RU2467356C2 - Method for seismic exploration of rocks - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to mining industry when exploring rocks. The method involves placing seismic locators on the earth's surface outside the scanning area, focusing radiation and receiving seismic waves through said locators. Each of the locators consists of a radiation areal aperture and a receiving areal aperture, in which radiation and receiving points are uniformly arranged, respectively. According to the invention, for each given point of scanning the investigated rock mass, a three-dimensional matrix of values of energy of scattered waves is obtained and an azimuthal vector diagram of the normalised energy of scattered waves is constructed. In this diagram, the direction of vectors is perpendicular to the scanning beams of the locators passing from the centre of the receiving aperture of each locator to the given point, and the scalar value of the vector is equal to the normalised energy of the scattered wave. Said diagram is identified with a fracturing rose diagram, in which the principal direction is the vector with the maximum value of the scattered wave, and the secondary directions are vectors with minimum values of the energy of the scattered wave.

EFFECT: high information content owing to the possibility of detecting differently directed fracturing in a geologic environment.

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Description

The present invention relates to seismic exploration, is intended to study the fracturing of rocks, as well as other heterogeneities in the geological environment, for example cavities (voids) filled with gas or liquid, and can be used to search for them in the geological environment.

The relevance of studying the fracturing of the geological environment when searching for hydrocarbon (HC) deposits is associated with high inflows of hydrocarbons in the wells drilled into the fracture zones, and has led to the creation of diverse seismic exploration methods that solve the problem of determining the spatial distribution of rock fractures in the geological environment and assessing the anisotropy of fracture directions in specific plots of land for optimization of hydrocarbon field development In a generalized form, methods for determining fracturing are presented in the publication [1, p. 92-105]. They are based on the use of characteristics of seismic specularly reflected waves (amplitude, spectrum, attenuation, velocity, coherence, distance, azimuthal directivity, etc.) and their transformation, taking into account the established correlations with fracturing. The disadvantage of these methods is the use of the characteristics of specularly reflected waves, which depend not only on the fracture, but also on many other factors, such as the structure of the lamination of the reflecting thickness, porosity, type of fluid saturation, stress state and other rock characteristics. Moreover, the influence of some of these factors on the characteristics of the reflected wave is greater than the fracture. Therefore, to study fracturing by the characteristics of specularly reflected waves, it is necessary to take into account and / or exclude the influence of other factors (layering, porosity, and other characteristics of these waves). Under real conditions of studying the fracturing of the geomedium (even in the presence of wells), it is impossible to exclude the multifactor effect on the characteristics of the specularly reflected wave in a sufficiently correct way to obtain results on the spatial distribution of fracturing with the necessary reliability.

There is also a known method of seismic exploration [2], which allows more reliable study of fracturing of the geological environment due to the fact that seismic scattered waves generated on the totality of open cracks are used.

This method consists in placing sources and receivers on the surface of the earth outside the studied rock mass, focused radiation and receiving seismic waves with their help, and subsequent processing of the obtained data. Before excitation and reception of seismic waves, the studied array is divided into cubic blocks and the emitted waves are focused to the center of each cubic block with in-phase summation of the waves at the receivers from the center of each cubic block for each radiation. When processing the obtained data, the energy of the waves from each center is determined, by the maximum values of which a three-dimensional image of a local diffracting object in the array is obtained.

The energy of scattered waves dominates (by ~ 90%) depending on the intensity (number) of cracks in the 1st Fresnel zone — the volume where the seismic signal of the scattered wave is formed. This volume has the form of a disk with a thickness in the center of h = 0.5λ and D = (2 · L · λ) ^0.5 , where L is the distance from the center of the areal reception system (aperture) to the studied point of the geomedium (center of the disk) and λ - seismic wavelength. Focusing of incident (from radiation points to a given point) and scattered (from a given point to reception points) seismic waves implements in-phase summation of seismic waves according to the travel time curves of the incident and scattered waves, respectively. The energy of the total scattered wave signal is identified with the intensity of fracturing in the volume of the 1st Fresnel zone centered at a given point in the geomedium, since there is a dominant relationship between the energy of the scattered wave and the intensity of fracturing. Using this method of seismic exploration, the total distribution of fracturing in the investigated volume of the geomedium and the shape of the local zones of anomalously high fracturing are determined.

The disadvantage of studying the fracturing of the geomedium by this method is the inability to determine the rose diagram of the azimuthal directions of fracture. When an elastic wave falls on the plane of the crack, the length of which significantly exceeds the size of the crack, a scattered wave is formed, the main energy of which propagates back and forth perpendicular to the plane of the crack [3], ie the crack has the directional characteristic of the formation of scattered radiation of an elastic wave (Fig. 1), which can be used when registering a scattered wave in different azimuthal directions of its propagation.

When a scattered wave signal is generated in the 1st Fresnel zone, where there is a collection of open cracks with different directions that determine the fracture anisotropy, the maximum energy of the scattered wave propagates in the direction perpendicular to the dominant crack propagation, and the minimum along this strike. If the set of cracks has a mono direction, then along this direction the energy of the scattered wave is practically absent and, therefore, such a zone of fracture cannot be detected (registered) by a receiving aperture, the line of sight of which coincides with this direction.

The objective of the invention is to increase the information content of the method due to the possibility of detecting differently oriented fractures in the reservoir.

The problem is solved in that in the known method of seismic exploration of rocks, including the placement on the Earth's surface outside the viewing area of seismic locators, each of which consists of an area radiation aperture and an area reception aperture, in which the radiation and reception points are equally located, respectively, focused radiation and reception of seismic waves with their help, subsequent processing of the received information, obtaining a volumetric matrix of scattered wave energy values at each point with According to the invention, for each given scan point of the studied rock mass, an azimuthal vector diagram of the normalized scattered wave energy is constructed, in which the directions of the vectors are perpendicular to the radar sight rays passing from the center of the reception apertures each locator to a given point, and the scalar value of the vector is equal to the normalized energy of the scattered wave, obtained from the corresponding the survey rays of each locator, and the above diagram is identified with a rose fracture diagram, in which the main direction of fracture corresponds to the vector with the maximum energy of the scattered wave, and the secondary directions of fracture correspond to the vectors with the minimum energy of the scattered wave.

At the same time, to increase the reliability of determining the main and secondary directions of fracture by the resulting rose diagram, it is advisable to review the studied rock mass from at least two locators located so that the specified scan points are viewed in at least two orthogonal directions. 2 locators are enough for these survey areas of the order of 1-2 km, and for large areas the number of locators should be taken more than two.

In order to normalize the values of the scalar magnitude of the vector, the energy of the scattered wave obtained for each locator at a given scanning point must be multiplied by the sum of the distances from the centers of the radiation apertures and the reception of the corresponding locator to the given scanning point.

To obtain the total field of fracturing, the normalized values of the energy of the scattered wave obtained from each locator are summed at each point.

In order to increase the reliability of detection of multidirectional fractures in a geological environment, it is necessary to conduct seismic observations from several locators whose receiving apertures are located on different sides of the study area so that all scanning points of the studied volume of the medium are surveyed by rays emanating from the center of the receiving apertures in orthogonal directions. In this case, the total fracture field obtained from all involved seismic locators contains all the fracture zones, including those with mono-direction of the cracks or a pronounced binary orientation of the set of cracks, i.e. anisotropy. To obtain a rose diagram of fracturing in an elementary volume (Fresnel's 1st zone) with a center at the focal point, a vector diagram is constructed consisting of vectors that have a direction perpendicular to the rays coming from the centers of the reception apertures to a given point and a scalar a value equal to the normalized energy of the scattered wave obtained from the corresponding survey beams from each locator.

The need for energy normalization is due to the fact that during the propagation of an elastic wave in the geomedium, its attenuation occurs due to the divergence of the wave front, absorption and scattering (at various inhomogeneities). Therefore, when determining the energy of scattered waves from locators located at different distances from the focal point, it is necessary to introduce a correction for the removal of the centers of radiation and reception apertures from the focal point. These deletions are calculated by the coordinates of the focus point (x _f , y _f and z _f ), the center of the radiation aperture (x _u , y _u and z _u ), the center of the reception aperture (x _n , y _n and z _n ) and the corresponding formulas:

L _u = ((x _u -x _f ) ² + (y _u -y _f ) ² ++ (z _u -z _f ) ² ) ^0.5 for the radiation aperture and

L _n = ((x _n -x _f ) ² + (y _n -y _f ) ² ++ (z _n -z _f ) ² ) ^0.5 for the reception aperture.

Since the energy of an elastic wave during focusing attenuates in direct proportion to the distance, the obtained values of the energy of the scattered wave at the focal point from each locator are normalized (divided) by the sum of the distances (L _u + L _n ) of the centers of the radiation apertures and the reception of the corresponding locator to the focal point. After such a conversion, a vector diagram of the normalized values of the energy of the scattered wave is obtained.

Considering the dominant dependence of the energy of scattered waves on the intensity of fracturing, the constructed azimuthal vector diagram is identified with a rose diagram of fracturing in the elementary volume of rocks of the geomedium where the scattered wave is formed. Moreover, since the propagation of scattered waves from a set of cracks occurs in accordance with the characteristic (diagram) of the directionality of this aggregate, the resulting rose fracture diagram reflects the azimuthal heterogeneity of the fracture, and it is used to judge the presence of the main and secondary directions of open fracture in the elementary volume.

The method is implemented as follows.

A seismic locator consisting of radiation and reception apertures is mounted on the day surface outside the contour of the survey, in which emission and reception points in the order of 100 for each aperture are placed uniformly (according to the schemes of a star, spiral, torus, square, etc.). Locators are placed so that each point is surveyed in several orthogonal directions from the centers of the reception apertures. A seismic wave is excited at the radiation aperture (explosion, shock or vibration), focus it with the help of the calculated time delays at a given point at which a scattered wave propagates to the day surface, including the area where the receiving aperture of this locator is located. Reception of the scattered wave is carried out using the calculated time delays realizing focusing at the same given point as when focusing the excitation aperture, and obtaining the energy of the scattered wave at the focus point. This energy is normalized to the sum of the distances from the centers of the apertures of radiation and reception to the focusing point. This operation for a given locator is repeated for all points of scanning the volume of the medium under study, as a result of which a 3D fracture field is obtained when viewing from a single locator. A similar 3D fracture field is obtained using other locators. The normalized values of the energy of the scattered wave received from each locator are summed at each point and a common field of fracture is obtained, in which the influence of anisotropy of the direction of fracture of the geological medium is excluded. For given points of scanning the volume under study, rose fracture diagrams are constructed as follows. At a given scanning point in directions perpendicular to the viewing rays, from the center of the receiving aperture of each locator that surveys a given point, a line vector is applied with dimensions of 0.5 of the normalized energy value (in arbitrary units) on both sides of the specified point. All values of the normalized energy are plotted on a single scale. The main direction of fracture corresponds to a line-vector having a maximum size.

Examples of the implementation of the method of seismic exploration of rocks are illustrated in figure 2, 3, 4A and 4B.

Figure 2 presents the location of the locators relative to the viewing area.

Figure 3 shows the total map of the distribution of fracturing for the studied viewing area.

Figures 4a and 4b show the constructed rose fracture diagrams for given scan points using 4 and 2 locators, respectively.

To study the fracture field in the viewing area with dimensions of 3 × 3 km, four locators were used, located outside the studied area from its four sides (Fig. 2), forming a system along which an orthogonal survey of points distributed uniformly along the x, y axes is possible z in increments of Δx = Δy = 25 m. The reception and emission points in the corresponding apertures are arranged in the form of a spiral, forming an areal seismic antenna with a relatively uniform directivity. The aperture size is 1200 m in diameter and the number of observation points is 100. For each locator, based on the focusing transformation of the emitted and received seismic wave field, maps of the distribution of fracture and a total map for the studied area are obtained. On the resulting map (figure 3) there are all local zones that were not identified by individual locators due to the azimuthal anisotropy of the fracture in these zones. For given points according to normalized energy (from each locator), rose fracture diagrams were plotted on the area area where horizontal drilling is planned (Fig. 4a). The horizontal borehole trajectory is carried out orthogonally to the main direction of fracturing of the oil reservoir rocks, since when this condition is met, the flow of oil into the drilled well increases significantly.

A similar example of determining rose diagrams for the same purpose of choosing the optimal drilling path for a horizontal well is shown for an area of 1.5 × 1.5 km (Fig. 4b), where 2 locators were worked out, one of which is located on the eastern side of the area and the other - from the south. The horizontal drilling path is defined in the direction perpendicular to the main fracturing vector.

Literature

1. Kuznetsov O. L., Chirkin I. A., Kuryanov Y. A., Rogotsky G. V., Dyblenko V. P. Experimental research. - M.: SSC RF - VNIIgeosystem, 2004. - 362 p. (Seismoacoustics of porous and fractured geological media: in 3 vols. T.2).

2. RF patent for the invention No. 2008697, class. G01V 1/00, publ. 1994.02.28.

3. Kuryanov Yu.A., Kukharenko Yu.A., Rock V.E. Theoretical models and seismoacoustics of porous fractured media. - M.: SSC RF - VNIIgeosystem, 2002. (Seismoacoustics of porous and fractured geological media: in 3 vols. T.1).

Claims (4)

1. A method of seismic exploration of rocks, including placing on the Earth's surface outside the study area of seismic locators, each of which consists of an area radiation aperture and an area reception aperture, in which the radiation and reception points are respectively located, focused radiation and reception with their help seismic waves, the subsequent processing of seismic information, obtaining a volumetric matrix of the energy values of scattered waves at each scanning point, the values of which are judged b the volume distribution of fracturing in the rock mass under study, characterized in that for each given scan point of the rock mass under study, an azimuthal vector diagram of the normalized scattered wave energy is constructed, in which the directions of the vectors are perpendicular to the radar survey rays passing from the center of the reception apertures of each locator to a given point, and the scalar magnitude of the vector is equal to the normalized energy of the scattered wave obtained from the corresponding survey rays of each locator, and the specified the diagram is identified with a rose fracture diagram, in which the main direction of fracture corresponds to the vector with the maximum energy of the scattered wave, and the secondary directions of fracture correspond to the vectors with the minimum energy of the scattered wave. 2. The method according to claim 1, characterized in that the survey of the studied rock mass is carried out from at least two locators located so that the specified scan points are viewed in at least two orthogonal directions. 3. The method according to claim 1, characterized in that for normalizing the values of the scalar magnitude of the vector, the energy of the scattered wave obtained for each locator at a given scanning point is multiplied by the sum of the distances from the centers of the radiation apertures and the reception of the corresponding locator to the given scanning point. 4. The method according to claim 1, characterized in that in order to obtain a common fracture field, the normalized values of the energy of the scattered wave obtained from each locator are summed at each point.

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