RU2291955C1 - Method for extraction of oil deposit - Google Patents

Abstract

FIELD: oil extractive industry, possible use during extraction of oil pools, in particular at later stages of extraction of watered pools with complicated geological conditions.

SUBSTANCE: method includes geo-physical research of structure of beds and research of wells, drilling of product and force wells, extraction of oil from product wells, forcing of displacing agents into force wells and usage of methods for affecting productive formations. Acoustic emission is registered preliminarily across the area of deposit. On basis of registration results sources of acoustic activity and distribution of fissuring across each productive formation is determined. During extraction, acoustic emission is registered in relation to area also in real time, on basis of total of change of acoustic emission and deposit extraction characteristics, in particular, isobar maps and water content of wells, weakly drained, sediment and washed zones are detected, directions of filtration flows are changed, additional fissure generation is initiated and intensified in weakly drained and sediment zones up to level of registered noises matching level of noises of main displacement vector.

EFFECT: increased efficiency of extraction with increased oil recovery, current and final oil recovery due to operative processing and usage of information received from geological environment, connected to dynamic processes occurring in productive formation across whole area of deposit.

22 cl, 1 ex, 6 dwg

Description

The invention relates to the oil industry, and in particular to methods for developing oil fields, and is intended for use both for newly introduced oil fields and for oil fields under development at any stage of their development, including the final one. The invention can be successfully used in complicated mining conditions.

Known methods for monitoring field development (RF Patent No. 2166630, No. 2135766), including conducting geophysical, geo-field studies of wells and laboratory studies of reservoir fluids and porous media, interpretation of geophysical studies of wells (GIS) and constructing a geological model of the reservoir, mathematical modeling of filtration processes and modeling the state of the oil and gas saturated stratum of the entire field and the processes occurring in it. When implementing these methods on the basis of direct measurements, the structure of the productive stratum and the processes taking place in it only near the well or in the near-well space, as well as changes in a number of characteristics of reservoir rocks during well drilling and operation, are rather accurately and reliably modeled. In the interwell space, the structure of the medium and the processes occurring in it are predicted based on these models. The mismatch between the simulated and real processes determines sufficiently significant deviations of the predicted and obtained production parameters in the wells (flow rate, water cut, pressure, etc.). In addition, obtaining the required output is far from operational. All this noticeably reduces the efficiency of development, increases the risk of making mistaken management decisions to conduct various activities in the field in order to increase oil recovery.

There is also a known development method (RF Patent No. 224321), with control of the movement of injected or circulating water during the development of oil fields, including the study of vertical seismic profiling with the excitation of elastic vibrations at points located on the rays emanating from the wellhead, registration of vibrations in the wells, special processing of data from all subsequent observations, construction of seismological sections from reflected waves.

This method in practice is not effective enough, since it is difficult to carry out in a constantly working field, in addition, the estimates obtained by the method can be obtained cheaper and more quickly from the production data of production wells.

Closest to the proposed invention is a method of developing an oil field (RF Patent No. 2067166), including geophysical studies of the structure of the reservoirs with the presence of deformed structural blocks and active tectonically-deformation zones and well surveys, drilling production and injection wells, oil production from production wells and fluid injection through injection wells and the use of reservoir stimulation methods during field development. The method allows the selection of the location of drilling wells and the order of their introduction into development at the initial and secondary stages, but does not provide reliable information for regulating development at the late and final stages under conditions of severe depletion and water cut of deposits. When implementing the method, there are no opportunities for direct control and monitoring of the methods used to influence the reservoir, which does not allow for effective regulation of the development process, coupled with the optimal impact on the reservoir. The method to a small extent provides an increase in current oil recovery and does not provide an increase in the final oil recovery of the field.

The objective of the invention is to increase the efficiency of development with increasing oil production, increasing the current and final oil recovery by obtaining operational processing and using information obtained from the geological formation medium that is directly or indirectly associated with stress-strain, fluid dynamic and physicochemical processes occurring in the reservoir over the entire area of the deposit, both in its natural state and under the influence of external natural and artificial influences, To create the most favorable conditions for the filtration oil flow to the wells when displacing it with a displacing agent in the fields of the field, to maximize the effectiveness of methods of stimulating formations while reducing energy consumption, expanding the functionality of the method.

To solve the problem in a known method, including geophysical studies of the structure of the reservoirs and exploration of wells, drilling production and injection wells, oil production from production wells, injection of displacing agents through injection wells and the use of methods of exposure to productive formations, according to the invention are pre-recorded by the area of the field seismic acoustic emission, on the basis of which the foci of seismic acoustic activity and the distribution of fracturing for each productive formation, and during the development process, seismic acoustic emission is recorded by area and in real time, by the combination of seismic acoustic emission and field development indicators, in particular isobar maps and water cuts of the wells, weakly drained, stagnant and washed zones are determined, filtration flows change directions, initiate and intensify additional cracking in weakly drained and stagnant zones to the level of recorded noise corresponding to the noise level in the main vector of crowding out.

When implementing the method, it is optimal, from the point of view of minimizing energy costs, to achieve maximum coverage of the formations, to initiate and intensify additional crack formation in weakly drained and stagnant zones by affecting the formations with physical radiation of an artificial and / or natural nature.

It is possible to record seismic acoustic emission over the field’s area in the natural background mode and / or in the mode of the response of the medium induced by external influence.

It is advisable to change the directions of the filtration flows using hydrodynamic methods, in particular cyclic water flooding, drilling additional wells, and / or physical methods, in particular wave and / or physicochemical methods, in particular, injection of alkali solutions and polymers into the formation.

To change the direction of filtration flows, it is most rational to adjust the density of the grid of wells and the development system, organize new foci of waterflooding, drill additional wells and sidetracks, while establishing the relationship of production and injection wells with respect to the direction of fracture in the development elements, which ensures oil displacement, which is predominantly perpendicular to the propagation of cracks , in particular in the in-line element of the development of injection wells, including the horizon flax and sidetracks, positioned along the line of fracture direction, and mining, including horizontal wells and sidetracks - parallel to this line.

When registering seismic-acoustic emission over the area of a deposit, it is advisable to identify the subvertical con- and / or post-sedimentation zones of crack formation formed by the ring-shaped structures, penetrating from the depths of the crystalline basement into the reservoir of the oil and gas reservoir, and to initiate additional crack formation in them.

To obtain important information about the processes occurring in the sources and drains of the filtration fields of the field, it is advisable to additionally register seismoacoustic emission over the field’s area to record seismoacoustic emission in the near-wellbore zone of the reservoir and analyze its signals in real time, for example, by means of identification and research using time series of nonlinear dynamical systems for assessing the metastability of the stress-strain state and fractured the mountain environment of local sections of the near-wellbore space of the reservoir.

At the same time, the registration of seismic-acoustic emission in the near-wellbore zones of a productive formation and the analysis of its signals in real time can be used for express monitoring of various technological processes when it affects a bottom-hole zone and a formation from wells, for example, hydraulic fracturing operations, vibration microwave exposure in combination with depressions and repressions.

In the process of drilling wells, especially in areas of increased fracturing and tension, to ensure high quality and eliminate possible accidents, such as drill pipe emissions, it is advisable to simultaneously record and fractal analysis of acoustic emission signals and / or electromagnetic emission signals coming from the drilled medium, on the basis of which to monitor the drilling process and assign its operational operations, in particular the replacement of drilling tools or regulation to the drilling mud.

Based on the aggregate changes in seismic-acoustic emission over the area in different zones of the field, it is possible to establish the distribution of oil and water saturation in the reservoirs.

When implementing the method, it is rational to initiate and intensify additional crack formation in weakly drained and stagnant zones by stimulating the formations with physical radiation with excitation and propagation of waves of elastic vibrations and / or pulsed wave packets of elastic vibrations and / or electromagnetic waves and / or pulses in the geological environment.

At the same time, in order to reduce energy consumption and maximize the effects of the volume of the deposit, it is optimal to constantly influence the formations with physical radiation continuously or periodically, during periods of time associated with the action of global geoplanetary factors on the geological environment, for example, with the action of lunar-solar tides and pulsations of the Earth’s core .

It is rational to carry out the impact on the reservoirs with physical radiation with the excitation and propagation of waves of elastic vibrations and / or pulsed wave packets of elastic vibrations in the geological environment simultaneously or alternately from the wells and from the surface of the reservoir.

When exposed to physical radiation with the excitation and propagation in the geological environment of waves of elastic waves and / or pulsed wave packets of elastic waves to formations from wells in them, it is advisable to simultaneously carry out a set of technical measures to eliminate the skin effect and increase the hydrodynamic connection with the formation, for example zones in combination with cycles of repression and depression on the reservoir and physico-chemical effects.

When exposed to strata by physical radiation, with the excitation and propagation of waves of elastic waves and / or pulsed wave packets of elastic waves in the geological environment, it is optimal to choose the dominant frequencies of excitation in the geological medium of waves of elastic waves and / or the repetition rate of pulse wave packets in the range of 20-500 Hz

To achieve high efficiency with minimal energy costs, it is optimal to effect physical radiation on formations with excitation and propagation of waves of elastic vibrations and / or pulsed wave packets of elastic vibrations in a geological environment with vibrational acceleration and vibrational displacement parameters exceeding, respectively, 0.1-0, 5 m / s ² and 0.1-1.0 microns.

The dominant frequencies of excitation in the geological environment of waves of elastic vibrations and / or the repetition rate of pulsed wave packets can be determined based on the analysis of the recorded signals of seismic acoustic emission, for example by narrow-band filtering and the allocation of the low-frequency envelope of the noise recording.

When implementing the method, it is advisable to pump displacing agents into injection wells in combination with exposure to bottom-hole zones and formations by physical and / or physico-chemical methods with the injection of agents and reagents required in accordance with the geological and physical conditions of destination.

When registering the seismic-acoustic emission field over the area of the deposit and establishing foci of seismic-acoustic activity, it is advisable to process seismic information in real time and use the focusing transformation of the seismic wave field.

To register the seismic acoustic emission field by area and establish foci of seismic acoustic activity, it is advisable to use at least two reception apertures spaced at least 2000 m apart, and the aperture size should be determined by the formula:

where D is the diameter, λ is the wavelength, λ = V · T, where V is the speed, T is the period, L is the distance from the center of the aperture to the farthest point of view, and the number of reception channels in each aperture should be at least 100.

When processing seismic information and using the focusing transform of the seismic wave field, it is optimal to focus to the grid points of the studied area to the depth of the target horizon, with the choice of cell size:

and the processing results should be presented in real time in the form of a 4-dimensional field of the distribution of seismic emission sources in the studied volume of the geomedium.

When implementing the method, in addition to registering the seismic-acoustic emission field over the area of the field, it is advisable to use the method of side seismic survey of wells (SLBO) to establish the distribution of fracturing in individual zones by the volume of the reservoir.

Also, when implementing the method, in addition to registering the seismic-acoustic emission field over the area of the deposit, it is possible to use high-resolution methods for processing aerospace images to determine the distribution of fracturing in each productive formation.

The above distinguishing features of the proposed method from the prototype determine the emergence of a new quality of oil field development associated with the creation of continuous energy-information interaction in feedback mode with the geological environment of the reservoir during oil displacement under the influence of various internal factors and external influences, with optimal consideration of the structural features of the geological environment, that provides the claimed method to obtain a new technical result set forth in ache invention.

The proposed method does not follow from the existing level of technology, and its distinguishing features differ from the essential features of known methods for developing oil fields.

The essence of the invention is as follows.

The most important fluidodynamic processes at all stages of oilfield development are largely determined by changes in the geodynamic parameters of the mountain environment: stress-strain state, micro- and macrocracking, dilatancy, etc. Thus, the nature of the development of fluidodynamic processes in terms of area and volume of deposits can be estimated from one of the indicated geodynamic parameters. Fracturing is chosen as this parameter - the main information parameter characterizing the filtration properties of rocks. Geodynamic processes affect fluid dynamics, mainly through a change in fracturing, determining the filtration characteristics of the reservoir and forming the main direction of formation fluid flows.

The informative parameters of the processes associated with the occurrence and collapse of open cracks, changes in their shape, size, etc., are signals of seismic acoustic emission (SAE). At the same time, seismic waves that spontaneously arise during the SAE process can be detected using standard hardware, and special transformations used for digital processing, for example, focusing transformation (FP) of a seismic wave field, can be used to localize the foci of the SAE in the studied volume of the geomedium.

The geological interpretation of the foci of the SAE consists in their identification not only with areas of the geological environment where open fracture has changed - the occurrence and collapse of cracks, their growth and change in shape, direction, etc., but also with areas of the medium with an increased modulus of the stress gradient, where the increased emission of SAE is due to the metastable stage of accumulation of microcracks without the formation of open cracks of increased permeability. The dynamics of the distribution of SAE foci over the area of the field allows you to control not only important fluid dynamic development processes, for example, the advance of the front of oil displacement by water, the change in the direction of fluid flows during artificial flooding, the formation of stagnant (slightly drained) zones, but also various processes of the influence of external natural factors (Lunar and Solar gravitational tides - ebbs, oscillations of the poles of the Earth, earthquakes), and artificial influences - non-stationary hydrodynamic, vibroseis nical impacts of hydraulic fracturing, etc.

According to the invention, seismic acoustic emission is preliminarily recorded over the area of the deposit, on the basis of which foci of seismic acoustic activity and the distribution of fracturing in each reservoir are established. This information, together with the available oilfield information, allows you to identify the boundaries of the zones of changes in the fluid saturation of the reservoir environment, the areas of deposits with still undeveloped reserves, to determine the metastable screens that impede oil displacement - local areas of increased mechanical stress due to the lithology of the block structure of the reservoirs or that have arisen in the development processes, as well as allows you to select the necessary measures for changing development modes and assigning impact methods targeting the target zones of the field.

During the development process, seismic-acoustic emission is recorded over the area and real-time information processing results are used to track the occurring changes in the distribution and intensity of weakly drained, stagnant and washed zones, while in order to ensure progressive dynamics of useful changes, the directions of the filtration flows are changed in the target areas, initiating and intensifying with using other methods of influencing the reservoir environment, additional crack formation in the desired zones, achieving reduction I and the elimination of undeveloped areas and generally improve oil recovery. At the same time, the controlling factor showing the achievement in real time of the required impact result is the development of the level of SAE noise (amplitude, spectral and fractal) in the treated zone, corresponding to the level of noise of the SAE for developed open crack formation along the main displacement vector. Thus, when implementing the method during development, the process of oil displacement is continuously monitored and regulated to achieve a potentially achievable oil recovery coefficient.

Changing the direction of filtration flows is not only the most important hydrodynamic factor in the formation of zones with a low and zero oil filtration rate, but also contributes to the initiation and intensification of crack formation under the influence of changes in stress gradients resulting in the formation of open cracks in metastable screens of stagnant zones. To enhance and maximize the development of cracking processes, formations are exposed to physical radiation of artificial and / or natural nature, which can be caused by excitation from the surface of the field or from the bottom of the wells, for example, elastic and / or electromagnetic waves and / or pulsed wave packets, with the development of dilatation wave phenomena in the near-wellbore zones and reservoirs. Reaching the impact zone even at relatively low intensity levels, these radiations produce perturbations of mechanical stresses that exert a trigger effect on the stressed geological formation medium, which causes a combination of mutually contributing processes: enlargement and coalescence of microcracks, strengthening and changing the nature of SAEs, formation of fractures open for filtering, and decomposition of metastable screen of the stagnant zone with relaxation of increased stresses in it.

In addition, when the layers are exposed to physical radiation, for example, elastic vibrations in an oil-saturated porous medium, a number of useful filtering effects arise, in particular, the dispersed, stationary under normal conditions, residual oil is mobilized and involved in the filtration flows through the formation.

To ensure maximum depth and effectiveness of the impact on the formations, the dominant excitation frequencies in the geological environment of waves of elastic vibrations and / or the repetition rate of pulsed wave packets in the range of 20-500 Hz are chosen. The existence of dominant low excitation frequencies is explained by the features of physical processes during the occurrence and propagation of acoustic emission.

The reaction energy of the medium by SAE can exceed the energy of the trigger action on the medium by 10 ² -10 ³ times, and the geophysical medium is seismically active in complete analogy with optically active media. A separate high-frequency pulse (short-wave packet) of acoustic emission is the result of microdestruction of the medium element, and the SAE comes from the evolution of acoustic emission pulses along the entire propagation path - nonlinear summation and interaction of elementary disturbances of the medium over a seismically active medium. Interaction with the active medium and energizing shifts the maximum of the spectral distribution of the intensity of the reaction of the medium to low frequencies - there is a low-frequency modulation of the noise signal of the SAE. Modulation frequencies - dominant frequencies can be determined, in particular, by narrow-band filtering and the allocation of the envelope of the noise recording of the SAE. When elastic waves of dominant frequencies propagate through the geological environment, the trigger effect is maximally manifested and the maximum exposure range is reached.

Due to the noticeable effect on the amplitude and nature of the SAE of the above effects by physical radiation, as well as many other external factors, for example, changes in reservoir pressure during pumping-pumping of liquids and gases or changes in temperature, the recording of seismic acoustic emission over the field’s area can also be effectively performed in the passive mode of natural background , and in the mode of the response of the medium induced by external influence, which not only exhibits the internal state of the area zone according to the methods studied Parameters of the formation, but also testifies to the effective conduct of external influence.

The response of the geological environment to external influences (the intensity and nature of the induced SAE) shows a significant dependence of trigger effects on the saturation of the geological formation medium that we have found, which allows the proposed method to register SAE by the area of the field, using noise signal processing, for example, spectral analysis, Wavelet and fractal analyzes, based on the aggregate changes in the SAE by area in different zones of the field to establish the distribution of oil and odonasyschennosti in layers.

When registering seismic acoustic emission over the area of the deposit according to the nature of the distribution of the foci of the SAE over the depth of the reservoir volume, under certain conditions it is possible to identify the subvertical con- and / or post-sedimentation zones of fracture formed by the ring-like structures, penetrating from the depths of the crystalline basement into the reservoir of the oil and gas reservoir. These zones can be associated with additional inflows of mantle oil into the reservoir layers, which are blocked by metastable "screens" of compacted rocks. With the targeted initiation of additional fracturing in them, the reservoir is “fed” and additional oil is obtained from them during development.

For the optimal organization of changes in the filtration flows and the application of reservoir stimulation methods, information on the state of the areas of sources and drains of the filtration fields of the field — near-well zones of productive layers — is important. For this, additional registration of SAE in these zones is provided, its processing by identification methods, studies of nonlinear dynamic systems and continuous graphical representation of real-time results that show the current stress-strain state of local near-well sections of the reservoir. These operations can also be used for express monitoring of various technological processes when impacting the bottom-hole zone (PZP) and the formation from the wells, as well as when monitoring the processes of drilling wells. For example, during hydraulic fracturing, it is possible to determine the most favorable time points for turning on the maximum power of the fracturing fluid, diagnose the depth of developing cracks and evaluate the asymmetry and the preferred direction of their development.

The method is as follows.

Preparatory work is being carried out on the oil field or on the selected separate site for the registration of the SAE by area: reconnaissance of the area to select the optimal location of the seismic locator reception system, installation of the seismic wave packet reception and registration system (SVP) with topographic location of reception points on the ground, experimental work on the selection of optimal conditions for the reception and registration of seismic waves (from internal points of the geological environment), determination the optimal aperture sizes of the seismic locator, determining the optimal parameters for grouping geophones at the reception point, as well as filtering and amplification during registration, carrying out experimental work to determine corrective static corrections to the reception points.

At the first stage, the SAE is recorded by area and the incoming seismic information is processed to identify foci of seismic activity and to map the distribution of fracturing.

Using the obtained data, as well as using the available oilfield information, determine the target areas for further operations by the method. In fields under development, poorly drained, stagnant and washed zones are determined. Assign a set of measures to implement a change in the direction of filtration flows in the target zones and apply methods of external stimulation of the reservoir - select wells for impact and / or locations for surface vibration sources to excite elastic waves.

If necessary, drill additional wells.

The signals obtained over the area of the signals are processed by the natural or induced by the external influence of the SAE geological environment of the strata and the dominant frequencies of excitation of elastic waves to influence the strata are determined. In selected wells, if necessary, field and geophysical studies, core studies are carried out.

Equip a plot of oil deposits to implement the method. Underground equipment is installed in the wells - downhole generators or pulse devices. In operating injection wells, special automated valves are mounted at the mouth, hydrodynamic or gas-dynamic generators of elastic vibrations, electrodynamic pulse generators or other generating devices are installed on the descent tubing. In producing wells, pulse devices are installed that use the energy of deep pumps, such as sucker rods, or powerful pulse electrodynamic devices that are fed by cable from the wellhead. If necessary, mobile vibroseismic platforms, vibration hammers that transmit energy towards the object through anchor wells buried beneath loose surface soils, MHD generators of electromagnetic pulses or other sources of excitation of physical radiation and waves are placed at selected points on the surface.

At the second stage, the directions of the filtration flows are changed, additional crack formation in weakly drained and stagnant zones is initiated and intensified, at the same time, the SAE is registered over the deposit area with the processing of incoming seismic information in real time, revealing continuously occurring changes in the distribution of seismic activity and fracture foci, while using also current oilfield information, such as isobar and water cut maps. According to the observed changes, optimal development control is carried out using a set of operations for changing the direction of the filtration flows and external influences on the reservoirs - they adjust the parameters of cyclic unsteady waterflooding according to the choice of wells and the regime, change the modes of exposure to physical radiation and change the wells and their excitation points, prescribe the use of physicochemical method with the choice of agents and reagents.

The level of changes in the EPS is monitored, and when the target reaches the level of the EPS, corresponding to the level of the main displacement vector on the area of the field or site, the development process is continued until the required oil recovery indicators are achieved.

As a result of ongoing operations with the organization of continuous energy-information interaction in the feedback mode with the geological environment in the reservoirs, the oil displacement regime is optimal in terms of the distribution of filtration fields and reservoir coverage, with the prevention and elimination of the formation of weakly drained sections and stagnant zones. In addition, when elastic waves are applied to formations, the dispersed residual oil, which is motionless under normal conditions, is mobilized and involved in the filtration flows through the formation. In wells associated with these zones and in the field as a whole, an increased influx of additional oil is initiated with an increase in the oil recovery coefficient.

An example implementation of the method.

We give an example of the method in two areas of the field with hard to recover reserves.

For these sites, independent development targets are sandstone strata of the Lower Carboniferous clastic layer (TTNK) - II, IVo, IV, V, VIo ^1-2 , VIo ³ , VI and Middle Carbonate carbonates of the Kashira, Verey horizons and Bashkir tiers. The main object in terms of productivity and reserves is TTNK. The average oil-saturated thickness of the layers is 0.8-2.2 m; porosity - 0.18-0.24; permeability from 0.09 μm ² to 1.34 μm ² (reservoir VI). The density of oil in reservoir conditions is 887.0-910.0 kg / m ³ , viscosity 13-34 mPa · s, saturation pressure 7.0 MPa, depth to the top of formations 1250-1300 m. Porous-fractured limestones are oil-bearing in the Kashirian horizon and dolomites with a thickness of up to 4.4 m, porosity of 14%, permeability of 0.01 μm ² . In the Bashkir layer, oil-saturated porous interlayers with a total thickness of 10.5 m and a porosity of 0-13%, average permeability of 0.05 μm ² . In limestones of the Verey horizon, porosity is 11-15%, permeability is 0.06 μm ² .

The water content of the products for TTNK is 92%, for average carbon - 70%.

In the first section of the Bashkirian Middle Carboniferous field selected for the method, work was carried out to select the optimal location of the areal seismic locator receiving system with its apertures, to install and configure the areal reception system for recording and processing the resulting seismic wave packets of the SAE using the passive seismic focal technique of Emissions (SLEE) of the Institute of New Oil and Gas Technologies of the Russian Academy of Natural Sciences (INNT) using a focused seismic wave transform lei. Further, according to the results of field registration of the SAE in combination with development indicators (water cut of wells, reservoir pressure, etc.), the distribution of fractures was obtained at the beginning of the work, the diagnosis of stagnant zones and the contour of the water cut of 50% (weight), poorly drained zones were outlined, of which the most significant in size is located in the area of producing wells (wells) No. 2574 and No. 2674. On figa shows the location of the focus of the injection wells with the distribution of weakly drained zones and fracturing in the reservoir, obtained at the beginning of the application of the method.

To intensify the development of weakly drained zones by the method, a set of works was carried out to change the direction of filtration flows and stimulate the formation with elastic vibrations to initiate and intensify additional fracturing using hydrodynamic generators of the STRENTER complex and UNIS units of the Oil Engineering Scientific and Production Enterprise. In injection wells. No. 2576, 2508, and No. 2675, after conducting VHF treatments to clean the bottomhole section using GD2V-4 hydrodynamic generators, GD2V-Sh generators for continuous operation of GD2V-Sh, working from the pressure of cluster pumping stations (KNS), were installed on the tubing pipes. No. 2574, 4918 and No. 2674 were installed pulse UNIS installations, working in conjunction with sucker rod pumps. To change the direction of the filtration flows, cyclic (unsteady) flooding was applied during periodic operation of injection wells. No. 2508, 2572, 2576, 2676 and production well. No. 2509. During the periodic operation of these wells, simultaneously with the impact on the formation with the generation of elastic waves and pulses, current registration of the SAE by the area of the site and assessment of changes in the distribution of fracturing were carried out, as well as oilfield information on reservoir pressure and water cut was evaluated.

By monitoring the result of the impact, the development in the treated zones of the level of SAE (by complex amplitude, spectral and fractal analysis) was achieved, corresponding to the recorded level in the direction from the well. No. 2676 to the well. No. 2678, where the main displacement vector is implemented.

On figb shows a diagram of the focus of the injection wells with the distribution of weakly drained zones and fracturing in the reservoir, obtained after six months after the start of work according to the method.

Figure 2 shows the characteristic of Pirverdyan in producing wells. No. 2574, 2676, illustrating the increase in additional oil production. As a result of producing wells. No. 2574 and No. 2674 additionally produced 3,521 tons of oil while reducing the volume of liquid production. On the whole, 3680 tons of oil were additionally produced in the allocated area over this period.

In the second selected section of the Lower Carboniferous Terrigenous Stratum (TTNK) field, a series of preparatory work was carried out similar to that described for the first section, and the area was recorded using seismic locators using the SLEE technique. According to the results of the seismic-acoustic location of the emission zones with the identification of fracture zones, together with the well development indicators, the presence of stagnant zones and a water cut isoline of 50% were verified, weakly drained zones formed by insufficient exposure to injection wells were outlined. No. 1413. On figa shows a location diagram of the wells of the site with the distribution of weakly drained zones and fractures in the reservoir at the beginning of the application of the method. If there is only one injection well in the area, it is proposed to organize an additional injection center for a complete change in the filtration in the volume of the formation and initiation of fracturing. To clarify the distribution of fracturing, side view seismic location measures were carried out near the well. No. 2759. As a result of SLE. No. 2759 was assigned for transfer under injection with simultaneous measures to excite elastic waves from a given well and to excite elastic waves and pulses from producing wells. No. 4260, 4245 and No. 4261. To implement the method in SLE. No. 2759 was developed for injection using a complex vibrating microwave effect on the BFZ using the hydrodynamic generators GD2V-3 and the jet pump IS-3 of the STRENTER complex. Prior to the development of this well and in the course of its implementation, registration of seismic-acoustic emission in the well formation layer was carried out. No. 2759 using a well string as a sound channel simultaneously with real-time spectrofractal analysis of its signals using a software-measuring complex based on a laptop computer. This express analysis made it possible to make operational amendments to the regimes and operations of exposure during processing of the bottomhole formation zone and showed the achievement of positive changes in the stress-strain state, fracture and saturation of the mountain environment of the near-well borehole space. No. 2759. Then, a hydrodynamic generator was installed in this well for the continuous operation of the GDV2-Sh, and water was pumped into this well. In well No. 4260, 4245 and No. 4261, UNIS installations were installed and, simultaneously with the operation of sucker rod pumps, the formation was stimulated with the excitation of elastic impulses. During water injection and impact from wells, changes in the distribution of foci of the SAE and fracture were monitored.

By monitoring the result of exposure, the development in the treated areas of the level of SAE (by complex amplitude, spectral and fractal analysis) was achieved, corresponding to the previously recorded level in the direction from the well. No. 1413 to the well. No. 2759, where the main displacement vector was implemented.

On figb shows the location of the wells with a change in weakly drained zones and the development of additional fracturing six months after the start of the impact. Figure 4 shows the characteristic of Pirverdyan, showing the increase in additional oil along the source of injection wells. No. 1413 and No. 2579. The measures carried out according to the method made it possible to additionally produce over 1033 tons of oil within 6 months by optimizing the development.

The use of the invention in complicated operating conditions of fields allows to increase the current oil production from 20 to 30%, to increase the final oil recovery by 7-20% while reducing capital costs and material resources by 20-40%.

Claims (23)

1. A method of developing an oil field, including geophysical studies of the structure of the reservoirs and well surveys, drilling production and injection wells, oil production from production wells, injection of displacing agents into injection wells and the use of methods of influencing productive formations, characterized in that they are pre-recorded by area seismic-acoustic emission fields, on the basis of which the foci of seismic-acoustic activity and the distribution of fracturing for each to the reservoir, and during the development process, seismic-acoustic emission is recorded by area and in real time by the combination of seismic-acoustic emission and field development indicators, in particular isobar maps and water cuts of the wells, weakly drained, stagnant and washed zones are determined, the directions of the filtration flows are changed, initiate and intensify additional crack formation in weakly drained and stagnant zones to the level of recorded noise corresponding to the noise level in the main vector displacement. 2. The method according to claim 1, characterized in that the additional cracking in weakly drained and stagnant zones is initiated and intensified by exposure to the layers with physical radiation of an artificial and / or natural nature. 3. The method according to claim 1, characterized in that the registration of seismic acoustic emission over the area of the field is carried out in the natural background mode and / or in the mode induced by external influence of the response of the medium. 4. The method according to claim 1, characterized in that the directions of the filtration flows are changed using hydrodynamic methods, in particular cyclic water flooding, drilling additional wells and / or physical methods, in particular wave methods, and / or physicochemical methods, in particular injection into the reservoir of alkali solutions, polymers. 5. The method according to claim 1 or 4, characterized in that in order to change the direction of the filtration flows, the density of the well network and the development system are adjusted, new foci of water flooding are organized, additional wells and sidetracks are drilled, and production and injection wells are relative to the fracture direction in the elements of development, which provides mainly oil displacement, perpendicular to crack propagation, in particular in the in-line element of development, injection wells, including horizontal, sidetracks are located along the direction of fracture, and production, including horizontal wells and sidetracks, are parallel to this line. 6. The method according to claim 3, characterized in that when registering the seismic acoustic emission over the area of the deposit, subvertical con- and / or post-sedimentation zones of crack formation formed by the ring-shaped structures penetrate from the depths of the crystalline basement into the reservoir of the oil and gas reservoir and initiate additional crack formation in them. 7. The method according to claim 3, characterized in that in addition to registering seismic acoustic emission over the field’s area, seismic acoustic emission is recorded in the near-wellbore zone of the producing formation and its signals are analyzed in real time, for example, by identification and time-series studies of nonlinear dynamic systems, to assess the metastability, stress-strain state and fracture of the mountain environment of local sections of the near-wellbore space of the reservoir. 8. The method according to claim 7, characterized in that the registration of seismic acoustic emission in the near-wellbore zones of the reservoir and the analysis of its signals in real time are used for express monitoring of various technological processes when exposed to the bottom-hole zone and the reservoir from wells, for example, fracturing operations, microwave exposure in combination with depression and repression. 9. The method according to claim 4, characterized in that in the process of drilling wells simultaneously record and fractal analysis of acoustic emission signals and / or electromagnetic emission signals received from the drilling medium, based on which the drilling process is monitored and its operational operations are assigned, in in particular, replacing drilling tools or adjusting mud characteristics. 10. The method according to claim 1, characterized in that the aggregate changes in seismic acoustic emission over the area in different zones of the field establish the distribution of oil and water saturation in the reservoirs. 11. The method according to claim 2, characterized in that the additional cracking in weakly drained and stagnant zones is initiated and intensified by the action of physical radiation on the reservoirs with excitation and propagation of waves of elastic vibrations and / or pulsed wave packets of elastic vibrations and / or electromagnetic waves, and / or pulses. 12. The method according to claim 2, characterized in that the effect on the formations by physical radiation is carried out continuously or periodically in periods of time associated with the action on the geological environment of global geoplanetary factors, for example, with the action of the Lunar-Solar tides. 13. The method according to claim 11, characterized in that the effect on the reservoirs of physical radiation with the excitation and propagation in the geological environment of waves of elastic waves and / or pulsed wave packets of elastic waves is carried out simultaneously or alternately from wells and from the surface of the reservoir. 14. The method according to item 13, characterized in that when exposed to physical radiation with the excitation and propagation in the geological environment of waves of elastic waves and / or pulsed wave packets of elastic waves to formations from wells, they simultaneously carry out a set of technical measures to eliminate the skin effect and increasing the hydrodynamic connection with the formation, for example, vibrating microwave treatment of the bottom-hole zone in combination with repression and depression cycles on the formation and physicochemical effects. 15. The method according to claim 11, characterized in that when the layers are exposed to physical radiation with excitation and propagation of waves of elastic vibrations and / or pulsed wave packets of elastic vibrations in the geological environment, the dominant excitation frequencies in the geological environment of waves of elastic vibrations and / or frequencies are selected following pulsed wave packets in the range of 20-500 Hz. 16. The method according to claim 11, characterized in that the effect on the reservoirs of physical radiation with the excitation and propagation in the geological environment of waves of elastic vibrations and / or pulsed wave packets of elastic vibrations is carried out with parameters of vibrational acceleration and vibrational displacement exceeding, respectively, 0.1 -0.5 m / s and 0.1-1.0 microns. 17. The method according to p. 15, characterized in that the dominant frequency of excitation in the geological environment of waves of elastic waves and / or the repetition rate of pulsed wave packets is determined based on the analysis of the recorded signals of seismic acoustic emission, for example by narrow-band filtering and the allocation of the low-frequency envelope of the noise recording. 18. The method according to claim 1, characterized in that the injection of displacing agents into the injection wells is carried out in combination with exposure to the bottom zones and formations by physical and / or physico-chemical methods with the injection of agents and reagents required in accordance with the geological and physical conditions of the appointment . 19. The method according to claim 3, characterized in that when registering the seismic acoustic emission field over the area of the field and establishing foci of seismic acoustic activity, they process real-time seismic information and use focusing conversion of the seismic wave field. 20. The method according to claim 1, characterized in that at least two reception apertures spaced from each other at a distance of at least 2000 m are used to register seismic-acoustic emission fields over the area of the field and establish foci of seismic-acoustic activity, while the size of the aperture is determined by the formula:

where D is the diameter; λ is the wavelength λ = V where V is the speed; T is the period; L is the distance from the center of the aperture to the farthest point of view, and the number of reception channels in each aperture is selected at least 100. 21. The method according to claim 19, characterized in that when processing seismic information and using the focusing conversion of the seismic wave field, focusing is carried out at the grid points of the investigated area to the depth of the target horizon, with the choice of cell size:

and the processing results are presented in real time in the form of a 4-dimensional field of the distribution of seismic emission sources in the studied volume of the geomedium. 22. The method according to claim 1, characterized in that, in addition to registering the seismic acoustic emission field over the area of the field, to establish the distribution of fracturing in separate zones over the reservoir volume, the method of seismic lateral viewing of wells is used. 23. The method according to claim 1, characterized in that in addition to registering the seismic-acoustic emission field over the area of the deposit, methods for processing high-resolution aerospace images are used to establish the distribution of fracturing in each productive formation.

Images