RU2690089C1 - Method of detecting and mapping fluid-saturated anisotropic cavernous-fracture reservoirs in inter-salt carbonate formations of a sedimentary cover - Google Patents

Abstract

FIELD: geophysics.SUBSTANCE: invention relates to the field of seismic exploration and can be used for mapping of complex fluid-saturated fractured-cavernous zones, with AHPP of fluids in geologic section of sedimentary cover of platforms and areas of their connection with marginal troughs. During excitation and registration of seismic signal of CDPM, data are processed with maximum attenuation of interference and ensuring preservation of primary seismic field, with separation of scattered component. Besides, energy and spectral characteristics, as well as degree of irregularity of scattered component seismic signals are determined. According to abnormal values of said parameters, fracture-cavernous zones with different degree of fracturing and cavernousness are selected. Inter-salt fluid-saturated reservoirs are a special prediction object, the geological structure of which is fundamentally different from massive fracture reservoirs, and is therefore characterized by special effects of reflection and recording in the wave field.EFFECT: improving reliability of prediction of complex fluid-saturated fractured-cavernous zones, with abnormally high bed pressure of fluids in halogen-carbonate sequences of geological section of sedimentary cover of platforms and areas of their connection with marginal troughs, which complicate drilling at different stages and stages of geological prospecting process.1 cl, 6 dwg

Description

The field of technology.

The invention relates to the field of seismic exploration, and can be used to identify and map the fluid-intersalt anisotropic cavern-fractured reservoirs with a wide range of permeability, from abnormally high formation pressures (AVPD) fluids in the geological section of a sedimentary cover platforms and their areas of articulation with foredeeps .

The level of technology.

As a result of carrying out seismic data using the common depth point method (MCT), processed according to a standard graph, it is almost impossible to detect and execute a forecast forecast of intervals (fractured-cavern and porous-fractured types) with high reservoir properties in most fields. sizes of caverns and cracks. Even more difficult is the prediction of heterophase fluid systems distributed in the fracture type of the void space of a natural reservoir, often complicated by AHF fluid. In particular, in the south of the Siberian platform, drilling at depths of 1.2-2.2 km revealed the presence of a halogen-carbonate formation of rapogenous saturated reservoir formations of fracture and cavern-fracture type in the geological section, in which the reservoir fluid pressures are 2.3 -2.6 times the hydrostatic, i.e. are abnormally high (Vakhromeev AG. Patterns of formation and localization of deposits of industrial brines in carbonate cavern-fracture reservoirs of the Cambrian south of the Siberian platform (according to deep drilling, well testing and field geophysics): Monograph. - Irkutsk: IrNTU Publishing House, 2015 - 248 s).

The known method proposed Dyakonov B.P., Kuznetsov O.L. et al. (Patent of the Russian Federation No. 2008697, 1991) uses diffracted seismic waves to detect areas with increased fracture in the geological environment, based on the theory of side-scan locators (LBO). This method can be implemented only when performing a special complex of field work, with special processing of seismic materials, which significantly increases financial costs.

The known method of seismic exploration of rocks (Patent RF №2251717, 2004), which is the prototype of the LBO (RF Patent №20069697, 1991). This method differs from the previous one in changing the method of field observations - it is proposed to have a reception aperture and a radiation aperture in pairs from two sides of the studied volume of rocks. With this method, the scanning of the medium occurs in two orthogonal directions, which makes it possible to distinguish zones with different orientation of cracks. To isolate waves with a lower intensity, as compared to regular waves and interference waves, one has to carry out a large number of accumulations of the useful signal. This requires a sufficiently large number of points of arousal and reception points. The multiplicity of accumulations can reach 10,000. However, this method can also be used only after carrying out field work, with special placement of sources and receivers.

A known method of searching for hydrocarbon deposits confined to fractured cavern reservoirs (Patent of the Russian Federation No. 2451951, 2005). This method describes the identification and assessment of the quality of fractured cavern reservoirs, which consists in the special processing of standard seismic survey data CDP with obtaining a full wave field containing the reflected and diffracted waves. When processing data, two cubes of seismic data are obtained: the migrated cube of reflected waves (reflectors) and the cube of diffracted waves (diffractors), while the cube of diffractors is obtained by subtracting the reflected waves and subsequent focusing of the scattered waves (RV), and using the diffractors cube, amplitude and spectral attributes are calculated seismic field, then the integral amplitude characteristics get a three-dimensional model of the scattering objects of the geological environment (cube index of acoustic inhomogeneity), and by means of By jointly interpreting the migrated cube of reflectors and the cube of the acoustic inhomogeneity index, we obtain the distribution of the instantaneous amplitudes of RW waves over the cross section of the cube in intervals corresponding to the studied productive levels of the geological section. The disadvantage of this method is that when subtracting the reflected waves do not carry out the identification of the type of subtracted waves on the means of modeling, or identification with the data of vertical seismic profiling (VSP). Since the reflected waves can also be attributed, and diffracted waves with significant propagation energy and weak energy RS. In addition, this method involves initially focusing RT transformations and only up to the summation stage, then data summation, and only then the conversion result is converted into seismic attributes.

The method described in the patent of the Russian Federation №2451951 implies initially recalculating radioactive substances into seismic attributes with subsequent focusing of data both prior to the summation stage and according to the total data. This approach allows to focus the energy of radioactive substances not only from strong emitters, but also from relatively weak ones (associated, for example, with increased reservoir porosity). And the method of focusing on aggregate data allows processing in a relatively short time, which will save machine costs and the cost of processing itself. The results of processing using the procedures of focusing summary data are often quite comparable, and in some cases they are not inferior to the results of preliminary specialized processing.

The closest is the method of seismic exploration of massive geological rocks (RF patent №2168187, 2001), in which a seismic signal is excited, and recorded by standard methods based on the technique of multiple overlaps (Meshbey VI. The technique of multiple overlaps in seismic exploration - M .: Nedra , 1985. - 264 p.). Seismic data is processed with maximum attenuation and ensuring the preservation of the primary seismic field, with the release of the scattered component, by additional suppression of regular reflected and multiple waves. In addition, they determine the energy and spectral characteristics, as well as the degree of irregularity of the seismic signals of the scattered component. According to the anomalous values of these parameters, fracture-cavernous zones are distinguished. This method has the disadvantage that the processing does not use focusing procedures in the allocation of scattered waves, therefore, it is unlikely to identify areas with minor fracture and cavernism in this way. Especially if these target zones are located in the middle part of the section and are overlapped to varying degrees by stationed strata, in which the acoustic properties change dramatically both in the section and laterally. Intersalt fluid-bearing reservoirs are a special object of forecast, the geological structure of which is fundamentally different from massive fractured reservoirs, and therefore is characterized by special effects of reflection and recording in the wave field. On the one hand, the layered medium is surely divided into a “soft” and “hard” type precisely because of the differential velocity of the wave at the “salt-dolomite” and “dolomite-salt” border. It is this basic property that underlies the procedure for linking VSP, acoustic logging (AK) and CDP data, and is used to significantly increase the level of interpretation of seismic data when studying the geological structure of the sedimentary cover. On the other hand, fractured reservoirs in the layered “salt – carbonate – salt” system in terms of their parameters (thickness of each individual reservoir or reservoir – fluid-impermeable layer) are often comparable with the maximum resolution of the CMP seismic survey.

It is known that the entire Earth's crust as a whole is a planetary fissure massif with a zonal structure of the fracture component of its rock-forming environment (Nikolaevsky VN The fracture of the earth's crust as its genetic trait // Geology and Geophysics. 2006. V. 47. No. 5. С 646-656; Milanovsky S.Yu., Nikolaevsky VN The Role of Fracture in the Evolution of the Earth's Crust // Tectonophysics and Topical Issues of Earth Sciences., By the 40th anniversary of the creation of the Laboratory of Tectonophysics at the Institute of Physics of Physics, RAS: Report materials All-Russian Conference in 2 volumes. M .: IFZ RAS, 2009. V. 2. S. 71-103). The term “fracturing” means a set of large and small voids (cracks, cavities) in a certain volume of the medium. Many collectors are associated with zones of increased concentration of cracks and cavities. Such zones are characterized by significant sizes: from the first hundred meters to a kilometer or more. The distribution of microvoids in space is uneven and, as a rule, is observed in the section in paragenesis together with extended sub-horizontal reflecting boundaries. It is the fractured layered multilayer type of distribution of natural reservoirs in the sedimentary cover of the platforms, where each layer of fractured carbonate reservoirs alternates with fluid-resistant, is the most difficult object to predict saturation and reservoir properties (FES), where the results can be characterized by ambiguous interpretation.

Most of the fractured zones have a tectonic origin (Dorofeeva TV. Tectonic fracturing of rocks and the conditions for the formation of fractured oil and gas reservoirs. - L .: Nedra, 1986. - 224 pp .; Kharakhinov, VV, Shlenkin, SI, Cracked oil and gas reservoirs - Scientific World, 2015. - 284 p.), which causes anisotropy of fracture and cavern-fracture reservoir type, since cavernosity develops as a secondary reservoir through permeable, filtering fracture systems. The areas of greatest fracture density (weakened zones) were the place of the occurrence of disjunctive dislocations of all ranks (faults, thrusts, thrusts, faults) with further geological development. The presence of disjunctive disturbances, as a rule, does not increase the thickness of the tectonic fracture that was formed earlier, only in the immediate vicinity of the disturbance line, in the zone 20–80 m wide, the integrity of the rocks changes due to the feathering faults and crushing (Smehov EM fundamentals of searches for fractured oil and gas reservoirs. L., Nedra, 1974, - 200 p.). At the same time, in the geological section of the halogen-carbonate stratum, which is considered in the present Application as a target object, the development of the void space, containing and filtering fluids, the so-called “filtration field”, is localized only in intersalt carbonate formations, and this property of the layer-by-layer distribution of permeable carbonate ( limestones, dolomites) and impermeable (salts, anhydrites) layers of the natural reservoir must be taken into account in the model of the forecast object. Despite the fact that the effect of disjunctive disorders on fracture thickness is insignificant, the identification in the context of the zones of influence of these violations is an important task, since they indicate the most weakened areas where structural fracturing could not compensate for the stress that arose during the formation of the plicative structures.

The main parameters of fracturing are the thickness, opening and the predominant azimuthal orientation of the fractures. The dimensions of cracks range from a centimeter to the first meters (small cracks) and from tens to hundreds of meters (large). In many cases, fracturing causes the development of cavernosity and karst carbonate formations, which can occur both at shallow and at great depths. Therefore, in the general case, fractured-cavernous zones should be considered. In contrast to porous rocks, the distribution of cracks is often not a chaotic, but a regular one. Thus, the anisotropic fracturing of reservoirs found in many areas (EM Smekhov. Theoretical and methodological foundations of searches for fractured oil and gas reservoirs. L., Nedra, 1974, - 200 p.) Indicates a predominantly azimuthal orientation of the fracture paragenesis, i.e. their regular development in three planes and unequal, multiple of different permeability, i.e. anisotropy of filtration, filtration field.

The field of scattered waves is formed from a set of cracks, i.e. anisotropic void space and is interference, depending more on the distribution of inhomogeneities than on the acoustic characteristics of rocks. The questions of wave field formation in randomly inhomogeneous media (zones of fracture and cavern development) have not been studied enough, which affects the interpretation of the registered scattered waves. The study of the features of the wave field formation in randomly inhomogeneous media by analytical methods is impossible. Currently, due to the increased interest of the oil and gas industry to the study of fractured reservoirs in dense rocks of the sedimentary cover and in the basement crystalline rocks, methods for numerical simulation of seismic wave propagation are being actively developed (Levant VB et al., Numerical simulation of seismic responses from fractured collectors by grid-characteristic method. M., EAGE Geomodel Publishing House, 2018, - 250 s; IE Kvass, et al. Solving direct seismic survey problems in fractured media using the grid-x method Abstract modeling. M., EAGE Geomodel Publishing House, - 296 pp .; Fayzulin IS, Kutsenko N.V. On the possibility of using scattered waves to study the fracture of the geomedia according to numerical simulation. EAGO, Geophysics, No. 5 , 2004, pp. 5-9).

Analyzing the published materials, we note the most important for practice the results of these studies:

- the intensity of the scattered wave is an order of magnitude lower than the intensity of the diffracted and about two orders of magnitude lower than the regular reflected wave;

- the combination of inhomogeneities forms a complex multiphase scattered wave, in which the most coherent and intense frontal part is caused by the sharpness of the transition boundary from the host rocks to the heterogeneity zone;

- the directional pattern of the scattered wave, as a rule, is not uniform - the most intense wave propagates forward in the direction of the incident wave, and in the opposite direction the wave is 1.5–2 times weaker;

- the shape and duration of the scattered wave depends on the size of the scattering region;

- increasing the concentration and uniformity of the distribution of cracks increases the amplitude of the scattered wave;

- cracks compared to caverns with the same number and size create an overall weaker background of the scattered component;

- the unidirectional field of cracks forms an asymmetrical wave response to the incident wave, i.e. the energy dissipated from such a fractured zone will depend on the direction of propagation of the incident wave. Obviously, the layered section of the salt-carbonate-salt target, where carbonate formations are unevenly / anisotropically fractured, further complicates this asymmetrical wave response.

In the course of processing and interpreting seismic data, the following geological factors should be taken into account:

1. In the geological section of the sedimentary cover of the Siberian platform, at least three geological formations are distinguished in relation to the middle, halogen-carbonate (object of forecasting): super-salt, halogen-carbonate and subsalt.

2. In the last decade, the vector of geological exploration of hydrocarbon (hydrocarbon) perspective objects shifted from typically platform areas (Angaro-Lena stage, Nepsko-Botuobin anteclise) to the marginal region of the Siberian Craton, the region of the marginal deflections of the platform.

3. The territories of the marginal deflections and the area of their articulation with typical platform structures are sharply complicated in terms of the geological structure of the section - here desalination is proved, and with it the loss of acoustic differentiation of the section halogen-carbonate sequence (i.e. change, disappearance of abrupt transitions, changes in velocity propagation of acoustic waves). Such a change — desalination and the replacement of salts with gypsum and anhydrite in a certain volume; in the transition zone a platform — the marginal deflection has a different genesis, i.e. occurred at different geological times and under different conditions, and will require a more detailed interpretation of the acoustic picture of seismic prospecting in integration with deep drilling data. Two different geological processes are described in the geological literature (Zharkov MA, Chechel EI Sedimentary Formations of the Cambrian of the Angaro-Lena Trough. - Novosibirsk: Nauka, 1973. - 238 pp .; Melnikov N.V. Uncompensated deflections and washout zones salts in the context of the south of the Siberian platform. New data on the geology and petroleum potential of the Siberian platform // N.V. Melnikov, A.O. Efimov, I.G. Safronova.– Novosibirsk: SNIIGGiMS, 1980. - P. 36-50 .; Melnikov, NV The Vendian-Cambrian salt-bearing basin of the Siberian platform (stratigraphy, history of development) [Text] / N.V. Melny kov. - Novosibirsk: Publishing House of the Siberian Branch of the Russian Academy of Sciences, 2009. - 148 pp., Stratigraphy of Siberian oil and gas basins, Cambrian of the Siberian Platform [Text] / Main Editor AE Kontorovich; - Novosibirsk: INGG SB RAS, 2016. T . 1 - 497 s.). The first process considers different conditions of primary sedimentation (lithogenesis), namely, in a closed saltwater basin, where rhythmic batches of carbonate-salt-sulfate accumulated, and in an open sea basin of normal salinity, where carbonate material accumulated in shallow lagoons; platforms and clinoforms. The second group of processes in epigenesis characterizes the processes of leaching and replacement of salt-bearing formations and packs - during interruptions in sedimentation (for example, pre-Litvintsovsky interruption in the Cambrian), as well as the processes of leaching of salts and carbonates in the infiltration stages of the evolution of the marginal areas of the platform.

Also documented is the increase in the power of the lower terrigenous part of the section (i.e., the presence of inclined reflecting boundaries) from the platform into the marginal deflections.

4. The geological section of the sedimentary cover is complicated by both structural-material (permafrost) and geological and structural heterogeneities, both regional and zonal-local plan. The modern structural plan of the northeastern side of the Siberian Platform is directly linked to the multi-tectonic structure of the Riphean-Vendian-Cambrian natural mega-reserve of oil and gas. Two structural layers - allochton and autochthon (Migursky AV, Staroseltsev VS Neftegazogeologichesky zoning of auto- and allochthon in the south of the Siberian platform) are distinguished in the shady-thrusting model of a deformed sedimentary cover // Modern problems of thrust-tectonics. Ufa, 1997. p. 67-69 .; Sizykh, VI, Sharyazhno-Nadvigovaya Tectonics of the Margins of Ancient Platforms, Novosibirsk: Publishing House of the Siberian Branch of the Russian Academy of Sciences: GEO Branch, 2001. 571 pp. Smetanin AV Experience of Dynamic Interpretation of Gravity Anomalies / / Irkutsk, 2000. - 85 p .; Models of a structure and quantitative about .. Regional ENKA hydrocarbon potential oil and gas reservoirs Predpatomskogo regional trough (Siberian Platform) Ed GG Chemin: monograph Novosibirsk: Izd GEO, 2017 - 560)... The sedimentary stratum of the Riphean and Vendian, “soldered” to the surface of the basement, constitutes the lower, autochthonous tier within the junction zone of the pre-Riphean trough and a typical platform structure. Above the Ossean horizon in the main salt-bearing suites of the Cambrian — Usolskaya, Belskaya, Angarskaya — the thrust-related tectonics are actively manifested. The sediment package has been torn down, shifted in directions to the north and west-north-west in the zone of influence of the Pre-Baikal-Patom thrust belt (Sizykh V.I. Sharyazhno-thrust tectonics of the margins of ancient platforms. - Novosibirsk: Publisher of the Siberian Branch of the Russian Academy of Sciences: Branch " GEO ", 2001. - 571 pp., Smetanin AV Experience of dynamic interpretation of gravitational anomalies // Irkutsk, 2000. - 85 pp., Sizykh V.A., Vakhromeev AG The role of a thrusting tectonics in the formation of anomalous - high reservoir pressures and industrial metal-bearing brines of the Siberian platform // Reports of the Russian Academy of Sciences. - 20 06. - №2. - p. 1-5.)

The listed complications of the geological section of the sedimentary cover significantly complicate the interpretation of seismic data in all its field modifications and interpretation algorithms, and require a more detailed, fractional algorithm for processing field data to solve the problem of identifying and mapping fluid-saturated anisotropic inter-salt cavern-fractured carbonate reservoirs with wide ranges. , with AVPD fluids in the geological section of the sedimentary cover of the platforms and their areas of intersection with the marginal and deflections. This statement is also true for “thin” technologies for studying layered fissure systems of a geological section of a sedimentary cover, as applied to the task of identifying, identifying and mapping zonal and local structurally real inhomogeneities (EHR) in the target intervals of the sedimentary cover, for example, discussed in this Application intersalt carbonate cavern-fissure reservoirs of halogen-carbonate reservoirs of the natural Cambrian mega-reserve (Vakhromeev AG, Myshevsky NV, Khokhlov GA Anomalously-high reservoir pressures as a factor complicating the development of hydrocarbon fields in Eastern Siberia // Proceedings of the All-Russian meeting “Modern geodynamics and dangerous natural processes in Central Asia: fundamental and applied aspects.” - Irkutsk: IZK SB RAS, 2006. - Issue 5. - С 98-119; AG Vakhromeev, Regularities of formation and localization of deposits of industrial brines in carbonate cavern-fractured reservoirs of the Cambrian of the south of the Siberian platform (according to deep drilling data, well testing and field geophysics): Monograph I. - Irkutsk: Publishing house of the Irkutsk National Research University, 2015. - 248 p.).

It is obvious that the algorithm for processing the seismic cube data in the prototype method does not allow to take into account the listed geological factors that complicate the wave pattern, and significantly reduce the efficiency of detection and mapping of fluid-saturated anisotropic cavernous-fractured inter-salt carbonate reservoirs according to the prototype. Solving this problem requires a detailed step-by-step account of the inhomogeneities in solving the problem of identifying and mapping cavern-fractured reservoirs in intersalt carbonate formations of the middle halogen-carbonate stratum of the Cambrian, on the edge of the Siberian platform.

Disclosure of the invention.

The technical result is a high reliability of the forecast - complexly constructed fluid-saturated fracture-cavernous zones, with abnormally high reservoir pressure of fluids in the halogen-carbonate strata of the geological section of the sedimentary cover of the platforms and areas of their interconnection with the marginal deflections that complicate drilling at various stages and stages of the geological exploration.

The technical result of the proposed method is achieved by identifying and mapping fluid-saturated anisotropic cavernous-fractured inter-salt carbonate reservoirs. The authors first identify an effective interval that corresponds to the target of the forecast geological section, step by step solve the problem of eliminating undesirable effects on the wave pattern in the target forecast object, which invariably takes place - from the upper part of the section (VCHR), including permafrost stratum, from the zone of development of karst phenomena in the Ordovician stratum (neo-autochthon), from local plicative dislocations (salt tectonics) linear (allochthonous anticlines) and isometric (brachyanticline and brachysyncline), and then solve the main problem of identifying and mapping the patterns, to study body patterns, to study body patterns, to study body patterns, to work patterns, to create body patterns, to create mats, for example, brachyanticline and brachysyncline, and then solve the basic problem of identifying and mapping the cores to identify and mapping body patterns, and to work out the same patterns to identify and mate the body patterns, to do the mapping of mats carbonate formations of the middle halogen-carbonate stratum of the Cambrian. As applied to deciphering the geological structure of complexly constructed fissure reservoirs of the halogen-carbonate sequence, detecting and mapping the volumes of the secondary void space of fractured inter-salt reservoir reservoirs, the solution of the problem is provided by using VSP data and acoustic logging data from deep wells (AK and its foreign modifications - acoustic scanner [ Sonic Scanner], ultrasonic high-resolution micro-imager [UBI]), and their domestic counterparts. This ensures a confident separation of the overall wave pattern, identification and leveling of negative effects from above and below the underlying strata of the section, which allows to detail the scattered component of the seismic field in the target object of research, to determine its energy characteristics: both generalized and at the level of individual inter-salt layers - collectors. Only the observance of the listed steps in the general algorithm for processing seismic data of CDP ensures efficient use of focusing processing procedures, both on seismograms and on summary data, with obtaining a section of the target object of study, the target fragment, i.e. the energy of the scattered waves, on the basis of which they reveal, investigate and differentially characterize complexly constructed alternating fractured cavernous intersalt layers at depths of 1.2-2.2 km.

The technical result is achieved by the fact that in the proposed method of detecting and mapping fluid-saturated anisotropic cavern-fractured reservoirs in inter-salt carbonate formations of the sedimentary cover, including the seismic signal excitation, seismic field recording and data processing, in which regular reflected and multiple waves are eliminated, the scattered component of the seismic signal is eliminated, the scattered component is eliminated by the seismic field, and the data are eliminated. fields, determine the energy and spectral characteristics, the degree of irregularity of the seismic signals of the scattered Components characterized in that, additionally, in the process of data processing in the total volume of the geological section, eliminate the influence of the underlying structural-material complex, leveling the influence of structural-material inhomogeneities of the subsurface part of the section, allocate the interval corresponding to the target of the forecast of the geological section, and for modeling various types of waves, characterizing the target object of the geological profile forecast, for the purpose of their identification they use the results of a comparative wave analysis of land seismic data with three-component vertical seismic profiling materials, acoustic logging data, for conversion into seismic attributes, then apply focusing processing procedures, both according to seismograms and total data, to obtain a section or cube of scattered wave energy, based on which they reveal complexly constructed anisotropic alternating fractured-cavern inter-salt reservoirs, with fractured reservoirs with scattered waves up to 250 conv. units, - from the cavern at the values of the scattered waves from 200 to 400 srvc. units, with a pore when the values of scattered waves from 400 to 500 srvc. units - a component of the void space, followed by mapping of the distribution contours of the void space over each intersalt carbonate formation and over the layered carbonate layer as a whole.

Brief description of illustrative materials.

FIG. 1 shows the time-lapse seismic section of the CDPG obtained after suppressing interference waves.

FIG. 2 shows the results of linking the materials of the 3-component VSP with the AK data on the well and the correlation of the reflecting boundaries in the wave seismic section of the MCTD in the target interval.

FIG. 3 shows the traces of the scattered signal component obtained after subtracting monotypic ascending waves.

FIG. 4 shows the paths of the instantaneous amplitudes RV.

FIG. 5 shows a section of the energy of the RV, calculated after focusing treatment procedures.

FIG. 6 shows the differential energy distributions of scattered waves by type of void space.

The implementation of the invention.

In order to map and identify fluid-saturated anisotropic cavern-fractured reservoirs in intersalt carbonate formations of the sedimentary cover, it is necessary to carry out non-standard technological approaches to the processing of the wave field. According to the presented data, a treatment was carried out aimed at the release of the energy of the scattered component from the wave field of the ascending waves recorded on the day surface by the CGT method. The applied nonstandard method is aimed at isolating the scattered component of the RV signal to identify irregular elements of geological media, such as fractured, cavernous, and rapogas zones. For processing, a geometrized data array was used, and it was formed after standard processing before applying filtering procedures, the base of static corrections and the speed data laws of CDP.

Before processing, the analysis of the quality of materials was carried out, with the calculation of the amplitude-frequency attributes of seismic recording in various time windows to determine the amplitude-frequency characteristics of various types of waves. After calculating and analyzing the dynamic characteristics of different types of waves, the generated processing graph can be divided into several main stages.

The first stage of processing - preparatory - includes: reading the material, calculating and entering static corrections, weakening harmonic noise and amplitude gaps (of technogenic origin).

At the second stage, the kinematic characteristics are calculated for different types of waves, the determination of the recovery parameters of the amplitudes of the ascending waves, the selection of the deconvolution parameters.

At the third stage, data processing is aimed at suppressing low-frequency surface waves, multiples, partially multiples and exchange waves. These waves are eliminated by preliminary results of kinematic analysis (after identifying the type of subtracted waves by means of modeling, or by identifying with data from three component VSP) by applying multidimensional filtering (Radon filtering, filtering in the frequency domain, etc.).

The materials of the 3-component VSP at the stage of processing were used to authenticate various types of waves recorded in the near-wellbore space by the methods of VSP and on the day surface with surface seismic survey. The results of kinematic calculations for various types of waves and data on lithological-stratigraphic binding were also used. In addition, an analysis was carried out to study the phase and amplitude-frequency characteristics of longitudinal waves recorded at different distances from the wellhead (the effect of distance on the signal recording form).

There are certain problems associated with the complex geological structure of the study area. This is primarily the negative impact of heterogeneity in the VCHR, thin layer of the target of the section, structural-tectonic inhomogeneities of the oversalt and salt-bearing strata, and other inhomogeneities of the section on the seismic recording of the useful signal. The influence of the above-mentioned irregularities causes a different level of wave-interference, which adversely affect the characteristics of the useful reflections. To study the characteristics of wave-interference and useful waves, we also used VSP materials, carried out in various parts of the study area.

On the basis of a comprehensive analysis of surface and borehole seismic data, interrelations were obtained between the characteristics of the geological structure of the environment and the dynamic characteristics of the wave field of useful waves and interference waves. Thereby, they tested (according to the results of testing) and implemented additional processing procedures, which allow reducing the influence of various wave-interferences on the useful part of the signal.

FIG. Figure 1 shows a seismic section fragment containing reflections of monotypic ascending longitudinal waves and the scattered component of the wave fields after applying the above processing procedures. Visually viewed incision is practically indistinguishable from the incisions calculated after standard treatment, due to the low level of PB.

To suppress monotypic reflected longitudinal waves, the authors propose a procedure for the selection of waves (Fig. 3). The algorithm of the method is based on the calculation of the matrix of normalized cross-correlation functions (PCF) of each of the tracks in the correlation window with the remaining tracks for each sliding sample (magnetogram) of the tracks. Each row of the obtained FCM matrix (for example, the kth) is a set of PVCs of the current path (kth in the path base or in a magnetogram) with all the other paths. The values of the maxima normalized by PVCs are estimates of the similarity coefficients of the two correlated paths. To improve the quality of the program, an iteration method was used. This procedure is used to obtain the wave field of the scattered waves. At the same time, the final selection of waves is carried out both according to seismograms with different sorting (it can be sorted according to the general point of excitation, according to the common depth platform, etc.), and according to the total sections (depending on the area of work, cost of work, power of the computing center tasks, etc.). The obtained temporary PB fields are recalculated into amplitude-frequency attributes (Fig. 4), then the focusing procedures are applied (Fig. 5). FIG. 4 shows the wave field of instantaneous amplitudes obtained after the procedure of attribute conversion, where a) 1 are the paths of instantaneous amplitudes.

FIG. Figure 5 shows the final section of the energy of the RS, calculated as a result of focusing transformations of the seismic attribute field.

Thus, according to the above algorithm, the focusing of the RV energy is possible both before the summation stage and according to the summary data. The processing procedures used also make it possible to obtain diffractors containing an image of the scattering elements of the medium and reflectors — a field of reflected waves without scattering elements. The inventive method of detecting and mapping fluid-saturated anisotropic cavernous fractured reservoirs in inter-salt carbonate formations of a sedimentary cover through scattered waves allows you to explore fluid-saturated alternating fractured-cavernous inter-salt formations with a fracture (with the RV value of 250 used. from 200 to 400 conventional units., type 2 - pore (PB values from 400 to 600 conventional units.) type 3 component of the void space (Fig. 6).

Example.

Let us consider seismic survey data using the example of the seismic cube CDP in the three-dimensional modification obtained in the south of the Siberian platform. The presented drawings (Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5, Fig. 6) reflect the results of the proposed methodology for the main stages of specialized processing aimed at extracting the scattered wave field component.

FIG. Figure 1 shows the time section of the CGD in three-dimensional modification, the target object is a halogen-carbonate sequence after suppression of various waves-interferences (man-made, multiples, surface, exchange, etc.) in the interval of the most intensive manifestations and gas saturation, where:

1 - seismic traces obtained as a result of summation over a common depth point (GBS);

2 - reflecting seismic horizons K2 (atovskiy horizon), Y (roof of Usolsk suite);

3 - calculation interval of amplitude - frequency attributes;

4 is a graph of instantaneous amplitudes calculated in the range of reflecting horizons (FG) K2 and Y.

5 - wells with fluid inflows (brine, gas) in the target interval;

6 - fissure-cavernous intersalt layers, with fissure-cavern-pore component of the void space.

FIG. 2 shows the results of linking the materials of the 3-component VSP with the AK data on the well, and the correlation of the reflecting boundaries in the wave seismic section of the MOGT in the target interval of the halogen-carbonate sequence, local carbonate fracture fluid-saturated (brine, gas) reservoirs, of which drilling received flush tributaries, and in the interval of which is recorded AHFD fluids.

FIG. 3 shows a fragment of the time section after applying wave selection procedures, where:

3.1 - total seismic paths of the RT.

3.2 - target interval;

FIG. 4 shows a similar fragment of the section of the instantaneous amplitudes of the RT, CDP data, obtained as a result of recalculation of amplitude-frequency attributes, where:

4.1 - instantaneous amplitude tracks.

FIG. 5 shows the results of specialized processing — a section of the RV energy obtained after applying focusing procedures, where:

5.1 - PB energy paths;

5.2 - reflecting seismic horizons K2 (atovskiy horizon), Y (the roof of the Usolsk suite);

5.3 - calculation interval of amplitude - frequency attributes;

5.4 is a graph of the change in the energy of the RS, calculated in the exhaust gas interval K2 and Y;

5.5 - characteristic paths of RV energy with a range from 200 to 300 (cu);

5.6 - RV cut intervals with energy characteristics from 100 to 200 (cu);

5.7 - cut intervals RV with energy characteristics from 300 to 400 (cu);

5.8 - RV cut intervals with energy characteristics above 400 (cu).

The technical result is a high reliability of the prediction of target objects — fluid-saturated inter-salt anisotropic cavern-fractured reservoirs with a wide range of permeability, with an overpressure fluids in the geological section of the sedimentary cover of platforms and areas of their intersection with marginal deflections, which complicate drilling at various stages and stages of geostructures. fields of scattered waves.

Claims (1)

The method of detecting and mapping fluid-saturated anisotropic cavern-fractured reservoirs in inter-salt carbonate formations of the sedimentary cover, including seismic signal excitation, seismic field recording and data processing, which eliminate the regular reflected and multiple waves, emit the diffuse component of the seismic field, determine the spectral energy and the spectral spectrum. the degree of irregularity of the seismic signals of the scattered component, characterized in that it additionally in the process processing the data in the total geological section eliminates the influence of the underlying structural-material complex, leveling the influence of structural-material inhomogeneities of the near-surface part of the section, allocates the interval corresponding to the target object of the geological section, and for modeling various types of waves characterizing the target object of the geological section forecast, use results of a comparative wave analysis of land seismic data with three-component materials seismic profiling, acoustic logging data, for conversion to seismic attributes, then apply focusing processing procedures, both on seismic and sum data, to obtain a section or cube of scattered wave energy, on the basis of which complex anisotropic alternating fractured-cavernous waves are detected intersalt reservoirs, with fracture - at values of scattered waves up to 250 arb. units, - from the cavern at the values of the scattered waves from 200 to 400 srvc. units, with a pore when the values of scattered waves from 400 to 500 srvc. units - a component of the void space, followed by mapping of the distribution contours of the void space over each intersalt carbonate formation and over the layered carbonate layer as a whole.

Images