polarized medium of this volume, rather large volumes of liquid are involved in the creation of these sources. The increase in the intensity of the resulting wave in the reservoir from this effect is already proportional to the number of wells, since the total volume of the well fluid, which is a body-distributed source of coherent waves, is proportionally increased.

In an advantageous embodiment of the method, the effects of the mutual influence of thermal and acoustic effects are significant, primarily due to the combination of heat and acoustic field sources in space. This combination, which is one of the identifying factors of the method, is due to the fact that the heating and mechanical forces causing fluctuations in the metal of the pipelines are created by the same physical effect induced (induced or concentrated in the metal of the pipeline using a pulsed high-frequency electromagnetic field) current, only the thermal effect is created in accordance with Ohm's law, and the mechanical effect is in accordance with the law of the electrodynamic interaction of the induced current with the line current energy distribution.

This interaction is especially significant in the production of viscous and super-viscous oil. The heating of this oil in the near-surface zone of the vibrating part of the metal of the pipelines significantly reduces the so-called "radiation resistance", which is determined by the force acting on the medium side and causing the absorption of mechanical energy by a viscous medium. The sound emission efficiency also increases with increasing frequency due to a decrease in the effect of “pushing out” and “drawing in” particles during oscillations. Heating of the near-surface zone to 50-90 degrees. Celsius reduces the viscosity of the medium near the surface by hundreds of times, and when the frequency increases to 5-20 kHz, almost all the mechanical energy of the oscillating body is converted into the energy of a propagating sound wave. In turn, sound exposure also reduces viscosity. Numerous studies have found that the effect of ultrasound on viscosity can produce an effect similar to heating a medium by 50 degrees. Thus, there is a nonlinear (mutually reinforcing) interaction of the thermal and acoustic energy flux.

A special role for the implementation of the method is played by the distribution of heating over the volume of the medium inside the pipeline system of wells. Actually, the volumetric heating of a viscous medium to technological temperatures, which reduces the viscosity to values not only sufficient for pumping it, but to a liquid state, the elastic properties of which are crucial to reduce the absorption of sound waves from volumetric distributed sources and the accumulation of wave energy due to their summation and mutual amplification due to interference, allows you to transfer this accumulated energy to the end user in the reservoir, where it is converted to the mind according to known physical laws nshenie oil adhesion to the rock, reducing the shear viscosity, increase the porosity of the formation and other effects, increases the flow of oil in the well.

As mentioned above, the use of a fluid flow (hydrodynamically), which is a good conductor of wave energy, to create volumetric sources of surface pipelines associated with boreholes is especially unique for an almost unlimited increase in the intensity of wave action on the formation. In this case, all the wave energy created in the system in the volume of all connected pipelines on the surface and in the wells is closed, and in the formation it is open, since it is consumed there.

Moreover, the use of heated low-viscosity fluid for injection into the formation not only increases the temperature of the formation, but also contributes to the delivery of wave energy to low-permeability areas.

This feature of the method, which consists in the possibility of accumulating wave energy in the volume of a group of wells, i.e. the summation and concentration of coherent sound waves within their pipelines and their mutual amplification in intensity from all sound sources (terrestrial and underground) generated by the pulsed high-frequency current of all transmission lines distributed over land pipelines and well pipelines, distinguishes and creates advantages compared to the above method (Patent RU 2361070), which also uses the multipoint effect distributed both in the depth of the wells and on the surface of the sources, the excitation being maneuvers are carried out by a pulsed (shock) method, and in which, to some extent, the effect of superposition of in-phase oscillations is also used. This advantage consists in controlling the redistribution (i.e., sewerage and direction) of the flow of this energy into the volume of the entire oil reservoir, which is achieved by the optimal choice of a group of wave energy emitting wells in the reservoir. For this, based on previously conducted geophysical surveys, by acoustic sounding of the formation, it is necessary to establish the wells that have the best acoustic connection with the oil reservoir, and determine the group of these wells, the radiation from which will cover the entire reservoir. At the same time, the coherence of radiation into the formation from all emitter wells provides an even greater advantage, which ensures an increase in the intensity of the impact in the entire volume of the wave energy blocked by the radiation into the oil reservoir, and not in the focused zones, as in the analogue mentioned above. For viscous oil fields, this advantage is crucial.

Compared to heating cables and other types of heaters, the described method has the main advantage, which from the point of view of heating consists in the formation of heat sources directly in the metal of the wells without thermal overload of the cable insulation and an order of magnitude greater specific power.

Compared with continuous high frequency induction heating systems, the claimed method also has significant differences and advantages. The difference is due to the pulsed mode of creating a high-frequency current in the transmission line and the possibility of proportionally decreasing the pulse duration to increase the energy of the pulse itself. The high frequency of the current in the pulse and the high energy in the current pulse create a synergistic effect of increasing the flow of heat power per unit length of the energy transmission line, which, in fact, makes it possible to heat massive pipes with one or two conductors laid along the pipeline. In standard high-frequency heating, this would require a winding of turns of wire around a pipe with a certain winding density.

The greatest effect when implementing the method described above, in which even greater accumulation of wave energy in the reservoir is achieved, is achieved by covering flow and pressure pipelines that are hydrodynamically connected with this group of wells by energy transfer lines and by the action of synchronous pulses, while some wells from this group and onshore pipelines covered by cable lines are used for pumping coolant, which, in turn, use heated well fluid and other wells in the same group.

In a preferred embodiment of the method, the effect is carried out in a group of wells, for example, one or more injection wells and all production wells dependent on them, by covering them with cable lines from their surface part to the bottom. In this case, all pulsed high-frequency power generators are tuned in order to create pulses of the same duration and frequency in all cable lines, and by increasing the pulse repetition rate, coherent acoustic waves are created, while the properties of well pipelines are used to enhance the penetration of the latter into the reservoir volume, filled with liquid, as amplifiers of coherent waves due to their volume interference and as guiding waveguides for emitting these waves into the formation, for which mny liquid heating produce temperature to reduce the viscosity to values which allow to minimize the absorption of mechanical oscillations in the pipes and acoustic waves in the well fluid.

With such an implementation, the possibility of creating sources of coherent sound waves distributed in a large volume (the volume of piping systems of all wells) and an unlimited increase in the volume of these sources, and thereby the intensity of wave action due to an increase in the number and length of pipelines, wells involved, concentration in the volume of wells of all generated wave energy and, through the use of the guiding properties of the wells, to obtain an overwhelming effect and intensification of wave action in the reservoir due to their further interference in the reservoir. In other words, for radiation into the formation, a large-scale (on the scale of the borehole arrangement of the entire formation) sound directed laser is created. Simultaneous heating of the fluid in the well, a decrease in its viscosity and acoustic resistance intensifies the wave process in it, reduces the loss of its energy and increases the transfer of this energy to the formation, which, in turn, accelerates the heat and mass transfer of the borehole fluid with the formation, thereby also creating a super-total effect integrated exposure.

This new result is manifested even more when they cover flow and injection pipelines that are hydrodynamically connected with this group of wells by transmission lines and synchronous pulses, while some wells from this group and land pipelines covered by cable lines are used to pump coolant, for which in turn, heated well fluid from other wells of the same group is used. Due to the hydrodynamic coupling, which is closed along the formation and on the ground communications, which is a conductor and accumulator of wave acoustic energy from all distributed sources, the total effect on the formation is further enhanced (due to the coherence properties). In this case, ground pipelines play the role of an acoustic and partially heat “gun”, and the flow of heated fluid plays the role of an effective conductor of acoustic energy into the formation.

The simplest unified and universal device that implements the described method is a device containing a group of generators consisting of a capacitive storage device, for example, an electric capacitor and a discharge semiconductor device, also containing a power supply unit for charging electric storage capacitors in the form of a DC filter connected through a rectifier to AC three-phase current networks, as well as control units, in which, unlike similar devices, generators and a power supply unit To charge storage capacitors, they are placed in a group of wells and pipelines so that the former are combined with cable lines for transmitting energy in wells and lines for transmitting on land pipelines so that cable lines and lines for transmitting energy are included in the discharge circuit of each individual generator as a load and placed near them, and the power supply for the charge is connected to the generators by a common charge circuit.

 A feature of the claimed device, which implements a method of intensifying the production of viscous oil, is that the distributed effect on the formation, carried out by a distributed system of generators, allows you to increase capacity both at each well and increase them by increasing the number of processed wells by increasing the number of generators. Due to this, the device is mobile due to the possibility of its rapid deployment and easily adaptable to new facilities. Another valuable property is a simplified power supply system, since power supplies can be connected in different places of the power system, where its reserve capacities allow it.

FIG. 1 shows a general view of a device for intensifying the production of viscous and super-viscous oil together with a production unit, FIG. 1, numbers 1-3 indicate the cables located respectively in the annular space of the producing well, on the surface of the injection pipeline and inside the tubing of the injection well. Cables 1 and 3 from the opposite end from the connection of the generators are closed to the pipe string through the borehole medium.

Figure 2 shows a detailed view of the placement of cables in wells.

Figure 3 shows the charge-discharge circuit of each generator 1, 2, 3, the circuit consists of a capacitive energy storage device in the form of a capacitor C, a semiconductor switch with reverse conductivity in the form of a thyristor VS and a diode VD. To decouple the output circuit and match the load (cable), a pulse transformer T was used. The generator power supply 4 is a three-phase rectifier connected to the power supply at the input, and through the buffer choke L to the output of the capacitor capacitance C of all generators. A single control unit for all generators is not shown in the figures.

The device operates as follows. Before the control pulse arrives at the control terminals of the thyristors, the capacitors C are charged by the inductor current to the same voltage, which depends on the accumulated energy in the inductor. When a control pulse is applied to the thyristors of generators 1-3, these capacitors are discharged to the loads in the form of cables. Moreover, since all semiconductor switches are connected in parallel, the discharge time of the capacitors, and hence the pulse duration, will be the same. In this case, the discharge process in each cable is wave, and the wave frequency is determined mainly by the inductive resistance of the cable - pipe string circuit (i.e. cable length) and the capacitance of the generator capacitor. By selecting the latter, it is possible to achieve the optimal frequency and wave parameters of the discharge process in the pulse itself, providing intensive induction heating, and due to the pulse duration, the required level of wave action.

Embodiments are not limited to the embodiments described herein, those skilled in the art based on the information set forth in the description and knowledge of the prior art will appreciate other embodiments of the invention without departing from the spirit and scope of the present invention.

The application does not indicate specific software and hardware for the implementation of all the mentioned devices and blocks, but it should be clear to a specialist in the field of technology that the essence of the invention is not limited to a specific software or hardware implementation, and therefore, any software and hardware can be used to implement the invention known in the prior art. So, hardware controls can be implemented in one or more specialized integrated circuits, digital signal processors, digital signal processing devices, programmable logic devices, user programmable gate arrays, processors, controllers, microcontrollers, microprocessors, electronic devices, and other electronic modules made with the ability to carry out the functions described in this document, a computer or a combination of the above.

The hardware of the power and mechanical parts can be implemented on the basis of any devices, components and units known in the art that can be adapted by a person skilled in the art to accomplish the tasks solved by the claimed invention.

Claims (22)

1. A method of intensifying oil production, in which:
- create a high-frequency pulse current in a group of two-wire electric energy transmission lines located in a group of wells and consisting of two insulated conductors or one insulated conductor and used as a second metal conductor for pipelines of a group of wells, by means of a group of high-frequency pulse current generators and act on a high-frequency pulse electromagnetic field created by high-frequency pulse current of conductors of a group of two-wire transmission lines, n metal surface pipelines group of wells;
- carry out thermal and acoustic effects on the in-pipe fluid in the group of wells and through it onto the reservoir of oil deposits by heating and mechanical vibrations of the metal of the pipelines that occur when a high-frequency pulse current passes through a two-wire electric energy transmission line;
- carry out additional thermal and acoustic effects on the in-pipe fluid in the group of wells and through it to the oil reservoir by heating and pressure fluctuations arising at the end of the two-wire transmission line as a result of high-frequency pulse discharge through the in-pipe fluid;
characterized in that the high-frequency pulse current generators are tuned to create high-frequency pulse current pulses with the same duration and repetition rate. 2. The method according to claim 1, in which the pulse repetition rate of the high-frequency pulse current is increased until forced metal oscillations of the pipelines of the group of wells appear at a frequency equal to the pulse repetition frequency of the high-frequency pulse current and the group of wells produces coherent sound waves in the fluid volume . 3. The method according to claim 2, in which an increase in the intensity of coherent sound waves in the volume of the liquid of a group of wells is achieved by heating this volume with a high-frequency pulse current to a temperature above the melting temperature of the viscous components of the in-pipe liquid in the surface zone of the pipeline metal. 4. The method according to claim 3, in which the volume of the in-pipe fluid is heated to a temperature of decreasing viscosity to values that minimize the absorption of sound waves in this fluid in the group of wells. 5. The method according to claim 4, in which the ratio of the heating power of the metal and the power of mechanical vibrations in the pipelines is controlled by changing the ratio of the current frequency of the high-frequency pulse current and the pulse duration of the high-frequency pulse current. 6. The method according to claims 1-5, in which the flow and injection, pressure, and prefabricated pipelines are hydrodynamically connected to this group of wells using a group of high-frequency pulse current generators and a group of two-wire electric energy transmission lines located on the surface surfaces near these pipelines, either along their outer surface or inside them. 7. The method according to claim 6, in which the pulses of high-frequency pulse current in flow, injection, pressure and prefabricated pipelines are synchronized by the pulse duration and frequency of their repetition with similar pulses in a group of two-wire transmission lines located in the pipelines of each well of a group of wells, hydrodynamically related to them. 8. The method according to claim 7, in which the waveguide and directing properties of pipelines filled with liquid or gas are used to accumulate and enhance the intensity of wave energy in a group of wells created by high-frequency pulse current in all electric energy transmission lines distributed over the surface and downhole pipelines, and by the optimal selection of a group of wells based on geological and geophysical surveys, they cover the entire oil reservoir by impact. 9. The method of claim 8, in which part of the wells from the group of wells are used to pump coolant into the reservoir. 10. The method according to claim 9, in which a heated well fluid from other wells of the group is used as a heat carrier. 11. A device for intensifying oil production, containing:
- a group of high-frequency pulse current generators containing capacitive energy storage devices and a discharge circuit based on semiconductor switches, as well as electric power transmission lines connected to the discharge circuit of the said generators, located in each well from a group of wells, configured to conduct high-frequency pulse currents along pipelines and through this create vibromechanical vibrations and heat in the pipelines along the entire length of the placement of these transmission lines;
moreover, the high-frequency pulse current generators are located near the transmission line and are configured to create high-frequency pulse current pulses with the same duration and repetition rate. 12. The device according to claim 11, in which the high-frequency signal generators are connected by a common charge circuit of capacitive storage devices connected through a DC filter to a network rectifier. 13. The device according to claim 11, in which the transmission lines are made in the form of two insulated metal conductors mounted on the surface of the pipelines with a longitudinal displacement relative to each other. 14. The device according to item 12, in which the transmission lines are made in the form of two insulated metal conductors mounted on the surface of the pipelines with a longitudinal displacement relative to each other. 15. The device according to claims 11-14, in which the metal conductors of the energy transmission line are installed inside the pipelines and additionally at the end opposite from the end of the connection of the generators, contain electrodes configured for high-frequency pulse discharge through the piping fluid. 16. The device according to clause 15, in which each metal conductor of the power transmission line is a distributed heating source. 17. The device according to clause 16, in which each metal conductor of the power transmission line is a distributed source of mechanical vibrations. 18. The device according to claims 11-14, 16, 17, in which energy transmission lines are located in each well from a group of wells and on flow, injection, prefabricated and pressure pipelines, hydrodynamically connected with this group of wells. 19. The device according to clause 15, in which the energy transmission lines are placed in each well from a group of wells and on flow, injection, prefabricated and pressure pipelines, hydrodynamically associated with this group of wells. 20. The device according to PP.11-14, 16, 17, 19, in which the insulated metal conductors of the energy transmission line are additionally configured to conduct such high-frequency pulsed currents to heat the oil to a temperature lowering viscosity to values that reduce the absorption of mechanical vibrations . 21. The device according to clause 15, in which the insulated metal conductors of the energy transmission line are additionally configured to heat oil to a temperature of decreasing viscosity to values that reduce the absorption of mechanical vibrations. 22. The device according to p, in which the insulated metal conductors of the energy transmission line are additionally configured to heat the oil to a temperature lowering viscosity to values that reduce the absorption of mechanical vibrations.

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