RU2451951C2 - Method of searching for hydrocarbon deposits confined to fissured-cavernous collectors - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: using Fresnel pre-stack techniques, two seismic data volumes are obtained: migrated reflected wave volume (reflectors) and diffraction wave volume (diffractors). The diffractor volume is obtained through subtraction and subsequent focusing of scattered waves. Amplitude and spectral attributes of the seismic field are calculated from the diffractor volume. A three-dimensional model of scattering objects of the geologic environment (acoustic heterogeneity index volume) is obtained from integral amplitude characteristics. Through sequential interpretation of the migrated reflector volume and the acoustic heterogeneity index volume, the distribution of instantaneous amplitude values of scattered waves on the section of the volume in intervals corresponding to the investigated productive levels of the geologic section is obtained. The distribution of amplitude values of scattered waves is classified according to values in accordance with the field-geophysical data. Objects with maximum acoustic heterogeneity index values, which correspond to zones of development of fissured-cavernous collectors are selected. The potential for drilling exploration and production wells is estimated on the selected objects.

EFFECT: high search accuracy.

3 dwg

Description

The present invention relates to the field of seismic exploration and can be used in the search for oil and gas fields with complexly constructed fractured cavernous reservoirs.

A known method of seismic exploration of rocks [1], in which the placement of sources and receivers outside the studied array from the two adjacent faces of this array. Transmission of the selected volume of rocks in two orthogonal directions is performed. Radiated waves are focused in the center of each selected block and wave energies from each selected block are determined. A three-dimensional image of a local diffracting object is obtained from each center of the selected block. For the most reliable combination of the image of the object obtained from two directions, the enumeration of the values of the propagation velocity of elastic vibrations is done. When fully combined, a true image of a diffracting object in space is obtained.

The main disadvantage of this method is that the observation system used differs significantly from standard seismic surveys by the common depth point method (MOGT), that is, to implement the method, it is necessary to use special layouts of sources and receivers, which technically complicates the method and requires significant economic costs.

Closest to the invention in technical essence (prototype) is a method for seismic exploration of massive geological rocks [2], in which a seismic signal is excited and recorded by standard methods. Seismic data is processed with the maximum attenuation of interference and ensuring the preservation of the primary seismic field. The scattered component is isolated by additional suppression of regular reflected and multiple waves. 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, fissure-cavernous zones are distinguished.

This method is based on the use of standard 2D and 3D seismic data obtained by the MOGT. However, the standard methods used in the prototype do not allow to accurately determine the location and shape of the diffracting object in space. The inability to determine with sufficient accuracy the desired characteristics is the disadvantage of the prototype.

The present invention solves the problem of increasing the accuracy of determining the location and shape of a diffracting object, obtaining recommendations for laying production wells.

To solve it, special methods of pre-migration Fresnel migration and a comprehensive analysis of geological and field-geophysical information on selected objects are used.

The technical result of the present invention is a method for searching for hydrocarbon deposits confined to fractured cavernous reservoirs, which makes it possible to more accurately calculate the amplitude and spectral attributes of a seismic diffuse field using cube diffraction methods, to construct bulk seismic geological models of fractured cavernous reservoirs, i.e. more accurately determine the location and shape of diffracting objects and build reliable maps of oil and gas potential according to target izontam recommendations on drilling of exploratory and development wells, reducing field development costs.

The technical result is achieved by the fact that in the method of searching for hydrocarbon deposits confined to the fissure-cavernous reservoirs, which, similarly to the prototype, carry out special processing of standard MOGT seismic data (2D and 3D) to obtain a full wave field containing reflected and diffracted waves according to the invention using special methods of pre-migration Fresnel migration receive two cubes of seismic data: a migrated cube of reflected waves (reflectors) and a cube of diffracted waves (diffractors). The cube of diffractors is obtained by subtracting the reflected waves and subsequent focusing of the scattered waves. Next, the amplitude and spectral attributes of the seismic field are calculated from the cube of diffractors. In accordance with the fact that the integral amplitude characteristics of the scattered field at each point of the cube are proportional to the index of acoustic heterogeneity in the vicinity of this point, a three-dimensional model of the scattering objects of the geological medium (the cube of the index of acoustic heterogeneity) is obtained from the integral amplitude characteristics. Further, by means of a joint interpretation of the migrated cube of reflectors and the cube of the index of acoustic heterogeneity, the distribution of the instantaneous amplitudes of the scattered waves over the cross section of the cube in the intervals corresponding to the studied productive levels of the geological section is obtained. This distribution is subsequently classified according to the magnitudes of the amplitudes in accordance with the field-geophysical information. Since the objects with the maximum values of the acoustic heterogeneity index correspond to the zones of development of fractured cavernous reservoirs, the prospectivity of exploration and production wells is estimated using the objects highlighted on the maps.

The essence of the method

The attenuation of waves in a medium is usually associated with two factors: inelastic absorption due to the conversion of the energy of elastic vibrations into thermal energy due to friction of the vibrating particles of the medium and the scattering of waves as a result of diffraction of waves by acoustic inhomogeneities of the medium, in particular, caverns and cracks. A scattered wave is usually formed on inhomogeneities of the medium with dimensions smaller than the incident wavelength. The superposition of all scattered waves forms a scattered seismic wave. Scattered waves differ from mirror-reflected waves in kinematic and dynamic parameters (seismic attributes). The kinematics of the scattered waves corresponds to a point emitter, and the dynamics is determined by amplitudes 1-2 orders of magnitude smaller than the amplitudes of the reflected waves. The energy and amplitudes of the scattered waves are determined by the fracturing parameters of the medium. The ratio of the amplitudes of scattered and reflected waves is the main problem of distinguishing weak in amplitude scattered waves from the background of reflected waves.

Existing methods for calculating seismic fields in complex environments can be divided into two classes. These are asymptotic, based on the ray representation of the wave field and its various modifications, and sequentially numerical methods for solving the dynamic equations of propagation of seismic disturbances. Asymptotic approaches to the study of wave fields are still very widely used and indispensable for preliminary analysis and understanding of the main features of the processes of formation and propagation of wave fields. However, their application for substantially inhomogeneous media does not allow obtaining the dynamic description of the total wave field with the necessary accuracy.

The method simulates seismic media in the acoustic approximation in a two-dimensional and three-dimensional setting in order to detect characteristic inclusions - diffractors in the medium. Moreover, the characteristic size of the inclusions is about tens of meters, and the difference in acoustic properties is about percent. Such conditions impose special requirements on the accuracy and productivity (calculation speed) of the diffractor calculation method.

The application of the method for the search for hydrocarbon deposits associated with reservoirs of an unconventional (fissure-cavernous) type provides the identification and assessment of the quality of fissure-cavernous reservoirs based on specialized and in-depth processing of 2D and 3D seismic data, a comprehensive analysis of geological and field-geophysical information, using specialized computer complex. The most informative component of exploration geophysics is the specialized processing of 3D seismic data, which, in contrast to 2D data, is based on more adequate three-dimensional models of the environment.

The method for identifying and assessing the quality of fractured cavernous reservoirs includes the following main processes: input and standard processing of 2D and 3D seismic information of the MOGT; specialized processing and construction of two independent cubes - a cube of reflectors (reflectors) and a cube of the index of acoustic heterogeneity of the geological environment - a cube of diffusers or diffractors. Next, mathematical modeling of the synthetic wave field scattered by point diffusers located in the nodes of a uniform grid inside the cube under study and the corresponding geometry of the shooting of this area and the velocity model obtained at the preliminary stage of processing and specialized processing of synthetic 3D data are performed. The cube of correcting coefficients is calculated and the true amplitudes of the synthetic cube are restored, the true amplitudes of the cube of reflectors and the cube of diffractors are restored, and dynamic parameters for the cube of reflectors and the cube of diffractors are selected. Correlation of the reflecting horizons is made and a three-dimensional fault-block model is created using a cube of reflectors, which is then transferred to a cube of diffractors and a volumetric seismic-geological model of fracture-cavernous reservoirs is built. Based on the volumetric seismic-geological model of fractured cavernous reservoirs, forecasting maps of the propagation zones of fractured cavernous reservoirs and seismic geological sections of reflectors and diffractors characterizing the structure of reservoirs with fractured cavernous reservoirs are constructed. At the last stage, maps of oil and gas prospects for target horizons are built with recommendations for laying exploration and production wells.

One of the main procedures for converting seismic records in the image of the geological environment is temporary and deep migratory migration. In the standard processing, migration procedures are used before summing up on the basis of constructing a time and depth-velocity model — classical Kirchhoff migration — continuation of the wave field in depth based on a one-sided wave equation. The main disadvantage of this migration is that it gives an image of the environment with distortions of the geological structure, amplitudes and spectral composition. This is due to the uneven "lighting" of reflecting and scattering objects, associated with the unevenness of the observation system.

In the proposed method, in contrast to standard processing, using cubic Fresnel migration methods, two cubes of seismic data are obtained: a migrated cube of reflected waves (reflectors) and a cube of diffracted waves (diffractors). In this case, a cube of diffractors is obtained by subtracting the reflected waves from the total wave field and subsequent focusing of the scattered waves. Next, the amplitude and spectral attributes of the seismic field are calculated from the cube of diffractors. The use of pre-migration Fresnel migration increases the signal-to-noise ratio for diffractors and scatterers, which allows to increase the accuracy of determining the location and shape of a diffracting object in space.

The amplitude characteristics of the scattered field (instantaneous amplitude function) at each point in the cube are proportional to the index of acoustic heterogeneity in the vicinity of this point. According to these characteristics, a three-dimensional model of scattering objects of the geological medium is obtained - a cube of the index of acoustic heterogeneity. Next, a joint interpretation of the migrated cube of reflectors determining the main horizons and the cube of the index of acoustic heterogeneity is performed and the distribution of the instantaneous amplitudes of the scattered waves over the area in the intervals corresponding to the studied productive levels of the geological section is obtained. The distribution of the instantaneous amplitudes of the scattered waves is classified by the magnitude of the amplitudes in accordance with field-geophysical information. Objects with maximum values of the index of acoustic heterogeneity, which correspond to the zones of development of fissure-cavernous reservoirs, are distinguished. According to the selected objects, the prospectivity of prospecting and producing wells is estimated.

The method is as follows.

At the first stage, for a specific license area where the seismic exploration of the MOGT (2D and 3D) was carried out, input and standard processing of seismic information is carried out. At the same time, the primary wave field is maximally preserved. Then, using a full wave field containing reflected and diffracted waves, using special Fresnel pre-migration methods, two cubes of seismic data are obtained: a migrated cube of reflected waves (reflectors) and a cube of diffracted waves (diffractors). In this case, a cube of diffractors is obtained by subtracting the reflected waves from the total wave field and subsequent focusing of the scattered waves. Next, the amplitude and spectral attributes of the seismic field are calculated from the cube of diffractors.

The use of pre-migration Fresnel migration allows to increase the signal-to-noise ratio for diffractors and scatterers and to increase the accuracy of determining the location and shape of the diffracting object.

The amplitude characteristics of the scattered field (instantaneous amplitude function) at each point in the cube are proportional to the index of acoustic heterogeneity in the vicinity of this point. According to the amplitude characteristics, a three-dimensional model of scattering objects of the geological medium is obtained - a cube of the index of acoustic heterogeneity. Next, a joint interpretation of the migrated cube of reflectors defining the main horizons and the cube of the index of acoustic heterogeneity is performed, and the distribution of the instantaneous amplitudes of the scattered waves over the area in the intervals corresponding to the studied productive levels of the geological section is obtained. The distribution of the amplitudes of the scattered waves is classified by their magnitude in accordance with field-geophysical information. At the same time, objects with maximum values of the acoustic heterogeneity index correspond to the zones of development of fractured cavernous reservoirs. According to the selected objects, the prospectivity of prospecting and producing wells is estimated.

Example.

The method of searching for hydrocarbon deposits associated with fissure-cavernous reservoirs has been tested on a large number of licensed sites in the fields of the Khanty-Mansiysk Autonomous Okrug (Khanty-Mansi Autonomous Okrug). As an example, data obtained at one of the Khanty-Mansi Autonomous Area deposits are presented. The main goal of the work was to identify the development zone of the fissure-cavernous reservoirs in the deposits of the Lower Tutleima sub-formation (layer U ₀ ), for which an analysis was made of the fields of reflected and scattered waves along the reflecting horizons B and B1 in the interval B-B1.

The list of graphic illustrations of the application of the proposed method.

Figure 1. The section of the temporary cube of reflected waves along line 493 (the section is shown in the lower left corner) of one of the Khanty-Mansi Autonomous Area deposits.

Figure 2. A section of a temporary cube of instantaneous amplitudes of scattered waves along line 493 (the cross section is shown in the lower left corner) of one of the Khanty-Mansi Autonomous Area deposits.

Figure 3. Map of the index of acoustic inhomogeneities in the interval of the Bazhenov formation (layer Yu ₀ ) of one of the Khanty-Mansi Autonomous Area deposits.

Figure 1 presents a time section of the reflected waves along line 493 (passing through wells 3000 and 3002) with the selected horizons B and B1.

Figure 2 shows a cross section of a temporary cube of instantaneous amplitudes of scattered waves along line 493, where the zones of maximum instantaneous amplitudes of scattered waves are highlighted in brown.

Figure 3 presents a map of the index of acoustic inhomogeneities of the interval of the Bazhenov formation (layer Yu ₀ ). On the map, in accordance with the index scale, zones of development of fissure-cavernous reservoirs with increased values of instantaneous amplitudes of scattered waves and increased values of the acoustic heterogeneity index are highlighted (the collector is highlighted in shades from red to blue, zones of possible development of the reservoirs are outlined in accordance with the legend on the map) . Based on the data obtained, it is possible to issue recommendations for the laying of production wells.

Comparison of the identified zones of development of the fracture-cavernous reservoirs with the data of oil inflow in the wells drilled in the studied area shows that in the wells 401, 3001, 3003, 3007, drilled in the development zone of the fracture-cavernous reservoirs, oil inflow was obtained from the formation Yu ₀ . Well 3002z, with no signs of oil, is located in the zone of lack of reservoirs.

Thus, the proposed method for the search for hydrocarbon deposits associated with fractured-cavernous reservoirs makes it possible to identify zones of fractured-cavernous reservoirs in space, to increase the accuracy of determining the location and shape of a diffracting object in space, and to provide reasonable recommendations for the laying of production wells.

Literature

1. RF patent №2251717, cl. 7 G01V 1/00, publ. 2005.05.10. Method for seismic exploration of rocks.

2. RF patent No. 2168187, class. 7 G01V 1/00, publ. 2001.05.27. The method of seismic exploration of massive geological rocks.

Claims (1)

A method of searching for hydrocarbon deposits confined to fissure-cavernous reservoirs, which consists in special processing of standard MOGT seismic data (2D and 3D) to obtain a complete wave field containing reflected and diffracted waves, characterized in that using special methods of stoke migration according to Fresnel they get two cubes of seismic data: a migrated cube of reflected waves (reflectors) and a cube of diffracted waves (diffractors), while a cube of diffractors is obtained by subtracting the reflected n and subsequent focusing of the scattered waves, the amplitude and spectral attributes of the seismic field are calculated from the cube of diffractors, then the three-dimensional model of the scattering objects of the geological medium (the cube of the index of acoustic heterogeneity) is obtained from the integral amplitude characteristics, and through the joint interpretation of the migrated cube of reflectors and the cube of the index of acoustic heterogeneity distribution of instantaneous amplitudes of scattered waves over the cube cross section in the intervals corresponding to the studied products The actual levels of the geological section, which are subsequently classified according to the magnitudes of the amplitudes in accordance with the field-geophysical information, distinguish objects with maximum values of the acoustic heterogeneity index, which correspond to the development zones of fractured-cavernous reservoirs, and evaluate the prospectivity of exploration and production wells from the selected objects.

Images