RU2502089C1 - Preparation method of structures perspective for prospecting and exploratory oil and gas drilling - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: seismic measurements are carried out by means of a CDP method on the surface area perspective in oil-and-gas-bearing respect. Processing and structural interpretation of seismic data is performed, thus obtaining structural maps of target reflecting horizons. Based on structural maps, additional build-up of two-dimensional networks of target reflecting horizons is performed. As per the received two-dimensional networks of target reflecting horizons and using a trend analysis method, build-up of two-dimensional networks a regional component is performed for each reflecting horizon. A local component is calculated. For cells of the two-dimensional network of the local component the prepared structures are localised for each target reflecting horizon at simultaneous fulfilment of two conditions: first - when the local component is larger than zero, and second - when a zero contour is closed. A sum of local component is defined for all the target reflecting horizons. With that, the local structure is considered to have been prepared for all the target reflecting horizons when the value of sum of local component is larger than zero. For allocated localised structures for each reflecting horizon there calculated is local structure amplitude and local structure surface area. Priority of readiness degree of the structure prepared for prospecting and exploratory oil and gas drilling is determined as per the value of amplitude and surface area of local structure, and namely: the higher the above local structure values, the higher the perspective of prospecting and exploratory oil and gas drilling.EFFECT: improving geological informativity of geophysical surveys, localisation and ranging of prepared structures as to the perspective at preparation for prospecting and exploratory drilling.5 dwg

Description

The invention relates to geophysical methods of deep structural mapping of oil and gas prospective elevations. The predominant use of the invention is the preparation of objects according to the structural plans of the sedimentary cover horizons of oil and gas producing or oil and gas prospective areas, characterized by relatively good knowledge of the upper part of the geological section and insufficient illumination of the deep structure.

There is a method for determining the ratio of structural plans of local elevations, in which, based on drilling and / or seismic data, the studied (target) structural surfaces of the local elevation are compared with the base horizon by finding the coefficients of correspondence of the areas, the planned elevation position, the displacement of the planned position of the elevation peak and amplitude correspondence (Gorelov A.A. To the method of quantitative assessment of the mismatch of the structural plans of local elevations in connection with the study of their genesis // Directions and oil and gas prospecting and exploration technique (Southeast of the Russian Platform). - M.: Nauka, 1985. - P.58-62).

The disadvantage of this method is the lack of quantitative criteria for the localization of structures and the lack of quantitative characteristics of the priority of objects in order of further drilling. The disadvantage of this method is that it does not determine the displacement vector of local elevations.

There is also a method for determining the conformity of the structural plans of local elevations, in which, according to seismic and / or drilling data, a geological and statistical analysis is made of the frequency of displacement of the vertices of local elevations along different horizons of the section along a conventional coordinate grid oriented along the long and short axes of elevations (Khachatryan PO, Kostenko A.N., Surovikov E.Ya. Methodology for studying the discrepancy between the structural plans of oil and gas bearing local elevations // Oil and Gas Geology and Geophysics, 1988, No. 1, pp. 2-4).

The disadvantage of this method is the lack of quantitative criteria for the localization of structures and the lack of quantitative characteristics of the priority of objects in order of further drilling. And in addition, to predict the displacement of the tops of local elevations along uncharted deep horizons, additional seismic studies are necessary, and in the case of insufficient information on these horizons, deep wells must be drilled, which greatly increases the cost of research.

Also known is a method of deep structural mapping of oil and gas prospective elevations, characterized by a mismatch of the structural plans of different horizons of the sedimentary cover (RF Patent No. 2107314). The essence of the known invention: conduct reconnaissance, gravimetric and profile seismic (MOGT) measurements on two mutually orthogonal profiles that coincide with the directions of the long and short axes of local elevation along the base horizon, conduct a correlation analysis of the different frequency components of the gravimetric field and seismic data, according to the results of which anomaly gravity forces corresponding to the base and target horizons determine the modulus and direction of the displacement vector of the local vertex elevations and conduct areal gravimetric survey, orienting the profiles in the direction of the displacement vector, choosing the distance between points and profiles of not more than one third of the radii along the axes OX and OY of the autocorrelation functions of local gravity anomalies of the target horizon. The disadvantage of this method is the lack of quantitative criteria for the localization of structures and the lack of quantitative characteristics of the priority of objects in order of further drilling.

Closest to the proposed invention is a method of deep structural mapping, detection and measurement of latent structural targets and minerals (Auth. Certificate. USSR No. 1048441). In the known method, the deformographic characteristics of the curvature of at least one basic structural surface are measured along various directions in natural coordinates, while the density of discrete observations of the base surfaces is increased with decreasing radii of curvature, and the rest is mapped using surfaces that are deformed so that they map the rest geological environment and determine in it hidden structural target objects and / or minerals.

In the specified known method, the measurement of the deformographic characteristics is carried out along various directions, while the discreteness of the observations of the base surfaces is inversely proportional to the radii of curvature of the base surfaces, the obtained observations of the deformed surfaces in accordance with their evolutionary graphs, the fields of displacement of the geological environment during its deformation, as well as its geological structure and the composition of the rocks establish the deformographic functions of communication, which are then used to map the rest th geological environment.

Significant disadvantages of this method are the uncertainty of the azimuths and the number of directions along which measurements of the characteristics of the base surfaces are made, the lack of quantitative relationships between the base and the studied horizons, limited applicability in areas characterized by a relatively low ratio of structural plans for different horizons and, as a consequence, the difficulty of determining the displacement vector of the tops of local uplifts along different horizons of the sedimentary cover. A significant drawback of this method is the lack of quantitative criteria for the localization of structures and the lack of quantitative characteristics of the priority of objects according to the priority of further drilling.

The technical result of the invention is to increase the geological and geological information content of geophysical research, localization and ranking of prepared structures according to their prospects in preparation for exploration drilling.

The technical result achieved is achieved by the proposed method for preparing structures prospective for exploration drilling for oil and gas, according to which seismic measurements of MOGT are carried out on an area prospective in oil and gas potential, they process and structurally interpret seismic data, obtaining structural maps of target reflecting horizons (OG ), while new is the fact that, on the basis of structural maps, two-dimensional grids of target reflecting horizons are additionally constructed, Then, using the obtained two-dimensional grids of the target reflecting horizons, using the trend analysis method, we construct two-dimensional grids of the regional component Reg for each reflecting horizon, after which the local component Lok is calculated by the formula: Lok = ОГ-Reg, where ОГ is the reflecting horizon in meters, Lok is the local component in meters, Reg is the regional component in meters, the prepared structures for each target reflecting horizon are localized by the cells of the two-dimensional grid of the local component, while two conditions: the first - when Lok is greater than zero, and the second - when the zero isoline closes, set the sum of the local component ∑Lok for all target reflective horizons, while the local structure is considered prepared for all target reflective horizons with ∑Lok greater than zero, for The parameters of the selected localized structures for each reflecting horizon are calculated: A is the amplitude of the local structure and S is the area of the local structure, and the priority is according to the degree of readiness of the prepared structure for exploratory drilling for oil and gas is determined by the values of A and S, namely: the higher the indicated values of the local structure, the higher the prospectivity of exploratory drilling for oil and gas.

Distinctive features of the proposed method in comparison with the prototype are: 1) the presence of quantitative localization criteria (∑Lok> 0 and Lok> 0) of the prepared structures; 2) the possibility of quantitative characteristics in terms of parameters A and S of the local structure, the priority of objects in order of priority for further exploration drilling; 3) taking into account, when implementing the method, the directions of the displacements of the vertices of the prepared structures along the target reflecting horizons by using the parameter of the total local component ∑Lok.

The specified technical result is achieved due to the combination of operations of the proposed method and the use of new parameters and criteria.

The increase in geological and geological informativeness of geophysical research by the proposed method is due to the construction of two-dimensional grids of target reflecting horizons, the use of the trend analysis method to build two-dimensional grids of regional and local components for each reflecting horizon.

Also, the increase in the geological informativeness of geophysical studies by the proposed method is due to taking into account the direction of the displacement of the vertices of the prepared structures when summing the local components of ∑Lok for all target reflecting horizons.

Ensuring the localization of structures in preparation for prospecting and exploratory drilling in the claimed method is achieved by fulfilling two conditions: the first when Lok is greater than zero, and the second when the zero isoline closes.

Ensuring the preparedness of structures for prospecting and exploratory drilling in the claimed method is achieved when the value of ∑Lok is greater than zero.

Ensuring the ranking of prepared structures for prospects in preparation for prospecting and exploratory drilling in the claimed method is achieved by calculating the amplitudes and areas of local structures, as well as by taking into account the priority according to the preparedness of the structure for exploratory drilling for oil and gas, determined by the value A and S, namely: the higher the indicated values, the higher the prospectivity of exploration drilling for oil and gas.

The proposed method is illustrated by the following figures: Fig. 1 - two-dimensional grid for describing the surfaces of reflecting horizons; Fig. 2 - three-dimensional structural model of the target reflecting horizons; Fig. 3 - reflecting horizon Pc (the roof of the Vesan terrigenous deposits) in the south of the Perm Territory; Fig. 4 - the regional component of the reflecting horizon Pc; Fig. 5 is the local component of the reflecting horizon Pc.

The essence of the proposed method is as follows. MOGT seismic surveys are carried out, after which they are processed and structurally interpreted. Receive structural maps of target reflecting horizons (Ampilov, Yu.P. Seismic interpretation: experience and problems. - M.: Geoinformark, 2004. - 286 p.).

The resulting structural maps of the target reflecting horizons are described by the surfaces of two-dimensional grids using interpolation algorithms. The mesh size is predominantly 100 × 100 meters (Fig. 1). All target reflecting horizons are described by their own two-dimensional grids of a single dimension and represent a three-dimensional structural digital model, a section from such a model is shown in Fig. 2. In this figure, the spatial relationship of the various target reflecting horizons is clearly visible. Figure 3 shows an example of the constructed surface of one reflecting horizon Pc in the south of the Perm Territory within the Bysk-Kunur depression.

Then, from the obtained two-dimensional grids of the target reflecting horizon, using the method of trend analysis (Davis JS Statistical analysis of data in geology. - M .: Nedra, 1990. - Book 2. - 426 p.), Construct a two-dimensional grid of regional component Reg (Fig. 4) for each target reflecting horizon. After that, the local component is calculated (Fig. 5) according to the formula Lok = OF-Reg, where OG is the reflecting horizon in meters, Lok is the local component in meters, Reg is the regional component in meters.

Fig. 4 and Fig. 5 give examples of the practical construction of the surfaces of the regional and local components, respectively, in the south of the Perm Territory within the Bysk-Kunur depression.

Further, the prepared structures for each reflecting horizon (Fig. 2) are localized by the cells of the two-dimensional grid of the local component (Fig. 5), namely, by the quantitative condition Lok> 0 and provided that they are described by a closed contour.

To take into account the directions of the displacements of the vertices of the local elevations of the selected local prepared structures along the target reflecting horizons, the local component ∑Lok is summed. And by the quantitative criterion ∑Lok> 0, the final localization of the prepared structures is established.

Then, for the selected localized structures for each reflecting horizon, the parameters are calculated: A is the amplitude of the local structure and S is the area of the local structure.

Thus, for further exploration work, local structures with A and S have been prepared. With maximum values of A and S, the structures are considered the most prepared and promising for oil and gas. In Fig. 5, Roman numerals denote prepared structures in decreasing order of their prospects for oil and gas.

As can be seen from the data presented, the proposed method for preparing structures prospective for oil and gas in comparison with the known method (prototype) can increase the information content of geophysical research; to reduce geological risks due to quantitative criteria for the localization and ranking of structures in their preparation for exploration drilling.

The proposed method can be implemented using the seismic method in the study of complex geological environments.

Claims (1)

A method of preparing structures promising for exploration drilling for oil and gas, according to which seismic measurements of the MOGT are carried out on an area prospective in the oil and gas potential, processing and structural interpretation of seismic data is carried out, obtaining structural maps of target reflecting horizons, characterized in that based on structural maps additionally produce the construction of two-dimensional grids of the target reflecting horizons, then from the obtained two-dimensional grids of the target reflecting horizons, using a method of trend analysis, two-dimensional grids of the regional component Reg are constructed for each reflecting horizon, after which the local component Lok is calculated by the formula: Lok = ОГ-Reg, where ОГ is the reflecting horizon in meters, Lok is the local component in meters, Reg is regional component in meters, the prepared structures for each target reflecting horizon are localized in the cells of the two-dimensional grid of the local component, while two conditions are satisfied: the first when Lok is greater than zero, and the second when zero isol The loop closes, sets the sum of the local component ∑Lok for all target reflecting horizons, while the local structure is considered prepared for all target reflecting horizons with a value of ∑Lok greater than zero, for the selected localized structures for each reflecting horizon the parameters are calculated: A is the amplitude of the local structure and S is the area of the local structure, and the priority in terms of the preparedness of the prepared structure for exploration drilling for oil and gas is determined by the value of A and S, namely: the higher the indicated values of the local structure, the higher the prospectivity of exploration drilling for oil and gas.

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