RU2291954C2 - Method for extracting hydrocarbon deposits including complex physical bed stimulation - Google Patents

Abstract

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

SUBSTANCE: method includes forcing displacement agents into force wells and extraction of bed fluid through product wells, research of natural fissuring of geological environment of bed, initiation and creation of additional channels for transfer of mass into wells. In accordance to invention during research of natural fissuring, zones of heightened fissuring and heightened strain of bed environment are detected across the area of deposit. in aforementioned zones or close to these product wells are selected and additional wells are drilled. Created and initiated are wave channels for energy-mass transfer on productive intervals of given wells in beds by means of successive feeding of physical energy impulses into bed. Performed simultaneously is recording of acoustic emission and/or electromagnetic emission signals received from bed, their fractal analysis, construction of volumetric attractors of condition of structure of geological environment in real time mode with continuous computer monitoring of strain, fluid saturation, fluid pressure, change of condition of formation and development of channels of energy-mass transfer in bed by groups of wells. On basis of monitoring of phase of maximal local instability of formation condition, moment of injection of each following impulse is assigned and its energy and frequency parameters are altered until receipt of response from environment.

EFFECT: increased efficiency of extraction due to purposeful selection of wells and realization of direct monitoring and operative control over parameters of processing, and also decreased energy costs and expanded functional capabilities of method.

19 cl, 1 ex, 1 dwg

Description

The invention relates to the oil industry and is intended for oil production, especially in the late stages of development of irrigated deposits with complicated conditions of poorly drained, low permeability and heterogeneous reservoirs.

Known methods for the development of oil fields in which to create additional mass transfer channels from the reservoir to the wells use hydraulic fracturing (hydraulic fracturing) (Nekrasov V.I., Glebov A.V., Shirgazin R.G., Vakhrushev V.V. Hydraulic fracturing: introduction and results, problems and solutions. - Ufa: State Unitary Enterprise Research Center for Scientific Research, Belaya Reka, 2001. - 237 pp., Ekonomidis Mikoel J., Holte Kenneth T. Impact on oil and gas strata (translated from English) ./ Edited by A.I. Bulatov - Krasnodar: VNIIKRneft, 1992. - Vol. 1. - 538 pp., RF Patent No. 2066746, IPC E 21 B 43/26, 33/13, published in BI No. 26, September 20 .96). These methods are a method of restoring and increasing well productivity, however, they do not fully reveal the potential of the procedure for creating reservoir communication channels with wells. During the application of these methods, the main result of technological operations of exposure remains unknown - the characteristics of the created additional channels-cracks in the wells. The process of development of the fracture channels during injection and after the termination of fluid injection remains hidden for the operator-technologist. Monitoring the process is carried out only by indirect signs that can be directly determined during processing, for example, by the dynamics of pressure changes at the wellhead, but in real conditions of treatment it is almost impossible to isolate the dynamics of pressure changes in the fracture from full pressure maps. The only method for interpreting the complex of parameters of well treatment using hydraulic fracturing in known methods is mathematical modeling of the process of development of fractures using very complex and expensive programs that require a lot of calculation time, long and not always achieved adaptation to the real geological and physical conditions of a particular reservoir. For modeling, large amounts of initial information are required, in particular, data on the filtration-capacitive and mechanical properties of rocks in the object. And if such data as permeability, porosity, etc. coefficients are sufficiently fully presented for oil deposits, then the elastic and strength properties of the rocks, requiring unconventional and complex research methods, almost everywhere do not have a representative volume for the deposits and differ in a significant range of values even within one lithotype. The use of correlation dependencies between elastic-strength and reservoir parameters gives significant errors in the estimates of mechanical parameters. All this greatly reduces the reliability of modeling and the efficiency of hydraulic fracturing control in these methods.

In addition, in these methods, a long and laborious procedure of mathematical modeling is carried out long before hydraulic fracturing is carried out in wells, its effectiveness is evaluated every time after the treatments themselves by coincidence of changes in the calculated and observed indirect values (for example, by changing the injection pressure), application of the methods It does not provide reliable recommendations for increasing the expected effect due to the optimal assignment of regime technological parameters of the hydraulic fracturing process.

All this greatly reduces the reliability of design, management and the effectiveness of these development methods.

Closest to the proposed invention is a method of developing an oil field, which involves drilling wells, injecting displacing agents into injection wells and selecting reservoir fluid through production wells, investigating the direction of natural fracturing of the geological environment of the formation, initiating directions and creating fractures (additional mass transfer channels) in the wells . (RF patent No. 20033789, IPC E 21 B 43/26, published in BI No. 43-44, 11/30/93). The known method allows under favorable conditions for the direction of natural fracturing of the geological environment and the possibility of initiation to produce sufficient deviations in the direction of propagation of artificial fractures from this direction to create a hydrodynamic connection between the individual wells of the reservoir, but its overall effectiveness in terms of the effect on the formation, on the intensification of the development of reserves, on the achievement of the inflow additional oil through the filtration fields of the reservoir to the wells, to increase the coverage of the reservoir is low, especially for slabodreniruemyh portions, low permeability, structurally heterogeneous deposits reservoirs, depleted deposits and watered.

This method provides only an indirect assessment of the direction of natural fracturing in the reservoir, and there are no actions to identify specific areas of increased fracturing, which does not allow for the design of the development to make the optimal choice of candidate wells for effective hydraulic fracturing. Verification of the initiation of cracks and the achievement of sufficient length in this method is carried out after completion of processing for hydrodynamic studies of the interaction of wells, and in this case, due to the lack of specific operations for initiating cracks and in the absence of direct control over their nucleation and propagation, as well as achieving the desired length the method does not eliminate all the above disadvantages of analogues. There is no effective strategy for finding optimal processing modes, and all attempts to create development projects using the method are inevitably associated with the accumulation of large statistical material for real hydraulic fracturing, not only in the fields, but also in their sections with different geological and physical conditions and different arrangement of well pairs relative to the direction natural fracture. In practice, this is difficult to implement and, in addition, it is inevitably associated with large errors in forecasts.

But most importantly, the known method provides only the prerequisites under favorable conditions for increasing the local connection of wells with the formation and does not provide opportunities for productive information and energy interaction of wells with a full volume of the formation, which determines not only local increases in inflows to the wells, but favorable changes in the saturation fields and enhanced oil recovery.

The objective of the invention is to increase the development efficiency with increasing reservoir coverage by exposure, increasing oil production and increasing oil recovery by targeted selection of well objects for processing, direct monitoring and operational management of treatment parameters, as well as creating the most favorable conditions for oil flow to wells after completion of treatments for groups of wells, reducing energy consumption, expanding the functionality of the method.

To solve the problem in a known method, which includes injecting displacing agents into injection wells and selecting formation fluid through production wells, investigating the natural fracture of the geological environment of the formation, initiating and creating additional mass transfer channels into the wells, according to the invention, in the course of studying natural fracturing, the area deposits are identified increased fracturing, tension and / or reveal zones of anomalies of other geological and physical parameters of the reservoir of the medium and in these zones or near them, producing wells are selected or additional ones are drilled, they initiate and create wave channels of energy-mass transfer at the productive intervals of these wells in the formations by sequentially supplying pulses of physical energies to the formation with simultaneous recording of physical radiation coming from the formation and their fractal analysis , the construction of volumetric attractors of the state of the structure of the geological environment in real time and continuous computer monitoring of changes in the status of the reservoir and the development of energy-mass transfer channels in the reservoir according to the groups of wells, on the basis of which the timing of the supply of each subsequent pulse is assigned and its energy and frequency parameters are set.

When implementing the method, the zones of increased fracturing over the area of the deposit in the reservoir are most rationally and with a high degree of reliability to identify by the method of seismic side view of wells (SLBO). This method gives volume telemetric pictures of the real distribution of cracks in the reservoir, in accordance with which the zones of crack accumulation, their configuration, density, location and direction in space are reliably determined.

It is possible to use well pressure pulses and / or electromagnetic and / or thermal pulses as pulses of physical energies when creating wave channels of energy-mass transfer.

When recording and analyzing physical radiation coming from the formation when creating wave channels of energy-mass transfer of physical radiation, it is optimal to record and analyze acoustic emission (AE) signals and / or electromagnetic emission signals coming from the formation.

In order to make rational use of standard oilfield equipment, it is advisable, when implementing the method, to pre-initiate the wave channels of energy-mass transfer at the productive intervals of the selected wells by superimposing the stages of repressive-depressive and reagent stimulation on the formation in combination with simultaneous exposure to elastic vibrations.

For the same purposes and to achieve maximum depth and effectiveness of the impact, it is optimal to effect elastic vibrations on the formation when initiating wave channels of energy-mass transfer in selected wells by borehole hydrodynamic generators with vibrational displacement values exceeding 0.3-1.0 μm and in the frequency range 20-450 Hz.

The reagent effect on the formation when initiating wave channels of energy-mass transfer in the selected wells is optimally carried out by pumping acids and / or oil-acid emulsions into the formation.

In order to provide feedback to the formation when initiating wave channels of energy-mass transfer, it is possible to simultaneously record and fractal analyze acoustic emission signals and / or electromagnetic emission signals from the formation.

When creating wave channels of energy-mass transfer with the sequential supply of pressure pulses into the formation, it is rational to use an oil emulsion as a well fluid.

At the same time, it is technologically rational to prepare an oil-acid emulsion directly at the bottom of the wells by pumping a mixture of acid and oil through a borehole hydrodynamic generator of elastic vibrations.

Since it is planned to drill additional wells near or inside areas with increased fracturing and medium tension, in order 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 coming from the drilled medium and / or electromagnetic emission signals, on the basis of which to monitor the drilling process and assign its operational operations, in particular, replacement of drilling tools or temporary weighting of drilling mud.

In certain geological and physical conditions, in order to expand the functional capabilities of the method, it is advisable, after creating wave channels of energy-mass transfer in the formation, to pump fluids into them - chemicals and / or coolants.

For the same purposes, it is possible, after creating wave channels of energy-mass transfer in the formation, to create an electrically conductive medium in them and to supply electric currents or flows of electromagnetic radiation.

In order to achieve maximum formation coverage and the required duration, it is possible, after creating wave channels of energy-mass transfer at the productive intervals of the selected wells and putting them into operation, simultaneously with the selection of formation fluid, to additionally influence the formation geological environment by disturbances of mechanical stresses.

In this case, it is rational to carry out the impact on the geological environment of the formation with disturbances of mechanical stresses with the excitation and propagation of waves and / or pulses of elastic vibrations and / or electromagnetic waves and / or pulses in the formation.

Impact on the geological environment of the formation by disturbances of mechanical stresses can be carried out by generators of elastic and / or electromagnetic waves and / or pulses from the faces of additionally selected production and / or injection wells.

In order to achieve the most volumetric impact on the formation, it is possible, in addition to acting on the geological environment of the formation, by disturbances of mechanical stresses from the wells, for example, downhole generators, to simultaneously or alternately perform this action also from the surface of the reservoir, for example, surface vibroseismic sources.

From the point of view of achieving high efficiency with minimal energy costs, the influence of disturbances of mechanical stresses on the geological environment of the formation is optimally carried out with parameters of vibrational acceleration and vibrational displacement exceeding, respectively, 0.1-0.5 m / s ² and 0.1-1.0 microns.

In order to reduce energy costs and maximize the effects of the volume of the reservoir, it is advisable to conduct impact on the geological environment of the formation with perturbations of mechanical stresses constantly 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 tides.

In order to maintain a high level of activity of the formation environment and expand the functional capabilities of the method, it is advisable to cyclically change the formation pressure in addition to acting on the geological environment of the formation by disturbances of mechanical stresses simultaneously with the selection of formation fluid in the formation.

For optimal production of oil reserves in the reservoir, it is advisable, in addition to acting on the geological environment of the formation, by disturbances of mechanical stresses after creating wave channels of energy-mass transfer at the selected wells and putting them into operation simultaneously with the selection of the reservoir fluid from the reservoir, cyclically disconnect and / or connect groups of wells to the work and initiate a change in the direction of the filtration flows in the reservoir.

The above distinguishing features of the proposed method from the prototype determine the emergence of a new quality of impact associated with the creation of continuous energy-information interaction in feedback mode with the geological environment of the formation during the action from the wells with optimal consideration of the structural features of the geological environment, which determines the maximum coverage of the formation in depth and strike with directional changes in stress fields, pore pressures, filtration fields and saturations in the reservoir x. At the same time, the process of developing an oil deposit proceeds under conditions of qualitatively new positive changes in the phase permeabilities of oil and water in the formations, a sharp intensification of capillary impregnation, a significant increase in the coverage coefficient of formations by oil displacement, in addition, the additional fracturing fields not only provide an increase in oil inflows to the wells and increase oil recovery, as well as in certain geological and physical conditions and replenishment of oil reserves in the reservoir.

The essence of the invention is as follows.

According to the invention, the geological environment of the formation is preliminarily studied in the reservoir and zones of increased fracturing, tension, and also zones of other anomalies of geological and physical parameters of the saturated porous formation environment are identified. At the late stages of development, in conditions of poorly drained, low permeability, and heterogeneous reservoirs, these zones are associated with changes in the saturation of the reservoir environment and indicate areas of the reservoir with still undeveloped reserves. The filtration flow of oil into wells within these zones is prevented by the presence of metastable screens - both natural, due to the lithology of the block formation structure, and areas with local increases in mechanical stresses that occur in the development processes with local changes in the reservoir pressure, as well as under the influence of other external technogenic and natural factors. In addition, zones of increased fracturing, as well as other zones of anomalies of geological and physical parameters, can be associated with unrealized or weakly functioning currently inflows of mantle oil from the depths of the crystalline basement to the reservoir, which are also clogged by certain metastable screens. In practice, these zones can be determined by seismicolocation of the side view of wells (SLBO). They can also be identified by high-resolution processing of aerospace images by the anomalies of the geophysical fields of the oil reservoir, for example gravitational or magnetic, the radonometry of the reservoir area or by the changes in the radioactivity of the produced fluids. With certain assumptions, it is also possible to determine these zones by field indicators of the history of reservoir development. Within these zones, existing wells are identified or new ones are drilled to conduct a comprehensive impact on the formation. The essence of the complex effect is the destruction of metastable screens that impede the flow of additional oil to the wells, the increase in mobile reserves and the possible replenishment of the total oil reserves in the deposits by creating energy-mass transfer wave channels penetrating the formation.

The structure of geological media is fractal in nature, and their real state is described by the definition of nonlinear dynamic systems. Various processes in geological environments cause emission signals of physical radiation, in particular, acoustic emission signals, the time series of which are also fractal - deterministically chaotic and carry important information about the nature of the occurrence of data from natural and induced by external interference mountain processes. Applying the methods of analysis of nonlinear dynamic systems, fractal analysis methods, it is possible to record the time series of physical radiation continuously using high-speed computers, with a minimum delay, to "observe" the state of the geological environment of a saturated oil reservoir. A nonlinear dynamic reservoir system is characterized by a strange attractor that attracts a set in a multidimensional phase space in which its trajectories are located. As a result of continuous computing on a computer, it is possible for a short time to analyze a sufficiently large sample of the emission signal, calculate the necessary parameters and obtain a picture of the attractor obtained on the monitor screen. Almost immediately, a similar analysis of the next signal sample coming from the medium occurs. In this case, during continuous analysis, the data and pictures corresponding to the processes occurring in the nonlinear dynamic system-layer will continuously change on the screen.

According to the invention, in the identified areas or near them, wells are selected and pulses of physical energies are successively fed through them into the formation. The perturbations of mechanical stresses that arise in the geological environment have a very significant effect on the state of the rocks, affecting the ductility, the kinetics of the formation of structural defects, micro- and macrocracks, and other processes. But from the point of view of a sufficiently remote effect on metastable screens with realistically achievable energetics with the creation of wave channels penetrating the formation, it is necessary to achieve a new impact quality - a transition to a new state through a sequential change in the medium with the maximum release of its own energy at each stage of exposure. At the same time, continuous energy-information interaction is organized in the feedback mode with the geological environment of the formation during the action from the wells.

This is as follows. Geological media emit emission signals even in a relatively equilibrium state, and at the same time, a strange attractor continuously pulsed on a computer pulsates in time. The state of relative equilibrium in the system is replaced by phases of a more unstable state, which indicates that emission of emission energy is accompanied by alternating phases of energy storage and subsequent discharge. Under the influence of external energy exposure, the emission of emission energy increases sharply, the pulsations of a strange attractor change the character and amplitude. When a pulse, for example, pressure in a fluid, is supplied from a well into a formation, the response of the medium is simultaneously analyzed - the emission signal from the formation, the change in the state of the formation system is recorded, and the timing of the subsequent pulse is determined, which corresponds to the phase of maximum local instability of the state of the medium. Under the influence of each pressure impulse, a certain transformation of the medium occurs - crack opening and additional crack formation with the restructuring of the structural matrix and a change in the saturation fields under the influence of rock stresses and fluid pressure. Similar certain changes occur when other energies, for example, electromagnetic ones, are fed into the formation. It is important that in this case a certain fraction of the formation’s own energy is released.

At the moment of impulse supply from the well, the transformation of the medium and the release of energy corresponding to the occurrence of local instability of the medium are maximum. If at the beginning of the action for observing the attractor there are not enough changes in the state of the medium, then feedback training is provided for “training” the effect - the pulse power and its frequency parameters change, until the corresponding useful medium reaction appears. Each subsequent impulse passes through a more conductive medium, and the depth of its energy impact and the release of energy for each stage of exposure increase. The released energy feeds the energy of the impulse and also increases the depth of exposure. But the most important thing is that in this case the contraction of the changes occurring under the influence of pulses occurs towards the place of maximum activity of the formation environment - to the previously identified zone of increased fracturing and tension. The impact is concentrated on a certain vector - a wave channel of energy transfer is formed. To confirm this process, we can draw an analogy in a natural phenomenon, when before the impact of a powerful lightning discharge to a certain place on the surface, you can observe the gradual preliminary occurrence of a weakly luminous beam - a precursor channel indicating the place of the subsequent lightning strike.

When the wave channel reaches the zone of maximum metastability of the state of the medium, trigger effects arise with the complete release of its own reservoir energy, the structure of the metastable screens is reorganized, new filtering channels are formed, favorable changes in the saturation and filtration fields occur, leading already to additional mass transfer to the wells. When performing an impact simultaneously from a group of wells, the resulting wave channels of energy-mass transfer are pulled together in one place and multiply the effect of exposure. If the zones of increased fracture coincide with local ring-shaped repressions and depressions of rocks penetrating from the depths of the crystalline basement into the reservoir of the oil and gas reservoir, this effect can also contribute to a sharp acceleration of the additional influx of mantle oil into the reservoir.

Before effecting the formation in selected wells, operations are carried out to initiate wave channels of energy-mass transfer. These operations include vibrating the bottomhole zones (PZP) to clean the filter channels of the porous medium, facilitate penetration of the working fluid into micropores and fractures of the rock, provide a wedging effect, weaken the surface strength of the rock and develop crack nucleation and microcracks in the PZP. When acid solutions are used as the working fluid, these processes are intensified both in terms of area and depth of exposure. If necessary, in order to improve the quality of cleaning and weakening the rock, the vibrating microwave effect is combined with cyclic repression and depression. As a result, a network of deep and branched cracks forms in the PZP and favorable conditions are created for the subsequent development of wave channels.

Fractal analysis of acoustic emission signals and / or electromagnetic emission signals coming from the geological environment and the construction of attractors of the state of its structure in real time are also carried out in well drilling processes. At the same time, effective comprehensive monitoring of drilling is carried out - according to a continuous change in the patterns of attractors, the condition of rock cutting tools is diagnosed, the approach of the bits to the zones of increased fracture is determined, the passage of the collectors by the drill with an assessment of their water or oil saturation is detected, the approach of the bits to possible zones with an abnormally high fluid pressure is determined in advance that allows during drilling to carry out the necessary technological operations in time to prevent accidental spills s drill pipes and at the same time maintain the necessary conditions for the successful subsequent development of oil reservoirs.

The method is as follows.

For the selected oil field, a study is made of the geological environment of the formation, tomography of the productive formations and the underlying mountainous environment along the section and over the area, for example, using the side-scan seismic location method (SLE) for a detailed study of the geological features of the occurrence, distribution of natural fracturing zones, weakly drained zones, and also identify zones of anomalies of seismic activity and other geological and physical parameters of the environment. The location of the objects of influence — these zones by the area of the reservoir — is determined and, within the limits of these zones, wells are selected whose drainage zones are associated with these objects or new ones are drilled to conduct complex physical impacts on the formation.

If it is necessary to clarify the available data, according to the methods of the inventors, they conduct laboratory studies of acoustoplastic and filtration-deformation processes on cores in the field of elastic vibrations and determine the threshold parameters of vibrational displacement and acceleration for the effective conduct of the microwave action in order to clean porous PZP wells and form microcracks, as well as for exposure to disturbing stresses on the identified zones.

Equipped sections of oil deposits for implementing the method.

In the injection and production wells selected for the impact, preliminary work is carried out to prepare for the impact on the formation, they plan the territory for arranging equipment and laying communications, check the technical condition of the wells, specify the geological and physical characteristics of the formation, evaluate the required operating parameters for supplying fluid pressure pulses, produce the necessary equipment of the wellhead with the required equipment, computer measuring complexes and carry out other necessary about work regulations. If necessary, produce additional perforation of the reservoir.

Hydrodynamic generators are installed in wells on descent tubing at the level of the productive interval of the formation and, with the supply of working fluid by wellhead pumping units, operations are carried out to initiate wave channels of energy-mass transfer in the formations: a vibrating microwave effect on the bottomhole formation zone in combination with cyclic repression-depression for filtering treatment channels of the porous medium, providing a wedging effect and weakening the surface strength of the rocks. When using special fluids, for example, oil-acid emulsions, as a working fluid, these processes are intensified both in terms of area and depth of exposure. At the same time, at the wellhead, using the measuring complex developed by the authors, it is possible to continuously record and fractal analyze the resulting response of the PZP medium - changes in the intensity and nature of acoustic emission events, based on which to control the operating modes of hydrodynamic generators and decide on additional processing cycles or completion of preliminary initiating work in the wells.

At the next stage of work, through the faces of wells, the formation is exposed to pulses of physical energies, for example, pressure pulses in the liquid. Wells are equipped with special downhole or wellhead impulse valve devices, and simultaneously with the operation of wellhead pumping units, successive supply of pressure pulses to the reservoir is performed. At the same time, recording and analysis of AE signals from the reservoir and computer monitoring of exposure modes are carried out at the same time. Using the created feedback with the reservoir, the effectiveness of the impact is monitored and its mode is adjusted - the optimal moments of the pulse supply and their energy and amplitude-frequency parameters are selected, which ensure the process of continuous creation of the wave channel of energy-mass transfer in the reservoir medium.

After the completion of the main stage of work, the treated wells are put into operation and injection agents are injected into injection wells and formation fluid is taken through production wells. At the same time, to ensure optimal conditions for oil displacement, special fluids - chemicals or coolants - can be pumped efficiently through the wave channels of energy-mass transfer formed in the formation. Also, these channels can be effectively used to supply electric currents or electromagnetic radiation streams into the formation.

To maintain the functioning of the wave channels of energy-mass transfer in the formation for a sufficiently long time, it is possible simultaneously with the selection of formation fluid to produce an additional effect on the geological environment of the formation by perturbations of mechanical stresses. For this purpose, wellhead or downhole generators or valve-pulse devices are installed in separate wells. They work continuously or periodically simultaneously with the injection of displacing agents in the injection wells and with the selection of formation fluid through the production wells. As them, hydrodynamic generators with a constant suspension can be used, including those working together with ESP in production wells, pulsed downhole equipment working in conjunction with sucker rod pumps, and other valve-pulse devices designed by the authors of the present invention. It is also possible to additionally influence the geological environment of the formation using surface vibroseismic sources - mobile vibroseismic platforms or vibration hammers that transmit energy towards the active zone of the formation through special anchor wells buried beneath loose surface soils.

The creation of unsteady and alternating pressure drops in the formation environment also with the aim of enhancing and maintaining a sufficient duration of the achieved effects can be achieved by changing the bottomhole pressure (injection and selection modes) in the wells, up to a complete periodic shutdown of the whole group of selected wells. At the same time, during shutdowns of injection wells into wells opposite to them, injection cycles are carried out in an alternating mode with large amplitudes of variation in the injection pressure. Periodic injection of the required increased volumes of fluid through hydrodynamic generators installed in the wells can be carried out at standard or even reduced pressures on the injection line, and at the same time it becomes possible to vary the parameters of the periodic injection over a wide range even using conventional SPS lines.

When implementing the method and implementing complex physical impact, not only the features of the geological structure of the formation are most fully taken into account, but also the possibility of its transformation, as well as the direction and nature of this transformation, while to ensure a sufficiently large scale and depth of the impact, the energy reserves of existing metastable states are rationally used mountain environments, providing a significant increase in the development of deposits, the development of stagnant, not previously covered zones and areas, a significant increase in the completeness of oil recovery from formations.

An example implementation of the method.

At the oil field they performed tomography using the SLBO method. We also conducted studies of natural acoustic noise and microbiological studies of hydrocarbon leaks over the reservoir area, which made it possible to identify areas of increased fracturing, increased microseismic activity, and poorly drained zones associated with undeveloped oil reserves. To clarify the binding of undeveloped reserves in areas to specific wells, we also conducted the methodology of the study of accumulated experimental production material by analyzing the displacement characteristics of the wells and assessed the ratio of relative recoverable reserves and mobile reserves to determine wells in which the actual oil content is lower than that given.

Based on the studies, a section of the oil field was selected for the method, which includes 6 injection and 15 production wells. A diagram of the deposit site is shown in the drawing. The objects of development are carbonate strata of the middle Carboniferous of the Kashirsky, Vereisky horizons and the Bashkirian tier. The main object of development on the site are limestones of the Verey horizon with a porosity of 11-15%, permeability - 0.06 μm ² . The oil density in the conditions of bedding is 887.0-910.0 kg / m ³ , the viscosity is 13-34 MPa · s, the saturation pressure is 7.0 MPa. The depth to the top of the beds is 1250-1300 m. The water cut of the average carbon is 60%.

The average daily current oil production in the area is 28.5 tons / day, the weighted water cut is 55%. The average daily current water injection is 236.3 m ³ / day, the average injectivity of wells is 39.4 m ³ / day, the average production rate of oil wells is 1.9 tons / day. In producing wells, 5 are operated using ESP (numbers 3, 8, 13, 14, 19 see drawing) and 10 - SHGN. Distribution by water cut: five wells are produced with water cut from 4.7 to 13.9%, four - with water cut from 55 to 95%, four - with water cut over 98%.

Distances between production and injection wells are from 350 to 450 m.

Based on core materials and reservoir fluid samples taken at the site, laboratory studies of the influence of mechanical stress disturbances on acoustoplastic and filtration-deformation processes were carried out and the threshold parameters of the vibrational displacement of the occurrence of trigger effects of deformation, accumulation of microdestruction and structural adjustment of saturated rocks ξ = 0.3 μm were determined, as well as threshold vibrational parameters of the occurrence of filtration effects and decolmation phenomena ξ = 0.25 m / s ² , ξ = 0.65 m km

The site is being arranged and preparatory work is being carried out, the technical characteristics of the generators planned for use, including pulse ones, are being set up to provide the required amplitude-frequency modes of exposure for each application.

Next, the implementation of the method begins. In injection wells 7, 10, 21, the bottom-hole zone is preliminarily cleaned of mechanical muds and tar asphalt using the Strant generator GD2V-3GT surfactant and hydrocarbon solvent compositions. Flushing of the face is carried out using a coiled tubing unit of the Hydra Rig type and a pump unit CA-320. The injectivity of wells 7, 10, 21 is adjusted to 31, 23, 50 m ³ / day, respectively, at an injection pressure of 13 MPa. Further, the Strant GD2V-6VSh generators are installed in the wells on the tubing pipes and connected to the pipelines of the SPS.

After beating the faces, washing the trunks, and patterning them into production wells 4, 9, 12, 18, the Strantor GD2V-15 generators are lowered to the tubing, while mechanical packers with anchors are installed on the pipes above the generators. A mixer is connected to the wellhead fittings, to which pressure lines of 3 pump units of the SIN-35 (TsA-320) type and 2 acid units for parallel operation are connected. The receiving hoses of the pumping units are installed in a technological capacity of 30 m ³ , filled with oil. From the annular valve, a flow line is laid in the technological tank.

Oil-Engineering Scientific-Production Enterprise measuring complex is connected to the well strings for recording acoustic signals from the formation along the casing, represented by sensitive piezoelectric transducers of the DN-3-M1 and DN-4-M1 types, signal pre-amplification devices, VSHV-003 -M3, analog-to-digital converter (ADC) E-330, a portable laptop computer based on the Intel Pentium-M processor, equipped with special calculation programs.

The working fluid is pumped - oil through the generators in alternating circulation modes through the annulus and technological capacity and - filling into the reservoir - outflow from the reservoir. At the same time, continuous monitoring of changes in the state of the environment of the PZP is carried out on the computer of the measuring complex. According to this control, if necessary, operations of pumping and injecting successively hydrochloric acid (24-28%) and oil-acid emulsion (50%) into the reservoir are prescribed, and it is possible to increase the pressure at the faces to rock pressure and higher. According to computer control, initiation operations are stopped, downhole fittings are bound to a nitrogen unit, and a microwave and foam action is applied to the bottomhole formation zone with the extraction of chemical reaction products from the formation.

Hydrodynamic generators are lifted from the wells by pipes and replaced with special downhole electromagnetic emitters of high-amplitude pressure pulses or valve-pulse hydraulic devices of the Oil-Engineering Scientific-Production Enterprise design. Electromagnetic emitters are based on the principle of repulsion of induced magnetic fluxes, which allow developing power in pulses up to 0.5-1.0 GW They descend on 73 mm tubing into the interval of the reservoir and connect cable to the generator of electric pulses with adjustable amplitude, duty cycle (0.1-10 s) and the oscillation frequency in the wave train (10-1000 Hz). The cable is attached to the pipes with clamps. The well valves are connected to the pump units and at the same time pumping the working fluid - oil through valve-pulse devices and / or electromagnetic emitters sequential supply of pressure pulses into the reservoir. Continuous computer control of changes in the environment of the reservoir is carried out and changes of the modes Pressure pulses cottages. In this case, the pulse power of electromagnetic emitters is successively increased from 10-15 kW to 0.5-1 GW. These changes are carried out both by adjusting the flow-pressure characteristics of the pumps and adjusting the adjustments of the operating units of the valve-pulse devices, and by adjusting the electric pulse generator to emit electromagnetic waves into the reservoir of pulses of elastic vibrations with a variable amplitude, as well as the sequence and frequency of oscillations in the train .

For production wells 3, 6, 14, 16, 20, sucker rod pumps are being re-equipped - pump shanks are equipped with special impulse downhole equipment of the Oil-Engineering Scientific-Production Enterprise design with pipe extension and unloading to the bottom.

After completion of the impact operations in wells 4, 9, 12, 18, when installing sucker rod pumps on them, this re-equipment is also carried out.

In production wells 3, 8, 13, 19, additional equipment for ESP suspension is produced by Sapphire-type electric spark generators, which are powered by an ESP electric drive system.

The injection wells of the section are additionally equipped with wellhead automated gate valves with remote control.

After completion of the operations of creating wave channels of energy-mass transfer in wells 4, 9, 12, 18, all wells are put into operation. At the same time, the action of disturbances of mechanical stresses from the groups of both production and injection wells is simultaneously performed.

The creation of unsteady and alternating pressure drops in the formation medium is carried out by periodic shutdown (10-14 days) of the injection well 7 during operation of the well 10 during this period of cyclic injection start-stop with a short period (5-10 hours). Well 7 works in a similar manner during shutdown periods of well 10.

When water is injected into injection wells and simultaneously exposed through elastic vibrations, the average injectivity increases and reaches a value of 54.3 m ³ / day. When selecting reservoir fluid, an impulse effect is simultaneously performed during operation of both rod pumps and ESPs.

In this mode, the site operation process is carried out for 2.5 months.

As a result, after this period, the weighted water cut of the products in the area decreased to 37%, and the average daily oil production increased to 42.2 tons / day (48%).

The use of the invention allows to significantly increase the efficiency of oil field development, in addition, its technical operations can be successfully used for computer control and monitoring of drilling processes, hydraulic fracturing in wells. These operations provide new opportunities for successful short-term earthquake control, as well as to predict the occurrence of harmful industrial phenomena, landslides, destruction of large-scale structures, etc.

Claims (19)

1. A method of developing an oil field, including injection of displacing agents into injection wells and selection of formation fluid through production wells, investigation of the natural fracturing of the geological environment of the formation, initiation and creation of additional mass transfer channels to the wells, characterized in that when studying natural fracturing, they are identified by the area of the reservoir zones of increased fracturing, tension of the reservoir environment, and production wells are selected in or near these zones, or they drill additional ones, initiate and create wave channels of energy and mass transfer at the productive intervals of these wells in the reservoirs by sequentially supplying pulses of physical energies to the reservoir with simultaneous recording of acoustic emission signals and / or electromagnetic emission signals from the reservoir, their fractal analysis, and construction of volumetric attractors of the state of the geological structure real-time environment and continuous computer monitoring of tension, fluid saturation, pressure lyuida deposits of state change and development of energy-group of wells in the formation of channels on which the local maximum phase state instability deposits prescribed time supply of each subsequent pulse and alter its energy and frequency parameters until the appearance of the medium response. 2. The method according to claim 1, characterized in that the zones of increased fracturing in the reservoir are detected by seismic location side view of the wells. 3. The method according to claim 1, characterized in that as the pulses of physical energies when creating wave channels of energy and mass transfer, pressure pulses of the well fluid and / or electromagnetic and / or thermal pulses are used. 4. The method according to claim 1, characterized in that the initiation of the wave channels of energy-mass transfer at the productive intervals of the selected wells is carried out by superimposing the stages of repression-depression and reagent effects on the formation in combination with the simultaneous action of elastic vibrations. 5. The method according to claim 4, characterized in that the action of elastic vibrations on the formation when initiating wave channels of energy and mass transfer in selected wells is carried out by borehole hydrodynamic generators with vibrational displacement values exceeding 0.3-1.0 μm and in the frequency range of 20-450 Hz 6. The method according to claim 4, characterized in that the reagent action on the formation when initiating wave channels of energy and mass transfer in selected wells is carried out by pumping acids and / or oil-based emulsions into the formation. 7. The method according to claim 3, characterized in that during the sequential supply of pressure pulses into the formation, oil acid emulsion is used as the well fluid. 8. The method according to claim 7, characterized in that the oil-emulsion emulsion is prepared directly at the bottom of the wells by pumping a mixture of acid and oil through a borehole hydrodynamic generator of elastic vibrations. 9. The method according to claim 1, characterized in that in the process of drilling wells simultaneously record and fractal analysis of acoustic emission signals and / or electromagnetic emission signals coming from the drilling medium, based on which the drilling process is monitored and its operational operations are assigned, in in particular the replacement of drilling tools or temporary weighting of the drilling fluid. 10. The method according to claim 1, characterized in that after creating the wave channels of energy-mass transfer in the formation, fluids are pumped into them - chemicals and / or coolants. 11. The method according to claim 1, characterized in that after creating the wave channels of energy-mass transfer in the formation, an electrically conductive medium is created in them and electric currents or electromagnetic radiation flows are supplied. 12. The method according to claim 1, characterized in that after the creation of wave channels of energy-mass transfer in the formation at the productive intervals of the selected wells and putting them into operation simultaneously with the selection of formation fluid, they additionally affect the geological environment of the formation by disturbances of mechanical stresses. 13. The method according to p. 12, characterized in that the impact on the geological environment of the formation by disturbances of mechanical stresses is carried out with the excitation and propagation of waves and / or pulses of elastic vibrations and / or electromagnetic waves and / or pulses in the formation. 14. The method according to p. 12, characterized in that the impact on the geological environment of the formation by disturbances of mechanical stresses is carried out by generators of elastic and / or electromagnetic waves, and / or pulses from the faces of additionally selected production and / or injection wells. 15. The method according to p. 14, characterized in that in addition to the impact on the geological environment of the reservoir disturbances of mechanical stresses from the wells, for example downhole generators, simultaneously or alternately carry out this action also from the surface of the reservoir, for example surface vibroseismic sources. 16. The method according to p. 12, characterized in that the impact of disturbances of mechanical stresses on the geological environment of the formation is carried out with parameters of vibrational acceleration and vibrational displacement exceeding, respectively, 0.1-0.5 m / s ² and 0.1-1, 0 microns. 17. The method according to p. 12, characterized in that the impact on the geological environment of the formation by perturbations of mechanical stresses is carried out continuously or periodically in periods of time associated with the action on the geological environment of global geoplanetary factors, for example, the action of lunar tides. 18. The method according to p. 12, characterized in that in addition to acting on the geological environment of the formation, disturbances of mechanical stress simultaneously with the selection of the formation fluid in the formation cyclically change the formation pressure. 19. The method according to p. 12, characterized in that in addition to the impact on the geological environment of the formation by disturbances of mechanical stresses after creating wave channels of energy and mass transfer at the selected wells and putting them into operation simultaneously with the selection of the formation fluid in the reservoir, it is cyclically disconnected and / or connected to work groups of wells and initiate a change in the direction of the filtration flows in the reservoir.