RU2379489C1 - Oil recovery intensification method and non-operating oil wells recovery using reservoir electromagnetic resonant treatment - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: according to a method, generate in a reservoir modulate electromagnetic vibrations with a help of surface or well located electromagnetic waves generators, directed from a production well and opposite, at least from one neighbouring well to one production well. Overlap generated opposite electromagnetic fluctuation with a help of control devices and a generator-receiver, located on the surface, on a hydrocarbon own vibration frequency, creating resonant vibration frequency, which generates hydrocarbon fluids molecules and atoms vibration with a pick resonant amplitude in vertical, horizontal and other plane. Direct each of hydrocarbon fluid generated molecules or atoms pick resonant vibration, in their hitting with collector skeleton process, towards to the production well with repeating runs. For runs initiation primary set up a rate on a vibration flow from the production well, which significantly exceeds flow rate of each opposite vibration flow, taking into account attenuation coefficients. Further more the vibration flow rate from the production well smoothly decreasing with simultaneous proportional smooth flow rate increase of each opposite vibration flow. At the process beginning localise the pick resonant appearance zones near by the neighbouring wells, at the nearest place of hydrocarbon fluid, blocked with reservoir water, location in the opposite to the production well point, then moving it towards the production well in a forced control regime.

EFFECT: oil recovery efficiency increase due to oil recovery factor increase not only for operating wells, but also for wells under lasting stand by.

5 cl, 15 dwg

Description

The invention relates to the oil and gas industry and can be used both for intensification of oil or gas condensate production with increasing well production, and for resuscitation of idle oil or gas condensate wells with an increase in oil recovery factor (ORF) while reducing the water cut of the pumped oil or gas-liquid mixture by electromagnetic resonance impact on the reservoir.

The application in the field of oil and gas production of wave (mechanical, electromagnetic, acoustic, etc.) effects on the fluid is due to a number of its advantages: a high degree of controllability, the manifestation of the effect in the short time after the start of the impact, the ability to carry out the impact simultaneously with the main production process, without interfering with it and other

A known method of influencing the fluid of oil fields during oil production, including the creation of an oscillatory process directly in the processed oil fluid by carrying electromagnetic waves in the frequency range from 3 * 10 ^-5 to 3 * 10 ¹⁴ Hz or ultrasonic waves in the frequency range from 1.5 * 10 ⁴ to 10 ⁹ Hz, or acoustic waves in the frequency range from 17 Hz to 20 kHz, which modulate information signals, resonant hydrocarbons of the processed oil fluid, and form standing waves (RU No. 2281387 C2, ЕВВ 43/16, publ. 20.04. 2006). The directional standing waves are generated by a resonant-wave device (generator) immersed in the well, and the resonant, standing waves are controlled by an antenna field located on the surface, which includes moving resonant modules, waveguides, etc.

Using the known method of resonant-wave action on the fluid allows you to reanimate the wells and significantly extend the life of fields characterized by low flow rate, waterflooding, heavy oils, etc., by increasing the oil recovery coefficient, its quality and rheological properties, while reducing the water content in the pumped fluid , reduce costs and terms of field development by reducing the number of wells drilled with increasing distance between them.

With the obvious effectiveness of the known method, it, however, has a significant drawback, which is that the wave resonance effect on the gas-liquid mixture is carried out only in the bottomhole zone, and this only leads to an increase in the hydrodynamic properties of the produced fluid at its location in the reservoir. The movement of the excited fluid from the reservoir to the production well is traditionally carried out by creating a depression on the reservoir by reducing the dynamic level of the borehole fluid in the casing of the well. Thus, the known method does not use the full potential of the resonance-wave action.

The known method adopted for the prototype, in which the wave oscillations of mechanical and electromagnetic generators are used to form and search for a hydrocarbon field (RU No. 2103483; ЕВВ 43/16, 43/24, G01V 1/40, publ. 07.01.1998) by heating the alleged oil and gas reservoir with external coolants controlled from the day surface and used for operational impact on the reservoir during hydrocarbon production, intensification of flow rate and secondary exposure to the contained fluids in the reservoir, in which the coolant is fed into layer in the form of wave energy. At the same time, in order to improve the filtration of fluids into the well during its testing for inflow on the surface above the expected production area, they are installed in a certain order that provides thermal coverage of the area, at the same time mechanical and electromagnetic wave generators. Moreover, electromagnetic generators have galleries sequentially covering their entire estimated productive area with their radiation, containing dipoles that generate carrier sinusoidal electromagnetic field packages with antinodes located in the middle of the thickness of the layer, and the modulating electromagnetic field of increased frequency is turned on and off respectively at the upper and lower boundaries of the layer superimposed on the carrier sinusoidal package. The boundaries of the heated formation stratum are regulated by the signal of the phase indicator connected to the output of the master oscillator of a sinusoidal signal of the electromagnetic field, determined by the depth of the estimated reservoir by the results of preliminary geological and geophysical surveys, and the frequency of the modulating high-frequency filling electromagnetic field is selected based on the distribution of the pore sizes of the formation. Moreover, the high-frequency electromagnetic field simultaneously causes the reciprocating motion of the fluids and the alternate repolarization of the skeleton of the reservoir, leading to thermal losses in the skeleton due to the formation of hysteresis phenomena during polarization of the dielectric of the skeleton by the electric field vector of the electromagnetic wave. The joint movement of fluids and heat transfer from the skeleton to the fluids is used to form continuous gas and oil phases, leading to the appearance of pop-up forces and acting on these phases in the direction of the upper boundary of the reservoir. The above operations are carried out until the gas-oil and water-oil contacts are detected and monitored from the surface using seismic acquisition stations and a secondary test of the exploration well takes place before gas and oil production. Additionally, to circumvent aggravating factors in the form of an aquifer or trap layer located above the proposed hydrocarbon field, the upper and lower boundaries of the proposed reservoir are connected to the surface using externally electrically insulated casing strings. To do this, two auxiliary additional wells are drilled in the area of the proposed field, one of them having electrical contact with the lower boundary of the reservoir, and the other with the upper boundary of the same reservoir. The supply of electromagnetic field waves to each of the electrically insulated wells is carried out according to the principle of opposite polarities in each half-cycle, for which the output of the dipoles is connected through the switching elements to the electrically conductive layer of casing strings. In addition, to create and attract helicons to thermal sensing of the proposed productive horizon, the casing of the exploratory test well and the casing of auxiliary auxiliary wells with an externally electrically insulated outer side surface, as well as the bodies of mechanical wave generators, are equipped with solenoids through which direct current is transmitted so that so that magnetic field lines penetrate the formation and close on the casing of the exploratory test well. And finally, to control the end of the process of formation of a hydrocarbon field and the termination of work on heating the reservoir, saving energy and labor costs, wave generators are installed on the radii between the exploratory well and the border of the hydrocarbon collection area, along the radius, gas and water-oil contacts are searched by sending wave pulses and receiving their reflections by the geophysical stations, and information from the geophysical stations is transmitted to the command information center to determine the coordinates at the boundaries of gas and oil-water contacts on each of the radii and their subsequent highlighting on the display screen, and the vertical coordinate of the borders of gas and oil-water contacts determines the depth of gas and oil-water contacts of the entire field.

Moreover, in his article “A stand for determining the oil and gas recovery of rock samples, a vibration exciter for this stand and the results of its tests” (Yu.A. Afinogenov. Siberian Branch of the RAS. Institute of Hydrodynamics. Acoustics of Inhomogeneous Media. Issue 112. Novosibirsk, 1997), the author of the method the prototype clarifies that it is of interest to consider the rock skeleton as a vibratory conveyor when transmitting different pulse periodic vibrations to it, in which the fluid inside the skeleton begins to move in communicating pore space in a given direction.

The disadvantage of this method also lies in the fact that the full potential of the wave action on the hydrocarbon fluid is not used. In this case, we are talking about the simultaneous resonance-wave action at several points along the contour of the proposed oil and gas bearing formation in order to create vibrational excitation of the formation fluid in individual zones of the oil-bearing reservoir with elements of the local vibro conveyor effect. As a result, a straining impulse is imparted in a certain direction to oil accumulations trapped and captured, however, forced movement of excited oil accumulations from the reservoir along a closed circuit from the injection well directly to the producing well does not occur in a controlled manner.

The present invention is directed not only to the resonant excitation of formation fluid hydrocarbons in separately selected, specified using the prototype method, sections of the oil reservoir by imparting a straining impulse in a certain direction, but also to the subsequent controlled directional movement of formation hydrocarbons in a closed system from the injection or nearest neighboring wells or groups of nearby neighboring wells, through a reservoir, directly to a specific production well e, is the most thoroughly prodavlivaya location hydrocarbon fractions blocked formation water (traps and slivers).

The technical result achieved in this case consists in a substantial increase in the production rate, as well as in an increase in the efficiency of oil production by significantly increasing the oil recovery coefficient (CIN) not only in existing wells, but also in the reanimation of wells that have been idle for many years, in which, due to imperfections, previously used Technologies have managed to extract at the moment only 20-30 %% of the identified hydrocarbon deposits.

The specified technical result is achieved by the fact that in the method of intensifying oil production and resuscitation of idle wells, in which using resonant wave generators located on the surface or submerged in the well, electromagnetic waves are generated in the reservoir, which superimpose on the natural frequency of the hydrocarbons of the processed fluid, forming resonant electromagnetic waves, and control the resonant waves using the equipment located on the surface, according to In the reservoir, modulated electromagnetic oscillations of the same frequency are created in the reservoir, directed counterclockwise from the producing well and from the nearest neighboring well or a group of nearest neighboring wells, then resonant electromagnetic oscillations are formed using superimposed on the surface of the control equipment and the receiver-generator by superimposing on the natural frequency of hydrocarbon vibrations the processed fluid and direct each of the resulting peak resonance oscillations in the direction of the producing well for repetitive runs, for which they initially set the wave flux from the producing well to a power significantly exceeding the power of each of the oncoming wave flux taking into account the attenuation coefficients, and subsequently, the power of the oscillating flux from the producing well is smoothly reduced with a simultaneous proportional smooth increase in the power of each of the oncoming vibrational fluxes , while the zones of peak resonance at the beginning of the process are localized near each of the nearest neighboring wells, Then it moves in a forced controlled mode directly to the production well, or, in the case of resuscitation of idle wells, at the point of the closest location of the fluid blocked by produced water at its point farthest from the production well, causing the molecules and atoms of the hydrocarbon fluid to oscillate with a peak resonant amplitude in the vertical, horizontal or other plane, moving to the producing well in the process of collisions with the skeleton of the collector when moving the peak resonance to repeated runs at a controlled fashion on the analogy with Vibrating.

To give an additional driving force to the movement of the hydrocarbon fluid, two paired traveling peak resonant electromagnetic waves with a phase shift relative to each other are generated.

The physical essence of the proposed method, reproducing the effect of the vibratory conveyor for transporting bulk cargo, when the particles of the bulk substance, colliding with the surface of the vibrating conveyor, get directional movement to the destination, is to excite the hydrocarbon fluid when its molecules and atoms begin to oscillate with a peak resonant amplitude in the vertical direction and move to the production well in the process of collisions with the skeleton of the collector due to the movement of the peak ansa repeated runs in a controlled manner. The proposed innovative principle can be called a “closed type hydrocarbon fluid vibro-conveyor” in a closed system - from the injection or the closest neighboring well or group of them, the area of which is located at a particular field due to production or other necessity, through the reservoir directly to the producing well, the most thoroughly pushing the location of hydrocarbon fractions blocked by formation water (traps). Otherwise, the proposed innovative principle can be called "directionally running peak resonance", which creates a significant additional directional pressure in the reservoir. The specified pressure additionally, in addition to the traditional depression, significantly enhances the directed movement of the fluid towards the production well throughout the reservoir, including, as already mentioned, oil accumulations (traps and captures) isolated by reservoir water, along the radii from the nearest neighboring ones, including injection ones, wells.

In addition, the effect of additional effort to move the hydrocarbon fluid to the production well is achieved by injecting a molecular magnetic solution, such as iron salts, or a colloidal solution with ferromagnetic nanofraction particles into the reservoir, not only due to their interaction with hydrocarbons, but also due to the physics phenomena of electromagnetic pressure (see. General course of physics of D.V. Sivukhin. Textbook for universities in 5 volumes. T.3. Electricity. - 5th ed., STER. - M .: FIZMATLIT, 2006). As you know, even Maxwell showed that electromagnetic waves, reflected or absorbed in the bodies to which they fall, exert pressure on them. This pressure is the result of the influence of the magnetic field of the wave on the electric currents excited by the electric field of the same wave, and sometimes also the effect of the electric field on the charges induced in the substance by the same field. As a result, a force begins to act in the direction of wave propagation, which causes the pressure of this electromagnetic wave. In the proposed method, thus, the specified force carries away in the process of directional movement of metal particles and the oil fraction.

To enhance the directed flow of a molecular magnetic solution or a colloidal solution of ferromagnetic particles, solenoids fed by direct current and creating a closed accelerating magnetic field between themselves can be installed directly on the generators.

To ensure the extrusion effect, peak resonant electromagnetic waves are generated on the walls of the reservoir.

The proposed method is illustrated in graphic material, which presents:

figure 1 - diagram of the implementation of the method, side view;

figure 2 - high-frequency sinusoidal electromagnetic waves corresponding to the natural frequency of hydrocarbon fluids in reservoir conditions;

figure 3 - low-frequency electromagnetic carrier oscillations;

figure 4 - modulated electromagnetic waves obtained by superimposing the oscillations presented in figure 2, on the oscillations presented in figure 3;

figure 5 - the result of the overlap of opposite-directional modulated electromagnetic waves with the localization of the occurrence of peak resonance near one of the nearest neighboring wells;

on figa - the result of overlapping counter-modulated electromagnetic waves with localization of the peak resonance at an equal distance between the producing and neighboring wells;

on figb - the result of overlapping each other counter-directional modulated electromagnetic waves with localization of the occurrence of peak resonance near the producing well;

Fig.6 is a variant of the propagation of modulated electromagnetic oscillations decaying as they propagate in the reservoir, directed from the side of the producing well, when their amplitude is delineated by a damped sinusoidal low-frequency function;

on figa is a variant of the propagation of modulated electromagnetic oscillations decaying as they propagate in the reservoir, directed from the side of a neighboring well, when their amplitude is delineated by a damped sinusoidal low-frequency function;

in Fig.7 - the result of overlapping counter-directional damped modulated electromagnetic oscillations when contouring their amplitudes with a damped sinusoidal low-frequency function with localization of the occurrence of peak resonance near the nearest neighboring well;

on figa - the result of overlapping counter-directional damped modulated electromagnetic waves when contouring their amplitude damped sinusoidal low-frequency function with the localization of the peak resonance at an equal distance between the producing and injection wells;

on figb - the result of overlapping opposite-directional damped modulated electromagnetic waves when contouring their amplitude damped sinusoidal low-frequency function with the localization of the occurrence of peak resonance near the production well;

in Fig.8 is a fragment of a diagram of the implementation of the method of Fig.1 in the case of the presence of traps in the reservoir, side view;

on figa is a horizontal section aa in Fig.8;

figure 9 is a diagram of the implementation of the method in the case of traps isolated by formation water with injection into the reservoir of a molecular magnetic solution or colloidal solution of ferromagnetic particles as a working fluid and with solenoids mounted on generators, side view.

The method of intensification of oil production is as follows.

In the production well 1 (Fig. 1), limited by the casing string 2, the production pump 3 (in this case, the deep-well sucker-rod pump SHGN), connected to the string of tubing 4 (tubing), is lowered and installed at a depth H of the _pump . On the surface of the wellhead, placed electromagnetic oscillation generator 5 connected to the directional waveguide 6, the descent into the wellbore before lowering the pump 3 and the extractive fixed in perforations in _{the perforation} depth H anchor zone 7. To improve the process efficiency of the generator is possible descent 5 electromagnetic waves directly into the perforation zone of the producing well.

Above the mouth of a nearby (including injection) well 8, limited by a casing string 9, an electromagnetic oscillation generator 10 is placed, to which a directional waveguide 11 is connected. The waveguide 11 is lowered into the well before the launch of the tubing string 12 and fixed in the perforation zone at the depth H of the _{perforation by the} armature 13. In order to increase the efficiency of the process, the electromagnetic oscillation generator 10 is lowered directly into the well perforation zone.

In this case, the reservoir, as a conditional example, contains hydrocarbon fluid 14 (oil fraction or gas condensate), separated from the formation water 15 by the oil-water contact (WOC) 16.

Generators 5 and 10, included in the production process, create counter-directed oscillatory flows in the reservoir. In this case, the flow of electromagnetic waves 17 created by the generator 5, through the waveguide 6 is directed through the reservoir from the producing well 1, and the stream of electromagnetic waves 18 from the generator 10 through the waveguide 11 is directed opposite to the producing well 1 also through the reservoir.

On the surface, approximately equidistant from wells 1 and 8, control equipment (not shown) and a scanning oscillation receiver 19 are located 20. To increase the efficiency, several receiver generators can be used along the entire length from neighboring wells to the production well. The specified equipment superimpose frequencies of opposing oscillations 17 and 18 and the natural frequency of the hydrocarbon fluid 14.

In the production process, carried out in the traditional way, in the injection well 8 using the injection pump 21, located on the surface, the flow 22 of the working fluid is injected into the reservoir through the perforations in the casing 9. With the established mode of production in the production well 1 in the space between the casing string 2 and the tubing string 4 at a depth of H _din installed column of borehole fluid. The indicated depth is the dynamic level of the produced fluid, which is sampled using a production pump 3, receiving, in this example, reciprocating movement from the rocking machine 23.

Oscillator 5 and 10 both produce high harmonic electromagnetic wave 24 (Figure 2), extending the period T _HF, deposited along a time axis t, and the amplitude A _HF, deposition deviations along the axis X, and low frequency sinusoidal electromagnetic wave 25 (Figure .3) propagating with a period of T _LF deferred along the time axis t, and an amplitude A _LF deferred along the axis of deviations X.

Inside the generators 5 and 10, using the known special equipment called adders, superimposed high-frequency electromagnetic waves, presented in figure 2, on low-frequency electromagnetic waves, presented in figure 3. As a result of the superposition (Fig. 4), modulated sinusoidal deep-penetrating electromagnetic oscillations 26 are generated, propagating with a period of T _LF , delayed along the time axis t, having a harmonic with a period of T _HF , and with an amplitude A _mode = A _HF , deposited along the deviation axis X. Modulated electromagnetic waves 26 are depicted in FIG. 1 as electromagnetic waves 17 and 18, which are generated by generators 5 and 10, respectively, and transmitted along waveguides 6 and 11.

Using control equipment and a receiver-generator 19 of sounding oscillations 20, modulated electromagnetic oscillations 17 and 18, having amplitudes A _mod1 and A _mod2 (Fig. 5), are applied to the natural frequency of vibrations 27 of a hydrocarbon fluid with amplitude A of its _own . As a result of superposition, a resonance oscillation 28 occurs with the amplitude A of the _resonance . Moreover, it should be noted that the deviation of the natural vibrations of the hydrocarbon fluid throughout the entire productive formation is scanned by the receiver-generator 19 (or their family), ahead of the repeated runs of the resonant peak and precautionarily correcting the characteristics of the electromagnetic fluxes 17 and 18 emitted through the producing 1 and injection 8 wells.

Figure 5 also reflects the resonant oscillation 28 of the opposite directional oscillatory fluxes: with the amplitude A of the _{resonance 1} near the production well, conventionally depicted by the X axis _ext. , and with the amplitude A of _{resonance 2} near the injection well, conventionally depicted by the X axis _n.sq. , taking into account the attenuation coefficients along the time axis t. Moreover, the origin of the peak resonance with the amplitude A _peak is localized near the injection well, for which modulated electromagnetic waves are emitted in a controlled manner so that the radiation power from the producing well with amplitude A _mod1 significantly exceeds the power of the oncoming radiation from the injection well with amplitude A _mod2 . Then, the peak resonance begins its forced controlled movement towards the producing well with a velocity V of _{resonance movement} .

Further emitting (Fig. 5a) in a controlled mode modulated electromagnetic waves in such a way that the radiation power from the producing well with amplitude A _mod1 decreases smoothly to a comparable power of smoothly increasing counter radiation from the injection well with amplitude

And _mod2 , and taking into account the attenuation coefficients along the time axis t, move the peak resonance with the amplitude A _peak and with the speed V of _{the resonance moving} towards the producing well with repeated runs.

And finally, continuing to emit further modulated electromagnetic waves in a controlled manner in such a way that the radiation power from the producing well with amplitude A _{mod1 is} set to the calculated minimum value, and the radiation power from the injection well continues to smoothly increase to the calculated maximum power with amplitude A _mod2 , and taking into account the attenuation coefficients along the time axis t, the peak resonance amplitude is approximated

And the _peak with a speed V of _{the resonance movement} to the production well with repeated runs, as shown in Fig.5b.

Oscillation generators 5 and 10 can simultaneously generate high-frequency harmonic electromagnetic waves 24 (see figure 2) and low-frequency electromagnetic pulsating oscillations. The result of the superposition (Fig. 6) is oscillations 29 with a pulsating amplitude A, _pulsar1 , which propagates (with the damping function 30 and 31 and axes 32 and 33) along the time axis t with a period of T _high , having harmonics with a period of T _low , as applied to the producing well 1. With reference to the injection well (figa), these superimposed oscillations have the form of a counterpropagating wave 34 with a pulsating amplitude A _pulsar2 , which propagates (with attenuation functions 35 and 36 and axes 37 and 38) along the time axis t with a period of T _H , having harmonics with period T _lf.

The modulated pulsating opposite directional oscillations 29 and 34 (Fig. 7), as well as the modulated sinusoidal opposite directional oscillations 17 and 18, shown in Figs. 5-5a, superimposed on the natural oscillation frequency 27 of the hydrocarbon fluid with amplitude A of its _own , introduce a productive formation in a resonant state with oscillations 39 of amplitude A of _{resonance 1} near the producing well and oscillations of amplitude A of _{resonance 2} near the injection well.

Similar to the modulation mode of sinusoidal oscillations, emitting in a controlled mode modulated pulsating electromagnetic waves in such a way that the radiation power from the producing well with amplitude A _pulsar1 significantly exceeds the power of the oncoming radiation from the injection well with amplitude A _pulsar2 , taking into account the attenuation coefficients along the time axis, initially form peak resonant amplitude A _peak near the injection well, as shown in Fig.7.

Further emitting in a controlled mode modulated electromagnetic waves in such a way that the radiation power from the producing well with amplitude

And _{pulsar1 is} reduced smoothly to a comparable power of smoothly increasing oncoming oscillations from an injection well with amplitude A, _pulsar2 and, taking into account the attenuation coefficients along the time axis, the peak resonance amplitude A _{peak is moved} at a speed V from the injection well to the producing one with repeated runs, as shown in FIG. 7a.

And finally, while continuing to emit further modulated electromagnetic waves in such a way that the radiation power from the producing well with amplitude A _{pulsir1 is} set to the calculated minimum value, and the radiation power from the injection well continues to smoothly increase to the estimated maximum power with amplitude A _pulsar2 and based on attenuation coefficients along the time axis approximate peak resonant amplitude a from _peak velocity V repeating _movement to the production well Xia runs, as shown in 7B.

The effect of the invention is also achieved if necessary, the resuscitation of idle wells for many years. In this case (Fig. 8 and 8a), the flow of electromagnetic waves 17 from the waveguide 6 is directed towards the injection well 8 through the reservoir, in which the oil fraction 14 is blocked by formation water 15 in the trap 40. At the same time, the flow of electromagnetic waves 18 from the waveguide 11 direct counter to the side of the producing well through the reservoir. Using equipment located on the surface, superimposed frequencies of opposing oscillations 17 and 18 and the natural frequency of the hydrocarbon fluid 14 directly in the area of its localization. In this case, the coordinates of the running peak resonance are formed at the point of the trap 40 far from the production well and then the peak resonance is moved with a speed V of _{displacement by} repeated runs towards the production well so that the activated excited hydrocarbons are released from the trap 40 and rush to the production well 1 , restoring its productivity.

In order to increase the efficiency of the process (Fig. 9), the electromagnetic oscillation generator 5 is lowered directly into the producing well 1, and the electromagnetic oscillation generator 10, respectively, into the injection well 8. After the generators 5 and 8 are turned on, they start to counter-emit modulated electromagnetic flows 17 and 18 with the aim of exciting the peak resonance and its further controlled movement to the production well 1 by repeated runs. In this case, electricity to the generators 5 and 10 is supplied from ground installations 41 and 42.

An additional force effect for moving the hydrocarbon fluid to the production well (Fig. 9) is also achieved by the fact that during the production process through the injection well 8, a molecular magnetic solution or colloidal solution of ferromagnetic particles 43 of nanofraction, entraining oil fraction 14. To enhance the directed flow of a molecular magnetic solution or colloidal solution of ferromagnetic particles 43 directly to the generators 5 and 10 installed Solenoids 44 and 45, fed by direct current, create an additionally closed accelerating magnetic field.

The disposal process for the reuse of ferromagnetic particles is carried out at the wellhead using electromagnetic forces in specialized traps of magnetically susceptible particles.

A specific calculation example to confirm the physics of the process, the prototype author cites in his other invention No. 2049912 RU “Method for the development of an oil and gas condensate field and equipment for its implementation”, however, the novelty and distinguishing features of invention No. 2103483 RU determined to use it as a prototype.

Using the proposed method allows you to:

- to further increase the production well’s flow rate due to additional forced efforts to move the hydrocarbon fluid to the production well along radii from the nearest neighboring ones, including injection wells;

- significantly increase the oil recovery coefficient (CIN) to 60 percent, including freeing oil from traps and captives, while the CIN, according to the results of the introduction of the analogue and prototype, reaches 40-45 percent;

- to reanimate oil and gas condensate wells, which have been idle for many years due to the previously used inefficient oil production technology.

Claims (5)

1. A method of intensifying oil production and resuscitation of idle oil wells by means of electromagnetic resonance effects on a 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 on the natural frequency of hydrocarbon vibrations fluid, forming resonant electromagnetic waves, and control the resonant waves using placed on the surface of the equipment, characterized in that in the reservoir it creates modulated electromagnetic waves of the same frequency, directed from the producing well and counter to at least one of the nearest neighboring wells in the direction of the producer, impose modulated electromagnetic waves of the same frequency using the control equipment and the receiver generator, placed on the surface, at the natural frequency of vibrations of the hydrocarbon fluid, thereby forming resonant electromagnetic vibrations causing the fucking of molecules and atoms of a hydrocarbon fluid with a peak resonance amplitude in a vertical, horizontal or other plane, and then each of the resulting peak resonances of the vibrations of the molecules and atoms of the hydrocarbon fluid during their collisions with the skeleton of the reservoir towards the producing well with repeated runs, for which they initially set To the oscillatory flow from the producing well, a power significantly exceeding the power of each of the oncoming oscillatory flows, taking into account the attenuation factors then in the future, the power of the oscillatory flow from the producing well is gradually reduced with a simultaneous proportional smooth increase in the power of each of the counter oscillating flows, while the zones of peak resonance at the beginning of the process are localized near the nearest neighboring wells or at the place where the hydrocarbon fluid blocked by formation water is in point opposite from the production well, then moving it in a forced controlled mode directly to the production well important. 2. The method of intensifying oil production and resuscitation of idle oil wells according to claim 1, in which generate two paired running peak resonant electromagnetic waves with a phase displacement, additionally giving a driving force of movement of the hydrocarbon fluid. 3. The method of intensifying oil production and resuscitation of idle oil wells according to claim 1 or 2, in which peak resonant electromagnetic waves are generated on the walls of the reservoir. 4. The method of intensifying oil production and resuscitation of idle oil wells according to claim 1 or 2, in which, as a working fluid, a molecular magnetic solution or a colloidal solution of ferromagnetic particles of nanofraction is injected into the reservoir. 5. The method of intensifying oil production and resuscitation of idle oil wells according to claim 1 or 2, in which directly on top of the generators lowered into the well, solenoids are installed, powered by direct current and creating a closed additional accelerating magnetic field between them.

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