WO2015072884A1 - Method for the exploration of oil and gas deposits and system for the implementation thereof - Google Patents

Abstract

The present multi-frequency phase sounding method, intended for the search for and detailed exploration of oil and gas deposits, includes acting on an oil and gas deposit with an electric field and a seismic wave, thus initiating electrical polarization and the displacement of petroleum fluid particles into reservoir rock and generating, in the deposit, an electromagnetic field (deposit response) commensurate with this action, and measuring and recording the parameters of the deposit response, which reflect a change in the phase-frequency characteristics of the spectrum of the seismic wave as it passes through the deposit, thus making it possible to register the presence of an oil and gas deposit and to determine the characteristics thereof.

Description

 METHOD FOR EXPLORING OIL AND GAS DEPOSITS AND

 COMPLEX FOR ITS IMPLEMENTATION

Technical field

 The invention relates to the field of exploration geophysics and is intended to conduct searches and a detailed study of oil and gas deposits (NGZ) on land, offshore and deep-water marine areas (including with permanent ice cover), as well as monitoring reserves in exploited NGZ in the interests of rational nature management.

 State of the art

 Known methods based on the study of the anomalous effects created by NGD under the influence of one of the natural or artificially excited physical fields - seismic exploration, electrical exploration, gravimetry, magnetic exploration, thermal exploration, radiometry and geochemistry (http.7 / ru.wikipedia. org / wiki / Γeoφhizic,

http://www.astronet.rU/db/msg/l 173309 /,

http: // geo. web.m / db / msg.htm ^ mid ^ 1 161637 & uri = page 17.html). All of the above methods use a physical field of the same kind, while almost all existing natural physical fields and the results of their interaction are present in the NGD and its environment. Seismoelectric methods are also known that combine seismic and electrical exploration based on the seismic-electric effect (SEE) - the appearance of electromagnetic fields (EMF) in the environment surrounding a gas condensate under the influence of a seismic wave, which causes the movement of particles of oil and gas fluid in micro-nanoscale capillaries of the host rock -collector (US patent 4904942). As a result of this movement, due to the friction of the particles of oil and gas fluid on the solid walls of the capillaries and overcoming the forces of surface tension, they are electrified. However, the EMFs arising from this usually have such a low intensity that the seismoelectric methods have still not found practical application in oil and gas exploration, since their real depth does not exceed several hundred meters.

 Seismoelectromagnetic (SEM) methods are also known.

(US Pat. Nos. 7,042,801, 7,330,790), which, in the aggregate of the essential features characterizing them, are the closest analogue to the claimed objects. The disadvantages, in particular, of the closest analogue are low noise immunity in the presence of electromagnetic and acoustic interference of natural and artificial origin, which forces the use of sophisticated methods of processing the received signals, which can not always provide high-quality results in real time. The reason for this is that in SEM methods only pulse-transition parameters and amplitude-time characteristics are used as information data _

3

secondary EMF characteristics that do not allow reliably determining the depth and productive capacity of NGZ.

 The problem to be solved and the technical result achieved

 The problem to be solved by the described invention is to improve the known methods and devices, in particular, the target complex impact on the desired NGD of two or more heterogeneous physical fields (polarizing electric fields and periodic multi-frequency seismic effects) in order to obtain information on phase-frequency characteristics (PFC) of electromagnetic response signals (NGS responses) of the secondary EMF generated by the NHS under the complex influence of these physical fields.

 The technical result achieved in this case consists in increasing the efficiency and probability of reliable detection of NGZ, a qualitative detailed description of the required NGZ.

 The list of drawings and designations on them

 The specified technical result is achieved using the proposed method and device for its implementation, which is schematically reflected in the following drawings:

 FIG. 1. Schematic representation of NGZ (Option).

 FIG. 2. The idealized structure of NGZ.

 FIG.Z. Representation of NGZ in the form of a capacitor.

 FIGA Capillary model NGZ.

 FIG. 5. Influencing and information fields according to the MP method.

FIG.6. Basic operations according to the MP method. FIG. 7. ZO-configuration of the exploration complex (GTRK) for the implementation of the MFZ method.

 FIG. 8. The principle of organization of the MN reception line in one shoulder.

 FIG. 9. Schematic representation of the receiving line MN in one shoulder.

 FIG. 10. The principle of organizing the MN reception line “into the gap” into two symmetrical arms along one line.

 FIG. 1. 1. Schematic representation of the receiving line MN “into the gap” in two symmetrical arms along one line.

 FIG. 12. Phasometric device for determining the depth of NGZ (FMU-G) by the electrical (E) components of the NGZ response.

 FIG.13. Phasometric device for determining the depth of NGZ (FMU-G) by the magnetic (N) components of the NGZ response.

 FIG. 14. The phasometric device for determining the power of the NGZ and the oil / free gas ratio in the NGZ (FMU-M) by the electrical (E) components of the NGZ response.

 FIG. 15. Phase measuring device for determining power

NGZ and oil / free gas ratios in NGZ (FMU-M) by the magnetic (N) components of the NGZ response.

 FIG.16. Structural scheme of GTRK for the implementation of the MFZ method.

 FIG. 17. X-shaped GTRK for the implementation of the MFZ method.

FIG. 18. V-shaped GTRK for the implementation of the MFZ method. FIG. 19. Linear two-shoulder PRK for the implementation of the MP method.

 FIG. 20. L-shaped PPH for the implementation of the MFZ method. FIG. 21. Linear single-shoulder PPH for the implementation of the MP method.

 The main structural nodes and features of the claimed device and auxiliary images are identified by a list of their designations in the indicated figures, namely:

 1 - sedimentary rocks;

 2 - tire;

 3 - free gas;

 4 - oil;

 5 - water;

 6 - reservoir rock;

 7 - free gas zone;

 8 - zone of oil with dissolved gas;

 9 - oil zone;

 10 - hydrophobic zone of oil;

 1 1 - zone of mineralized water;

 12 - capillaries;

 13 - hardware-software complex (AIC);

 14 - source of elastic vibrations (IAA);

 15 - seismic receiver (SP);

 16 - supply line AB;

 17 - receiving line MN;

18 - three-component magnetometer; 19 - receivers of electrical (E) components of the NGZ response;

20 - movable module (PM);

 21 - electric field;

 22 - seismic wave;

 23 - direction of the incident seismic wave;

 24 - direction of displacement of particles of oil and gas fluid;

25 - electrical (E) components of the NGZ response;

 26 — magnetic (H) components of the NGZ response;

 27 - the BEGINNING of operations using the MFZ method;

 28 - 1 STAGE - PREPARATION;

 29 - operation “Occupation of the initial position”;

 30 - operation “DEPLOYMENT OF THE SEARCH AND EXPLORATION COMPLEX”;

 31 - 2 STAGE - SEARCH;

 32 - operation "ELECTRIC POLARIZATION";

 33 - operation "SEISMIC IMPACT";

 34 - operation "RECEIVING AND REGISTRATION OF DATA";

 35 - operation "DETECTION OF NGZ";

 36 - 3 STAGE - DETAILED EXPLORATION;

 37 - operation "MOVING PM BY PROFILES";

38 - operation "ACCUMULATION OF DATA ARRAY";

 39 - 4 STEP - DESCRIPTION;

 40 - operation “INTERPRETATION OF DATA”;

 41 - operation "DETERMINATION OF THE DEPTH OF THE DEPOSIT

NGZ ";

42 - operation "DETERMINATION OF CAPACITY NGZ"; 43 - operation "DETERMINATION OF THE RELATIONSHIP OIL / FREE GAS IN NGZ";

 44 - operation "DESCRIPTION OF NGZ";

 45 - END of operations on the MFZ method;

 46 - input filter;

 47 - adder;

 48 - scale amplifier;

 49 - device instant automatic gain control (MARU);

 50 - digital filter;

 51 - phase meter;

 52 - pulse shaper;

 53 - meter time intervals;

 54 - frequency multiplier;

 55 - channel FMU-M from the receiving line MXNX;

 56 - channel FMU-M from the receiving line MYNY;

 57 - channel FMU-M from the receiving line MZNZ;

 58 - control and processing unit (BWO);

 59 - the main computer (RNO);

 60 - transceiver equipment (PAP);

 61 - receiver GPS / GLONASS;

 62 - generator block (GB);

 63 - electric generator;

 64 - receiving and measuring unit (PIB);

65 - auxiliary computer (RSV); 66 - transformer;

 67 - controlled rectifier;

 68 - pulse generator;

 69 - generator of elastic vibrations;

 70 - GPS / GLONASS coordinate reference system;

 71 is a phase measuring device for determining the depth of the NGZ (FMU-G);

 72 is a phasometric device for determining the power of NGZ and the ratio of free gas / oil in NGZ (FMU-M);

 73 - antenna transmitting and receiving equipment (PAP);

 74 - antenna receiver GPS / GLONASS;

Detailed description and examples of carrying out the invention. The method of multi-frequency phase sensing (MFZ-method) of prospecting and detailed exploration of oil and gas deposits (NGZ) is characterized by a combination of interconnected focus on achieving the indicated achievable technical result of the operations reflected in the claims. The MFZ method includes the following steps, during the implementation of which the NGD is electrically polarized by creating an electric field of a three-dimensional spatial configuration and a stable amplitude-phase spectrum and purposefully using multi-frequency seismic oscillation sources (IAA), multi-frequency seismic action three-dimensional spatial configuration with stable amplitude-phase spectra that affect NGS. In re- As a result of the combined effects of these physical fields, electric polarization and the subsequent movement of oil and gas particles in the capillaries, micropores and microcracks of the reservoir rock are initiated. In this way, an electromagnetic field (NGS response) adequate to these influences is formed in the NGD and its environment, the parameters of the NGZ response formed in this way are measured and recorded, reflecting the change in the main phase-frequency characteristics (PFC) of the spectrum of the seismic wave during passage her through the NGZ.

If an abnormal, exceeding the measured background value over areas without anomalies is detected, phase difference between the different frequencies (1st and 2nd ^ 7th) harmonics of the NGD response and the initial ones taken as reference, different frequencies (1st and 2- ^ -7th) by the harmonics of seismic effects, the presence of a gas condensate in the studied geological section is recorded. Then repeat the above-mentioned operations on the profiles within the studied area and form a database of measured parameters of the NGD responses to determine the depth, power and the oil / free gas ratio of the NGD. By analyzing and producing a geological and geophysical interpretation of the data obtained, they form a set of computer codes that are adequate to them, and determine the characteristics and parameters of the study of gas condensate, on the basis of which 2D and 3D graphic images of maps, sections, and 3D models of gas condensate are formed. If necessary, repeat the above set of operations. A useful modification of the claimed object is a method in which, to determine the depth of the NGD, the obtained data on the phase shifts between the 1st harmonic of the initial seismic effect and the 1st harmonic of the NHZ response are measured and interpreted. To clarify the desired result, we additionally measure the time shifts between the leading edges of the initial seismic effect and the NGS response at the known propagation velocity of the seismic wave in the studied geological section. This also applies to a method in which, to determine the power of an OGD, the obtained data on changes in the values of phase shifts between the 1st and 2nd ^ 7th harmonics in the OGG response relative to their values in the initial seismic action arising from dispersion of the phase velocity of a seismic wave as it passes through the NGD. Also useful is the method in which, to determine the oil / free gas ratio in the NGD, the obtained data on the changes in the phase shifts between the 1st and 2nd - 7th harmonics in the NGD response relative to their values in the initial one are measured and interpreted seismic action resulting from the dispersion of the phase velocity of the seismic wave during its passage through the NG, with sequential seismic action in the frequency range of 1-30 Hz in increments of 1 -5 Hz.

The search and exploration complex (GTRK) for implementing the claimed method is characterized by a set of interrelated focus on achieving the specified achievable technical result reflected in the claims design features and their features. GTRK is designed as interconnected receiving and transmitting equipment (PAP) of a hardware-software complex (AIC) and selected in an amount from one to twelve mobile modules (PM). Each of the PMs is composed of interconnected control and information processing unit (CUO), including an auxiliary computer (RSV) and a coordinate reference system (GPS), a receiving and measuring unit (PIB), including a geophysical receiver (SP), a three-component magnetometer, phase meter for determining the depth of NGZ (FMU-G) by magnetic (NH, HY and HZ) components of the NGZ response, phase meter for determining the power of NGZ and the oil / free gas ratio in NGZ (FMU-M) by magnetic (HX, HY and HZ) components face, generator unit (GB), including an electric generator, generator of elastic vibrations, source of elastic vibrations (IAA).

At the same time, the agro-industrial complex is composed of interconnected control and information processing unit (CUO), which includes the main computer (RSO) and coordinate reference system (GPS), the generator unit (GB), which includes an electric generator, a transformer, three pulse generators, one for each of the supply lines (AB) connected to the transformer through controlled rectifiers, an elastic oscillation generator, an elastic oscillation source (IAA), three mutually perpendicular supply lines (AB), two of which (AXBX and AYBY) are located in the horizontal planes with the formation of a symmetrical cross. Each of the AHBX and AYBY is connected to the generator unit “in gap” in two symmetrical arms, and the third (AZBZ) is connected to the generator unit in one arm and placed vertically down from the intersection of two horizontal ones.

The receiving and measuring unit (PIB) of the agro-industrial complex includes a seismic receiver (SP), a three-component magnetometer, a phase measuring device for determining the depth of the NGZ (FMU-G) based on the magnetic (NH, HY and HZ) components of the NGZ response, a phase meter a device for determining the power of NGZ and the ratio of oil / free gas in the NGZ (FMU-M) by the magnetic (HX, HY and HZ) components of the NGZ response, a phase measuring device for determining the depth of the NGZ (FMU-G) by electrical (EX, EY and EZ) components of the NGZ response, a phase measuring device for determining the power H GZ and oil / free gas ratios in NGZ (ФМУ-М) on electric (EX, EY and EZ) components of NGZ-response, three mutually perpendicular receiving lines (MN). Two of them (MXNX and MYNY) are placed in a horizontal plane with the formation of a symmetrical cross coaxially with the feeding lines AXBX and AYBY. At the same time, each MXNX and MYNY line is connected to the receiving and measuring unit “in gap” into two symmetrical arms, and the third (MZNZ) is connected to the receiving and measuring unit in one arm and placed vertically downward from the place of the AZBZ supply line the intersection of two horizontal. At the same time, from 3 to 24 meters of electric components of the field are connected to each arm of each of the receiving lines (MN). A useful modification of the claimed device is a complex in which two mutually perpendicular supply lines (AXBX and AYBY) are placed in a horizontal plane with the formation of a symmetrical cross, each connected to the generator unit “into a gap” into two symmetrical arms, and two mutually perpendicular receiving lines (MXNX and MYNY) are placed in the horizontal plane with the formation of a symmetrical cross coaxially with the AXBX and AYBY feeding lines, each connected to the receiving unit “into the gap” into two symmetrical arms. This also applies to a complex in which two mutually perpendicular supply lines (AXBX and AYBY) are placed in a horizontal plane from one point, each connected to the generator unit in one shoulder, and two mutually perpendicular receiving lines (MXNX and MYNY) are placed in a horizontal plane from one point coaxially with the supply lines, each connected to the receiving and measuring unit in one shoulder. A complex is also useful in which one supply line (AHVX) is placed in a horizontal plane along one line and connected to the generator unit “in gap” in two symmetrical arms, and one receiving line (MXNX) is placed in the horizontal plane along one line coaxially the supply line and is connected to the receiving and measuring unit “into the gap” in two symmetrical arms.

A suitable modification is a complex in which two mutually perpendicular supply lines (AXBX and AZBZ) are placed in a vertical plane from one point, each sub It is connected to the generator unit in one shoulder, one of which (AXBX) is located horizontally and the other (AZBZ) is vertically down, and two mutually perpendicular receiving lines (MXNX and MZNZ) are placed in a vertical plane from one point with the supply lines , each connected to the receiving and measuring unit in one arm, one of which (MXNX) is located horizontally coaxially with the AXVX supply line, and the other (MZNZ) is vertically downward.

 A complex is also useful in which one horizontal supply line (AXBX) is connected to the generator unit in one shoulder and one horizontal reception line (MXNX) is connected to the reception and measurement unit in one shoulder and placed from one point with the supply line coaxially her.

 It is also advisable to use the modification of the complex in the agro-industrial complex and the PM of which three or four phase-measuring devices for determining the depth of NGZ (FMU-G) are used to implement the claimed method, each of which includes three input filters for each of the electric (ΕΧ , ΕΥ, ΕΖ) and magnetic (ΗΧ, ΗΥ, ΗΖ) components of the NGD response, adder, two large-scale amplifiers (reference and information input) covered by an instantaneous automatic gain control (MARU) circuit, two digital filters, two shaper owls, time-interval meter and phase meter.

This also applies to the complex, in the agricultural and industrial complex of which three or four phase-measuring devices for determining the capacity of NGZ and the oil / free gas ratio in NGZ were used (FMU-M) for implementing the claimed method, each of which includes three measurement channels (channel X, channel Y and channel Z), one for each of the electric (EX, EY, EZ) and magnet nitric (HX, HY, HZ) components of the NHZ response. Moreover, each channel includes an input filter, a large-scale amplifier covered by the MARU circuit, two digital filters, a frequency multiplier, and a phase meter.

 In summary, the essence of the invention lies in the fact that the proposed method is a combination of the following operations:

 - creation of an electric field of a three-dimensional spatial configuration and a stable amplitude-phase spectrum for the electric polarization of NGD;

 - periodic multifrequency seismic action of a three-dimensional spatial configuration with stable amplitude-phase spectra for the oriented movement of polarized particles of oil and gas fluid in capillaries, micropores and microcracks of the reservoir relative to its solid skeleton, and the formation of electromagnetic fields adequate to this effect in NGZ (and its environment) ( NGZ response);

- registration and measurement of the phase response of the thus formed NGZ response, which reflects the change in the main phase response spectrum of the seismic impact passing through the layers of the GBZ and undergoes a change due to the dispersion of the phase velocity of the seismic waves in an absorbing nonlinear elastic medium of an oil and gas fluid; - making a decision on the presence of NGD in the studied geological section when an abnormal (exceeding the measured value of the background over the areas without anomalies) phase difference between the different-frequency (1st and 2nd- 7th) harmonics of the NGZ response and taken as reference different-frequency (1st and 2nd- ^ 7th) harmonics of the initial seismic action;

 - repetition of the above operations on profiles within the studied geographical area in order to form a database of measured phase response characteristics of NGZ responses to determine the depth and thickness of NGZ;

 - repetition of the above operations on profiles within the studied geographical area with a change in the frequency of seismic effects in the range of 1-30 Hz in steps of 1 Hz in order to form a database of measured phase-response characteristics of the NGZ responses to determine the oil / free gas ratio in the detected NGZ;

 - analysis and geological and geophysical interpretation of the obtained data, determination of the characteristics and parameters of the layers of the studied gas condensate formation, on the basis of which 2D and 3D graphic images of maps, sections, and ZO-models of gas condensation are formed, if necessary, repetition of the described set of operations.

The procedure for detecting and measuring the phase difference between different-frequency (1st and 2nd ^ 7th) harmonics of the NGD response and reference different-frequency (1st and 2nd ^ -7th) harmonics of the initial seismic effect eliminates the ambiguity of interpretation data, reduces the effects of natural and artificial interference origin, thereby increasing the likelihood and reliability of the detection of NGD in the studied geological section, the accuracy of the description of the studied NGZ.

 At the same time, the proposed method and device for its implementation, the prospecting and exploration complex (GTRK), ensure the achievement of a technical result: increasing the efficiency of searches and the likelihood of reliable detection of NGZ, a qualitative detailed description of the detected NGZ, as well as monitoring of stocks in operating NGZ.

It should be noted that in the application the principle of the unity of the invention is observed, since the proposed method and system have the same purpose, serve the same purpose, inextricably from each other ensure the achievement of the same technical result, and are interconnected by a single inventive concept characterized by the claims. At the same time, the concept of legal protection is based on the fact that the continuity and interconnectedness of the proposed objects, as well as the permissible variation in the implementation of certain essential features or their aggregates predetermine, including the unconventional nature of the wording of some features. For example, the design features of the proposed system are reflected not only by the characteristics of the nodes included in it and their structural relationships, but also by means of functional or structural analogues that uniquely characterize the device, by the implementation of the necessary functions. When presenting information confirming the possibility of implementing the claimed technical solution, it is advisable to describe in more detail practical examples of its implementation. When describing the examples, it is not advisable to dwell in detail on the information known from the published data. It would be advisable to dwell in detail only on the distinctive essential features of the proposed solution. The explanatory examples given are not the only possible ones and clearly demonstrate the achievement by the given set of essential features of the required technical result.

 In connection with the ambiguous interpretation by many specialists of the terms and concepts used in the description of inventions from the field of geophysics and exploration, it is advisable to give specific definitions that are used in the wording of essential features and a description of the claimed objects.

 - Oil and gas reservoir (NGZ) - a natural local accumulation of oil and gas in the void space of the host reservoir rock, usually limited by a fluid support above and supported by a layer of formation water from below, an integral fluid dynamic system, localized geological structure (http: // \ vww.mining-enc.ru/n/neftegazovaya-zalezh/).

- The reservoir rock is a rock having a void space, permeability, in which the movement of liquid and gas under the influence of gravity and differential pressure is possible. The collector is limited by a fluid stop (screen, lid) - rock that does not contain voids and channels, or contains voids and channels of such small sizes that makes it impossible to move liquid and gas.

 - NGZ layers - separated in NGZ separated by virtue of their inherent physicochemical properties, layers of free gas, oil, oil with gas dissolved in it at the boundary of the gas-oil contact, the hydrophilic layer of oil at the border of the oil-water contact and mineralized water .

 - Oil and gas fluid is a gas and oil system characterized by a state combining liquid oil and gas, the behavior of which during deformation can be described by the laws of fluid mechanics.

 - Geological section - a transverse section of the upper layers of the earth's crust containing rocks, faults and other geological structures lying below the surface of the Earth.

 - NGZ response - a multi-frequency electromagnetic signal - the response from the secondary EMF arising in the NGZ and its environment.

- Search and exploration complex (PRK) - a complex of equipment for conducting searches and detailed study of NGZ, which includes a hardware-software complex, one or two movable modules and a set of supply (AB) and receiving (MN) lines with primary field converters. Depending on the conditions of work, GTRK can be placed on a motorized chassis (land option) or in modules / containers for placement on a ship (marine option). - Hardware-software complex (AIC) - the main set of equipment and software as part of the State Television and Radio Broadcasting Company.

 - Mobile module (PM) - an auxiliary set of hardware and software as part of the PRK, located on a moving platform (for example, on a car chassis or a ship).

 The method consists in detecting, recording, analyzing and interpreting geophysical data obtained as a result of the reception and processing of NGD responses arising from the occurrence of physicochemical processes in the NGD, initiated by the targeted complex effect of polarizing electric fields and seismic on the NGD exposure.

The emergence of the NGS response is due to the effect of the electrokinetic conversion of the seismic energy into an electromagnetic field by an electrically polarized oil and gas fluid due to the occurrence of an electric current due to the oriented movement of charged particles of the oil and gas fluid in the capillaries, micropores and microcracks of the host reservoir rock. In this case, the phase response characteristics of the NGZ response unambiguously reflect the phase response frequency of the seismic wave passing through the layers of the gas pressure zone and undergo changes due to the dispersion of the phase velocity of the seismic waves in the absorbing nonlinear elastic medium of the oil and gas fluid, and their comparison with the reference phase response of the initial seismic effect allows one to practically reliably detect NGZ and determine its characteristics and parameters, such as: - spatial location of NGZ (contours, depth of bedding);

 - averaged effective thickness (power) of NGZ;

 - the ratio of free gas / oil in NGZ;

 necessary for the subsequent formation of 2D and 3D graphic images of maps, sections, GZ-models of NGZ.

 The method differs from the known in that:

 - as information data, the phase response characteristics of the NGZ response arising from seismic action on a previously electrically polarized NGZ are considered. The main information parameter in the method is the phase difference between the different frequencies harmonics of the NGZ response in comparison with the reference phase difference between the different frequencies harmonics of the initial seismic effect. In this case, the phenomenon of an abnormally high dispersion of the phase velocity of the seismic wave, reflected in the phase response of the NGZ response, is observed exclusively in the NGZ layers and is an almost reliable indicator of the presence of the NHS in the studied geological section;

 - seismic and polarizing electric influences are given specific spatio-temporal and phase-frequency configurations, which is achieved by the parameters of the apparatus generating electric and seismic influences, 2–3-dimensional geometry of the supply lines AB and spatial diversity of sources of elastic vibrations (IAA);

- it becomes possible to carry out ZO-tensor measurements, which is ensured by creating a 2-3-dimensional configuration MN receiving lines in combination with the spatial separation of three-component magnetic field receivers (magnetometers) over the studied area. Physicochemical basis of the MFZ method

NGZ is a natural accumulation of hydrocarbons (oil and gas) in the capillaries, micropores and microcracks of the host reservoir rock, bounded by a top impermeable to oil and gas fluid and a layer of mineralized water from the bottom (FIG. 1).

 At the same time, the volume of oil / free gas located in the NGZ has a number of unique properties:

 - significantly greater compressibility than the skeleton of the reservoir containing it, sedimentary rocks and water;

 - the ability to move in the capillaries of the collector;

 - the ability to polarize under the influence of electric fields;

 - the ability of electrokinetic conversion of the mechanical energy of seismic action into an electrical signal.

As a result of this, a pronounced dispersion of the phase velocity of seismic waves is observed in the NGZ, which is practically absent when they pass through ordinary sedimentary rocks. The properties listed above give the NGZ generally unique features that clearly distinguish the presence of oil and gas fluid in the studied geological section, which are a practically unambiguous indicator of its presence and are suitable for use in oil and gas exploration.

 NGZ, not disturbed by technological operations, can be represented in the form of an idealized structure (FIG. 2), in which there are five, not clearly delineated, but significantly different in their physicochemical properties:

 - free gas zone;

 - oil zone with a high content of gas dissolved in it;

 - oil zone (with a minimum gas content);

 - hydrophobic oil zone (with a small water content)

- water is located mainly along the walls of the capillaries of the collector, wetting their surface;

 - zone of mineralized water.

 Each of these zones has its own significantly different physical, chemical, physical and electrophysical properties and reacts differently to external influences in the form of artificially excited electric fields and seismic effects.

According to its electrophysical properties, NGZ can be represented as an electric capacitor, the upper which is a well-conductive tire, and the bottom is a layer of mineralized water (FIG.Z).

 Between these plates is a dielectric - oil and gas fluid (zones 1-3), capable of polarizing electrically, thereby accumulating electrical energy.

 Zone 4 is inherently an electrochemical pseudo-dielectric capable of storing electrical energy by separating and moving charges in double electric layers along the walls of the capillaries of the collector.

 Thus, NGZ is a kind of accumulator of electric energy and can accumulate it the more, the greater the intensity of the polarizing electric field between the formation cover and the zone of mineralized water, and the more the volume of oil and gas fluid is in the zone of influence of the polarizing electric field.

 If such a peculiar capacitor is charged with a powerful polarizing electric field, and then with a seismic action, cause the oriented movement of electrically polarized particles of oil and gas fluid in the capillaries, micropores and microcracks of the host reservoir rock, then an electric current will be generated in the NGD and the excitation of a secondary EMF in the surrounding NGS medium, which is instantly recorded on the day surface in the form of a NGS response.

The phase-frequency characteristics of the low-frequency (1-GHz) seismic impact when passing through sedimentary rocks practically do not undergo changes. When the seismic wave reaches NGZ and As it passes through the NGZ layers, a pronounced dispersion of its phase velocity is observed. Under the condition of preliminary polarization of the NGD by an electric field, changes in the phase response of the seismic effect are instantly reflected in the phase response of the NGZ response.

 The magnitude of the phase shifts between the spectral components of the initial seismic action and the NGS response, as well as the magnitude of the time shifts between the leading edges of the initial seismic effect and the NHS response at a known propagation velocity of the seismic wave in sedimentary rocks in the studied geological section, allow us to determine the distance passed by the seismic wave before the change in its phase response.

 The principle of detecting NGD and determining the depth of occurrence of NGD in the MFZ method is based on these properties.

Seismic action with a frequency of 1-5 Hz causes the most significant displacements of all particles of oil and gas fluid in the capillaries of the host reservoir rock. Moreover, in the frequency range of 1-50 Hz with a 3-fold change in frequency, the dispersion of the phase velocity of the seismic wave can reach 10%. The greater the power of the NGS and the more free and dissolved in oil gas is in it, the more the phase response of the seismic wave passing through the layers of the GNZ changes, and the more the phase response of the NGZ response and the reference phase response of the initial seismic effect are different. After the seismic wave passes through all the layers of the NGZ and its further propagation deep into the sedimentary rocks, the NGZ response is not observed. The principle of determining the capacity of NGDs in the MPF method is based on these properties.

 Oil and gas fluid particles vary significantly in size and therefore have different inertia. With an increase in the frequency of seismic impact, the amplitude of displacement of the largest and most inertial (oil) particles of oil and gas fluid decreases first of all, therefore, the movement of polarized particles in the oil zone is sequentially excluded from the formation of the NGS response, and then in the zone of oil with dissolved gas. When the seismic frequency reaches a value of 15–20 Hz, the movement of the most inertial (oil) particles of the fluid stops; only the low-inertia (gas) particles of the fluid and the phase shift between the harmonics of the NGZ response are involved in the formation of the NGS response at these frequencies it has a direct dependence on the volume of free gas in the NGZ.

 Based on these properties, the principle of determining the ratio in the oil / gas free gas condensate in the MPZ method is based.

 In real environmental conditions, capillaries, microcracks and micropores of the reservoir rock are not strictly vertically oriented, and as a result of movements of the earth's crust they can be arbitrarily oriented (FIG. 4) - up to 50-60 degrees from the vertical in any direction.

Therefore, a polarizing electric field must be formed in a three-component manner, with the possibility of adjusting its spatial configuration and changing electric cops (the product of the length of the supply line by the current in it) of each supply line AB. For this, when implementing the method, a three-dimensional configuration of the electric field is used due to the use of three mutually perpendicular supply lines, two of which are deployed in the horizontal plane, forming a cross, and the third is deployed vertically downward from the intersection of two horizontal ones.

 The seismic effect moves the particles of oil and gas fluid through the capillaries, microcracks and between individual micropores of the collector in the direction coinciding with the directions of the seismic action propagating from the day surface from the IAA in the direction of the NGZ. Therefore, the seismic effect must also have a three-dimensional configuration. To do this, when implementing the method, several (two or three) spatially separated IAAs are used, working coherently.

 These conditions determine the configuration of the supply lines and seismic effects in specific embodiments of the method.

 The physical fields used in the MFZ method are subdivided into acting and information fields (FIG. 5).

1. The generated polarizing electric field is an acting physical field. Under its influence, the particles of the oil and gas fluid are able to polarize electrically and, thus, the gas condensate can store electric energy in the form of electric charges. 2. The generated seismic effect is also an affecting physical field, because, passing through the layers of the gas condensate, it causes an oriented movement of the pre-electrically polarized particles of oil and gas fluid in the capillaries, micropores and microcracks of the host reservoir rock, as a result of which electric current is generated in the gas condensate and excitation secondary EMF in the environment of NGZ.

 3. The secondary EMF is an informational physical field, since the phase response of the NGZ response unambiguously reflects the change in the phase response of the seismic effect passing through the layers of the NGZ.

 To solve the set prospecting and exploration tasks by the MFZ method, various PRK are used, differing in the geometry of the supplying AV and receiving MN lines and the location of the IAA, for the most efficient use of the above-described influencing and informational physical fields.

 In accordance with the foregoing, the achievement of the indicated technical result is ensured in the claimed method by performing basic operations - electrical polarization of the non-hazardous object, seismic action on the non-hazardous object, registration of the components of the non-hazardous object responses and processing of the data obtained in the four stages - preparation, searches, detailed intelligence and descriptions, the functional diagram of which is clearly reflected in FIG.6.

 Let us explain the steps of FIG.6 in the following example.

1st Stage - Preparation. 1.1. Occupation of the starting position.

 1.2. GTRK deployment.

 At the end of the 1st Stage, it is necessary to coordinate the PRK in a given geographical area. The anchor points fix the location of the AIC and PM, the geometry and orientation of the supply and receiving lines. Coordinate data are necessary when forming a profile grid for contouring the detected NGD.

 2nd Stage - Searches.

 2.1. Electric polarization - creation of an electric field of a three-dimensional spatial configuration with stable amplitude-phase spectra in the studied geological section for the electric polarization of the gas condensate separation.

 The polarizing electric field of the ST configuration is created by three mutually perpendicular supply lines AB, two of which (AXBX and AYBY) are deployed in a horizontal plane, forming a symmetrical cross, each connected to the generator block “in gap” into two symmetrical arms along one line, and the third (AZBZ) is connected to the generator unit in one shoulder and placed vertically down from the intersection of two horizontal (FIG.7).

2.2. Seismic impact is a periodic multi-frequency seismic effect of three-dimensional spatial configuration with stable amplitude-phase spectra in the studied geological section. The seismic effect of the ZE configuration is created through the use of several (two or three) spatially separated IAAs working coherently. The main DUT is located stationary at the intersection of the supplying AV and receiving M lines, additional DUTs are located at the PM.

 2.3. Reception and registration of data.

 Reception and registration on the day surface of the electric (E) and magnetic (H) components of the NGZ response, reflecting the change in the phase response of the seismic wave passing through the NGZ layers.

 Reception and registration of electrical (EX, EY, EZ) components

The NGZ response is carried out by receivers of electrical components from 3 to 24 in number for each arm of each of the receiving lines (FIG. 8-1 1).

 For this, three mutually perpendicular receiving lines MN are arranged, two of which (MXNX and MYNY) are placed in the horizontal plane, forming a symmetrical cross coaxially with the supply lines AXBX and AYBY, each connected to the receiving and measuring unit “in gap” in two symmetrical arms and the third (MZNZ) is connected to the receiving and measuring unit in one shoulder and placed vertically downward coaxially with the supply line AZBZ from the intersection of two horizontal ones (FIG. 7).

Reception and registration of magnetic (HZ, HY, HZ) components of the NGD response is carried out using several (two or three) three-component magnetometers. The main magnetometer is stationary at the intersection of the supply and reception lines, additional magnetometers are located on the PM. To eliminate the interference caused by vibrations, magnetometers are placed on platforms stabilized by gyroscopes.

 2.4. NGZ detection.

 The presence of NGS in the studied geological section is detected when an abnormal (exceeding the measured value of the background over the areas without anomalies) phase difference is detected between the different frequencies (for example, the 1st and 3rd) harmonics of the NGZ response and taken as reference different frequencies ( for example, 1st and 3rd) harmonics of the initial seismic impact,

 Stage 3 - Detailed Intelligence.

 3.1. Move PM on profiles.

 PM move along the specified research profiles in order to carry out auxiliary seismic impact in order to provide the possibility of creating the GZ-configuration of the seismic impact.

 3.2. Electric polarization according to clause 2.1.

 3.3. Seismic impact - according to paragraph 2.2.

 At the 3rd Stage, seismic action is carried out both at a frequency of 1 Hz, and with a sequential change in the frequency of seismic action in the operating frequency range of 1-30 Hz in steps of 1 Hz.

 3.4. Reception and registration of data - according to clause 2.3.

 3.5. Accumulation of an array of data.

Accumulation of an array of data on the values of phase shifts between the 1st harmonic of the initial seismic impact and the 1st harmonic of the NGD response and the values of phase shifts between, for example, the 1st and 3rd harmonics of the initial seismic impact and the 1st and 3rd harmonics of the NGD response over the entire investigated area in the operating frequency range of the seismic impact.

 4th Stage - Description.

 4.1. Interpretation of data.

 Interpretation of the accumulated data array according to clause 3.5. in order to determine the parameters of the detected NGZ.

 4.2. Determination of the depth of NGZ.

 It is carried out by measuring and interpreting data on the values of phase shifts Δφη between the 1st harmonic of the initial seismic action and the 1st harmonic of the NGD response at the known propagation velocity of the seismic wave in sedimentary rocks in the studied geological section.

 Determination of the depth of the NGZ is carried out by the E- and H-components of the NGZ response using identical phase-measuring devices for determining the depth of occurrence (FMU-G), one for each of the components. In this case, the E-components of the NGZ response arrive at the FMU-G input from the receiving lines ΜΝ, and the H-components of the NGS response arrive at the FMU-G input from the three-component magnetometer (FIG. 12-13).

At the first (reference) input of the FMU-G, voltage is supplied from the seismic receiver (SP) located near the main IAA, which, through the input filter with a passband of 0.5-30 Hz, enters a large-scale amplifier covered by a circuit for instantaneous automatic gain control (MARU ), the output voltage of which is normalized and maintained equal to 1, 0 ± 0.05 V, after which it enters a software-tunable digital filter that selects the voltage with a frequency of the 1st harmonic and feeds it to the reference input of the digital phase meter.

 The second (informational) input of FMU-G is supplied with voltage with a frequency of the 1st harmonic of the NGD response, which is obtained by summing all the components of the NGD response after preliminary filtering using an input filter, normalizing at the level of 1.0 ± 0 , 05V and final narrow-band filtering using a tunable digital filter. The phase shift Δφη measured in this way is strictly proportional to the time of passage of the seismic wave from the IAA to the NGZ plus the time of the passage of the seismic wave through the NGZ layers.

 To determine the depth of the NGZ, it is necessary to know the phase velocity of the seismic wave in the sedimentary rocks of the upper part of the geological section and the average thickness of the NGZ, which should be subtracted from the resulting total depth during subsequent processing.

 In this case, it is necessary to verify that there is no anomalous effect of the dispersion of the phase velocity of the seismic wave in sedimentary rocks over the NGZ. For this, an additional measurement of the depth of the NGD at a frequency, for example, of the 3rd harmonic, is carried out and the results are averaged.

Keep in mind that phase meters measure phase shifts in the range of 0-360 degrees. Therefore, if the phase shift is, for example, 363 degrees, the phase meter will give a reading of 3 degrees. This can be observed when the depth of the NGZ is greater than wavelength of the 1st harmonic of seismic impact. For example, with a depth of 4625 m and an average velocity of the seismic wave of 2200 m / s:

 2200x2 = 4400 m + 225 m, i.e. 360x2 = 720 + 45 degrees, the phase meter readings will be equal to 45 degrees, and correspond to an apparent depth of about 225 m.

 Therefore, in the FMU-G method used in the MFZ method, working on the principle of measuring time intervals, an output signal (N3600) is provided that displays the total number of phase shift cycles by 360 degrees, which eliminates the ambiguity in determining the phase shift Δφη.

 4.3. Determination of NGZ power.

 It is carried out by measuring and interpreting data on the values of phase shifts Δφ between, for example, the 1st and 3rd harmonics of the initial seismic effect and the 1st and 3rd harmonics of the NGD response, arising due to the dispersion of the seismic phase velocity waves as it passes through NGZ strata.

 Determination of the power of the NGD is carried out by the E- and H-components of the NGD response using identical phasemetric power determination devices (FMU-M), one for each of the components. In this case, the E-components of the NGZ response arrive at the FMU-M input from the receiving lines ΜΝ, and the H-components of the NGZ response arrive at the FMU-M input from the three-component magnetometer (FIG. 14-15).

FMU-M is made according to an analog-digital circuit: an active filter with a passband of 0.5-30 Hz is installed at the input, after which an adjustable scale amplifier is included, covered by the MARU digital circuit, which maintains the amplitude of the output signal at the level of 1.0 ± 0.05 V when the input signal level changes within 1 μV-1 mV. Then this amplitude-normalized signal is fed to the inputs of narrow-band software tunable digital filters, tuned, respectively, to the 1st and 3rd harmonics of the NGZ response. Three times the analog-to-digital frequency multiplier is connected to the output of a digital filter tuned to the 1st harmonic of the NGD response. Therefore, voltages with the same frequency equal to the frequency of the 3rd harmonic of the NGZ response are supplied to the inputs of the digital phase meter, as a result of which the phase shift count Δφ between the 1st and 3rd harmonics of the NGZ response appears on the phasemeter output indicator.

 In each of the FMU-M, three channels are organized (channel X, channel Υ and channel для) for measuring the phase shift Δφ for each of the electrical (EX, ΕΥ and ΕΖ) and magnetic (HX, ΗΥ and Н) components of the NGZ- response (ΔφΧ, ΔφΥ, ΔφΖ), and the result is averaged by calculating the root mean square value as the square root of the sum of the squares of all six readings.

 The value of this averaged phase shift is programmatically recalculated into the averaged power of the NGD, taking into account the knowledge of the phase velocity for the frequency of the 1st harmonic.

4.4. Determination of oil / free gas ratio in NGZ. It is carried out by measuring and interpreting data on the values of phase shifts Δφ between, for example, the 1st and 3rd harmonics of the initial seismic effect and the 1st and 3rd harmonics The NGS response arising due to the dispersion of the phase velocity of the seismic wave during its propagation through the NGZ layers, with a sequential change in the frequency of the seismic action in the frequency range 1-30 Hz in steps of 1 Hz.

 The oil / free gas ratio in the NGZ is determined by the E- and H-components of the NGZ response using the identical FMU-M, one for each of the components. In this case, the E-components of the NGZ response are fed to the input of the FMU-M from the receiving lines MN, and the H-components of the NGZ response are fed to the input of the FMU-M from a three-component magnetometer (FIG. 14-15).

 4.5. Description of NGZ.

 Processing and analysis of the accumulated data array, a description of the characteristics and parameters of the detected NGD and the formation of maps, sections, 2D and ST models of NGD. At the same time, the monitoring of residual reserves in the exploited NGZ is carried out on the NGZ studied and described earlier, therefore, the search stage is excluded from the list of the stages to be performed, and after the preparation stage they proceed to the detailed exploration and description stages.

The achievement of the indicated technical result is also provided in the declared GTRK for the implementation of the described method, the structural diagram of which is shown in FIG. 16.

In practice, the claimed method is carried out using GTRK, consisting of the main set of equipment and software - AIC, an auxiliary set of equipment software and tools - basically one or two PM, supply lines AB and receiving lines MN, made in the form of a set of purposefully interconnected specialized functional units, with which, in an automated mode, they realize a sequence of operational tion of the method.

 The hardware-software complex (AIC) (the main set of equipment) performs the main seismic impact, receives and registers the E- and H-components of the NGZ response, controls the operation of the PM, receives data from the PM, and stores an array of data measurements, processing, analysis and interpretation of measurement data, its own coordinate reference using GPS / GLONASS systems, and functionally consists of three blocks:

 - Control and processing unit (BWO);

 - Generator unit (GB);

 - Receiving and measuring unit (PIB).

 The control and processing unit (BUO) implements:

 - GB operation management;

 - management of the main IAA;

 - management of the PIB;

 - PM work management;

 - accumulation, processing, analysis and interpretation of data obtained from PIB and PM;

 - coordinate reference of the agricultural sector using GPS / GLONASS systems;

and includes: - main computer (РСО, Master-PC);

 - a set of transmitting and receiving equipment (PAP) for communication and control of the PM;

 - receiver of the coordinate reference system.

 The generator unit (GB) provides power to the AIC, power lines AB, the main DUT and includes:

 - electric generator;

 - transformer;

 - three controlled rectifiers;

 - three controlled pulse generators;

 - generator of elastic vibrations;

 - The main IAA.

 The receiving and measuring unit (PIB) receives and registers the E- and H-components of the NGZ response and includes:

 - two FMU-G (FIG 12-13);

 - two FMU-M (FIG.14-15);

 - a three-component magnetometer for receiving the H-component of the NGZ response;

 - a seismic receiver for determining the initial (accepted as reference) parameters of the initial seismic impact from the main IAA.

The mobile module (PM) (auxiliary set of equipment) provides auxiliary seismic effects, reception and registration of the H-component of the NGZ response, its own coordinate reference using GPS / GLONASS systems, transmission received data on the agro-industrial complex and functionally consists of three blocks:

 - Control and processing unit (BUO-PM);

 - Generator block (GB-PM);

 - Receiving and measuring unit (PIB-PM).

 The control and processing unit (BUO-PM) carries out:

 - GB-PM operation management;

 - management of the auxiliary IAA;

 - PIB-PM work management;

 - transfer to the AIC of data received from PIB-PM;

 - PM coordinates using GPS / GLONASS systems;

 and includes:

 - auxiliary computer (PCB, Slave-PC);

 - generator of elastic vibrations;

 - auxiliary IAA working coherently with the main

IAA;

 - a seismic receiver for determining the initial (accepted as reference) parameters of the seismic impact from the auxiliary IAA;

 - a three-component magnetometer for receiving the H-component of the NGZ response;

 - FMU-G (FIG.13);

 - FMU-M (FIG. 15);

 - A set of PAP for communication and control with the agro-industrial complex;

- receiver of the coordinate reference system. Using these devices, they carry out a targeted integrated effect on physical gas fields of different fields (electrical and seismic), register and process the incoming data on the measurement results of the phase response of the NGZ response and the results of their comparison with the reference phase response of the initial seismic effect to form a database reflecting the main parameters of the study NGZ.

 Depending on the tasks and the conditions of the work, the following state television and radio programs are provided,

 X-shaped PRK.

 It differs from FIG. 7 as follows (FIG. 17):

 - the configuration of polarizing electric fields is achieved through the use of two mutually perpendicular supply lines (AXBX and AYBY), which are placed in the horizontal plane, forming a symmetrical cross, each connected to the generator block “in gap” into two symmetrical arms on one line;

 - two mutually perpendicular horizontal receiving lines (MXNX and MYNY) are used, which are placed in the horizontal plane, forming a symmetrical cross coaxially with the supply lines, each connected to the receiving and measuring unit “into the gap” in two symmetrical arms, one at a time lines.

 This PRK can be used to search for NGZ on land and in shallow water (with bottom depths of up to 30 m).

It is implemented in land and sea versions. In the land version, the supply and reception lines are located on the surface of the earth, the agro-industrial complex and the PM are located on the automobile chassis.

 In the maritime version, the supply and reception lines are located directly at the bottom, the agro-industrial complex is located on the main vessel, PM are placed on auxiliary vessels.

 V-shaped GTRK.

 Differs from FIG. 7 as follows (FIG. 18):

- the configuration of polarizing electric fields is achieved in _. due to the use of two mutually perpendicular supply lines (AXBX and AYBY), which are placed in a horizontal plane from one point, each connected to the generator unit in one shoulder;

 - two mutually perpendicular receiving lines (MXNX and MYNY) are used, which are placed in a horizontal plane from one point coaxially with the supply lines, each connected to the receiving and measuring unit in one shoulder.

 This GTRK can be used to search for NGZ on land and in shallow water (with a bottom depth of up to 30 m).

 It is implemented in land and sea versions.

 In the land version, the supply and reception lines are located on the surface of the earth, the agro-industrial complex and the PM are located on the automobile chassis.

In the maritime version, the supply and reception lines are located directly at the bottom, the AIC is located on the main vessel, the PM is located on the auxiliary vessel. Linear two-shoulder GTRK.

 Differs from FIG. 7 as follows (FIG. 19):

 - the configuration of polarizing electric fields is achieved through the use of one horizontal supply line (AHVX), which is placed in a horizontal plane along one line and connected to the generator unit “in gap” in two symmetrical arms;

 - one horizontal receiving line (MXNX) is used which is placed in a horizontal plane along one line coaxially with the supply line and connected to the generator unit “in a gap” in two symmetrical arms.

 This GTRK can be used for detailed exploration of discovered NGZs and monitoring reserves in operating NGZs on land and in shallow water (with bottom depths of up to 30 m).

 It is implemented in land and sea versions.

 In the land version, the supply and reception lines are located on the surface of the earth, the agro-industrial complex and the PM are located on the automobile chassis.

 In the maritime version, the supply and reception lines are located directly at the bottom, the agro-industrial complex is located on the main vessel, PM are placed on auxiliary vessels.

 L-shaped GTRK.

 Differs from FIG. 7 as follows (FIG. 20):

- the configuration of polarizing electric fields is achieved through the use of two mutually perpendicular supply lines (AHVX and AZBZ), which are placed in a vertical planes from one point, each connected to the generator unit in one shoulder, one of which (AHVX) is located horizontally, and the other (AZBZ) - vertically downward;

 - two mutually perpendicular receiving lines (MXNX and MZNZ) are used, which are placed in a vertical plane from one point with the supply lines, each connected to the receiving and measuring unit in one shoulder, one of which (MXNX) is horizontally aligned AHVH supply line, and the other (MZNZ) - vertically down.

 This PRK can be used to search for NGZ in marine areas (with bottom depths of up to 3 km), including those in areas with constant ice cover.

 The horizontal supply and reception lines are located on the sea surface (in the ice version - under the sea surface at depths of at least 10-15 meters) and towed by the main vessel, the vertical supply and reception lines are immersed in water. AIC is located on the main vessel, PM is located on the auxiliary vessel. In the ice version, PM is not provided.

 Linear single-shoulder PRK.

 Differs from FIG. 7 as follows (FIG. 21):

- the configuration of the polarizing electric field is achieved through the use of one horizontal supply line (AHVX), which is connected to the generator unit in one arm. - one horizontal receiving line (MXNX) is used, which is connected to the receiving and measuring unit in one shoulder and placed from one point with the supply line aligned with it.

 This GTRK can be used to search for NGZ in marine areas (with bottom depths of up to 300 m), including those in areas with a constant ice cover.

 The horizontal supply and reception lines are located on the sea surface (in the ice version - under the sea surface at a depth of at least 10-15 meters) and are towed by the main vessel. AIC is located on the main vessel, PM is located on the auxiliary vessel. In the ice version, PM is not provided.

 Industrial Applicability and Achievement

 technical result.

Thus, as follows from the foregoing, the features indicated in the claims are essential and purposefully interrelated with each other with the formation of their stable combination, necessary and sufficient to obtain the specified technical result. The achieved technical result, as shown by the experimental data, can only be realized by an interconnected set of all the essential features of the claimed objects reflected in the claims. The claimed significant distinguishing features were obtained on the basis of creative processing of the results of studies and experiments, analysis and generalization of them and data from well-known published sources, interconnected to achieve the technical result indicated in the application, as well as using inventive intuition.

 The proposed method does not contain operations that cannot be implemented using known technologies, in particular, computer processing of information. Compliance with the criterion of “industrial applicability” of the proposed facilities is also proved by the absence in the claimed claims of any signs that are practically difficult to realize on an industrial scale.

 In addition to the technical result indicated above, the practical application of the proposed invention also allows for further improvement of the methods of prospecting and exploration of gas reserves, in particular with respect to saving time and financial costs when monitoring residual reserves in exploited gas reserves.

Claims

CLAIM

1. Method of multi-frequency phase sounding (MFZ-5 method) for searching and detailed exploration of oil and gas deposits (OGD), including the following steps, during which the OGZ is electrically polarized by creating an electric field of a three-dimensional spatial configuration and a stable amplitude-phase spectrum , purposefully carry out with the help of sources of elastic (seismic) vibrations (IUS) a multi-frequency seismic effect of a three-dimensional spatial configuration with stable amplitude-phase spectra, which influence the NGZ; as a result of the complex influence of the indicated physical fields, they initiate an electrical

15 tric polarization and the subsequent movement of oil and gas fluid particles in capillaries, micropores and microcracks of the reservoir rock, thereby forming an electromagnetic field (NGZ response) adequate to these influences in the OGZ and its surrounding environment, measuring and recording the parameters of the formed ta-

20 how the OGZ response displays the change in the main phase-frequency characteristics (PFC) of the spectrum of a seismic wave when passing through the OGZ, when an anomalous phase difference between different frequencies is detected, exceeding the measured background value over areas without anomalies ( 1 - th and 2 7th) harmonics

25 OGZ response and initial, accepted as reference, multi-frequency (1st and 2nd + 7th) harmonics of seismic impact, regi-

SUBSTITUTE SHEET (RULE 26) Straight out the presence of oil-gas reserves in the studied geological section, then repeat the above operations along profiles within the study area and form a database of measured parameters of oil-gas reserve responses to determine the depth of occurrence, the thickness of the oil-gas reserve and the oil/free gas ratio in the oil-gas zone, analyzing and performing a geological and geophysical interpretation of the obtained data, they form a set of computer codes adequate to them, while determining the characteristics and parameters of the studied oil and gas zone, on the basis of which 2D and 3D graphic images of maps, sections, 3D models of oil and gas zones are formed, if necessary repeat the above described set of operations.

2. The method according to claim 1, in which, to determine the depth of the OGZ, the obtained data on the magnitude of phase shifts between the 1st harmonic of the initial seismic impact and the 1st harmonic of the OGZ response are measured and interpreted to clarify the desired As a result, time shifts are additionally measured between the leading edges of the initial seismic impact and the non-seismic response at a known speed of propagation of the seismic wave in the studied geological section.

3. The method according to claim 1, in which, to determine the power of the OGZ, the obtained data on changes in the values of phase shifts between the 1st and 2nd-^-7th harmonics in the OGZ response relative to their values in the original seismic response are measured and interpreted. - actions arising due to the dispersion of the phase velocity of a seismic wave as it passes through the NGZ.

SUBSTITUTE SHEET (RULE 26)

4. The method according to claim 1, in which, to determine the oil/free gas ratio in the OGZ, the obtained data on changes in the values of phase shifts between the 1st and 2 7th harmonics in the OGZ response is measured and interpreted relative to their values in the -

5 moving seismic impact, arising due to the dispersion of the phase velocity of the seismic wave as it passes through the NGZ, with sequential seismic impact in the frequency range 1-30 Hz in steps of 1-5 Hz.

5. Search and exploration complex (PR) for implementing the method according to claim 1, containing a hardware-software complex (HSC) interconnected by receiving and transmitting equipment (RPE) and selected mobile modules (PM) in an amount from one to twelve ), each of which is composed of interconnected control and information processing units

15 (BUO), including an auxiliary computer (RSV) and a coordinate reference system (GPS), a receiving and measuring unit (RIB), including a seismic receiver (SR), a three-component magnetometer, a phase-metric device for determining the depth of the NGZ (FMU-G) using magnetic ( HX, HY and HZ) components

20 there is an OGZ response, a phase-metric device for determining the power of an OGZ and the oil/free gas ratio in an OGZ (FMU-M) using the magnetic (HX, HY and HZ) components of the OGZ response, a generator unit (GB) including an electric generator , generator of elastic vibrations, source of elastic vibrations (IUS), while APC

25 is composed of interconnected control and information processing units (CUU), including the main computer

SUBSTITUTE SHEET (RULE 26) (PCO) and coordinate reference system (GPS), a generator unit (GB), including an electric generator, a transformer, three pulse generators, one for each of the supply lines (AB), connected to the transformer through controlled rectifiers, an elastic generator vibrations, a source of elastic vibrations (IUS), three mutually perpendicular supply lines (AB), two of which (АХВХ and AYBY) are placed in a horizontal plane, forming a symmetrical cross, each connected to the generator unit “in a gap” in two symmetrical arms, and the third (AZBZ) is connected to the generator block in one arm and is placed vertically down from the intersection of two horizontal ones, a receiving and measuring unit (RIB), including a seismic receiver (SR), a three-component magnetometer, and a phase-metric device determination of the depth of the oil-gas reserve (FMU-G) using the magnetic (НХ, HY and HZ) components of the oil-gas response, a phase-metric device for determining the power of the oil-gas zone and the oil/free gas ratio in the oil-gas zone (FMU-M) using the magnetic (НХ, HY and HZ) components of the OGZ response, a phase-metric device for determining the depth of the OGZ (FMU-G) from the electrical (EX, EY and EZ) components of the OGZ response, a phase-metric device for determining the power of the OGZ and the oil/free gas ratio in NGZ (FMU-M) according to the electrical (EX, EY and EZ) components of the NGZ response, three mutually perpendicular receiving lines (MN), two of which (MXNX and MYNY) are located in the horizontal plane, forming a symmetrical cross coaxially feeding main lines АХВХ and AYBY, each connected to the

SUBSTITUTE SHEET (RULE 26) the receiving and measuring unit “in a gap” in two symmetrical arms, and the third (MZNZ) is connected to the receiving and measuring unit in one arm and is placed vertically down coaxially with the supply line AZBZ from the intersection of two horizontal ones, and to each arm of each From the receiving lines (MN) from 3 to 24 meters of electrical field components are connected.

6·. The complex according to claim 5, in which two mutually perpendicular supply lines (АХВХ and AYBY) are placed in a horizontal plane, forming a symmetrical cross, each is connected to the generator unit “in a gap” into two symmetrical arms, and two mutually perpendicular receiving lines (MXNX and ΜΎΝΥ) are placed in a horizontal plane, forming a symmetrical cross coaxially with the supply lines АХВХ and AYBY, each connected to the receiving and measuring unit “in a gap” in

15 two symmetrical shoulders.

7. The complex according to claim 5, in which two mutually perpendicular supply lines (АХВХ and AYBY) are placed in a horizontal plane from one point, each connected to the generator unit in one arm, and two mutually perpendicular receiving

20 lines (MXNX and MYNY) are placed in a horizontal plane from one point coaxially with the supply lines, each connected to a receiving and measuring unit in one arm.

8. The complex according to claim 5, in which one supply line (АХВХ) is placed in a horizontal plane along one line and connected

25 is connected to the generator block “in a gap” in two symmetrical arms, and one receiving line (MXNX) is placed in a horizontal plane

SUBSTITUTE SHEET (RULE 26) bone along one line coaxially with the supply line and is connected to the receiving and measuring unit “in a gap” into two symmetrical arms.

9. The complex according to claim 5, in which two mutually perpendicular 5 supply lines (АХВХ and AZBZ) are placed in a vertical plane from one point, each connected to the generator unit in one arm, one of which (АХВХ) is located horizontally, and the other (AZBZ) - vertically down, and two mutually perpendicular receiving lines (MXNX and MZNZ) are placed in the 10 vertical plane from one point with supply lines, each connected to a receiving and measuring unit in one arm, one of which (MXNX) is located horizontally coaxially with the supply line АХВХ, and the other (MZNZ) is located vertically downwards.

10. The complex according to claim 5, in which one horizontal supply line (АХВХ) is connected to the generator unit in one arm and one horizontal receiving line (MXNX) is connected to the receiving and measuring unit in one arm and is placed from one points with the supply line coaxial to it.

1 1. The complex according to claim 5, in the APC and PM of which three 20 or four phase-metric devices for determining the depth of the NGZ (FMU-G) are used to implement the method according to claim 2, each of which includes three input filters for each of electrical (ΕΧ,ΕΥ,ΕΖ) and magnetic (ΗΧ,ΗΥ,ΗΖ) components of the NGZ response, an adder, two scale amplifiers (reference and information input), covered by an instantaneous automatic

SUBSTITUTE SHEET (RULE 26) gain control (MARU), two digital filters, two pulse shapers, a time interval meter and a phase meter.

12. The complex according to claim 5, in the APC and PM of which three or four phase-metric devices are used to determine the power of 5 NGZ and the oil/free gas ratio in the NGZ (FMU-M) to implement the methods according to paragraphs 3, 4, each of which includes three measurement channels (channel X, channel Y and channel Z), one for each of the electrical (EX, EY, EZ) and magnetic (HX, HY, HZ) components of the NGZ response, and each The channels include an input filter, a scale amplifier covered by a MARU circuit, two digital filters, a frequency multiplier and a phase meter.

SUBSTITUTE SHEET (RULE 26)