UA10354A - Method for seismic survey - Google Patents

Abstract

Method for geological survey prescribes excitation of vibrations with well sources, reception of vibrations with surface seismic-receivers, registration of direct wave, integration of seismic records at reversed continuation of wave fierld and focucing direct wave in source, determination of spatial orientation of fine-stratification of cut rocks. The invention relates to geophysical methods for survey and search of mineral beds and can be used at seismic susrvey of fine-stratified and fractured anisotropic geological media in deposit pools of oil-gas bearing regions.

Description

The proposed invention relates to geophysical methods of prospecting and exploration of mineral deposits and can be used in seismic exploration of thin-layered and fractured anisotropic geological environments in sedimentary basins of oil and gas-bearing regions.

There is a known method of seismic exploration, which provides for the excitation to oscillate sequentially at points located along the ground profile passing through the well, where at a pre-selected depth below the sharp reflective boundaries in the upper part of the section, a seismic receiver is installed that receives reflected waves from below the underlying boundaries of the section 1). The disadvantage of the method should be considered weak protection against high-speed interference waves when the target reflected waves are isolated.

There is a known method of seismic exploration, based on the estimation of the anisotropy index of the medium in relation to the interval times and velocities, obtained by using the longitudinal and transverse reflected waves of the method of multiple profiling without involving the observed well data (2. The disadvantage of the method is the low accuracy of determining the elements of the radial velocities.

The most modern and closest in terms of technical solution to the proposed method is the method of seismic exploration, based on the excited vibration in the well, reception of the vibration by seismographs of the ground rectilinear profile passing through the mouth of the wells, registration of direct waves, processing and transformation of seismic records, evaluation of values of the revealed radial velocity predominant orientation of fracturing and microlayering |Z). The disadvantages of the method include the low accuracy of determining the anisotropic parameters due to the low resolving power of the systems! observed

The basis of the proposed invention is the task of improving the technique of seismic exploration of thin-layered and fractured geological environments by evaluating the anisotropic characteristics of rocks and determining the spatial orientation of the ordered fracture and rhythmic microlayering of sedimentary deposits based on the elements found in the following indicators! radial velocities.

The task is solved by the fact that in the proposed method of seismic exploration, which provides for the excitation of oscillations by borehole sources, reception of oscillations by ground seismographs, placement on a straight line profile passing through the mouth of observation wells, registration of a direct wave, summation of seismic records with an inverted extended wave field and focusing of a direct wave in the source , determination of the predominant orientation of rhythmic thin layering and ordered fracturing, according to the invention, the source is placed at a given depth of 7 » X in the well, where X is the length of the recorded wave, ground seismic receivers are placed uniformly with a step of 0.5 A within the surrounding area of the well, size! which is two or more times greater than depth 7, form an image of a fictitious source Оо(хо; Ус) in the studied medium by summing seismic records at the inverted extension of the observed field with a given effective velocity Mzf, determine the element! zlllipticheskoy indicate! radial speed

Mio Uz U, 2 - 12 U Ho" (w ho)

Huh? (2-03? 1.

H 2xHoi: 2 r ho? Z202-2:17 " where Mi and M»2 are the maximum and minimum values of the radial velocity, respectively, and f is the angle of inclination of the major semi-axis of the indicator to the 07 axis, find the spatial orientation of the rhythmic thin layering and ordered fracturing of the rocks under the conditions that the maximum value of the radial velocity corresponds to the direction of wave propagation along the layering of rocks, and the minimum velocity value corresponds to the direction of wave propagation perpendicular to the layering.

The advantages of the proposed method are that thanks to 1) excitation of a direct wave by a borehole source and its registration by ground seismographs, 2) formation of an image of a fictitious source in the anisotropic medium under study, 3) obtaining estimates of the values of the elements of the radial velocities based on the difference in the position of the true and fictitious sources in space, 4) determination of the predominant orientation of rhythmic thin layering and ordered fracturing of rocks, the extraction of additional geological information in the form of anisotropic characteristics of sedimentary deposits associated with fracturing, thin layering, etc. is ensured.

The proposed invention is explained by a drawing (Fig. 1), which shows the scheme of the implementation of the proposed method of seismic exploration, which includes a well oscillating source 1, ground seismic receivers 2, arranged in a uniform sequence within the surrounding area of the observation well on a rectilinear profile aligned with the axis of of radial velocities, the elements of which are the major semi-axis 4, corresponding to the largest value of the radial velocity, the minor semi-axis 5, corresponding to the smallest value of the radial velocity 6 and the angle 7 of the inclination of the major semi-axis of the indicatrix of the scythe 07, the hodograph 8 of the registered wave, the image 9 of the fictitious source obtained in the process of inverted continuation of the observed wave field.

The method is carried out by the following sequence of operations. Place an oscillating source in the well at a given depth 7 » X. Place ground seismographs with a half-wave step within the surrounding area of the well on a rectilinear profile passing through the mouth of the wells, the size of which is two or more times greater than the depth 7 of the source placement. The reception of excitation oscillations is carried out. Direct wave registration is made. An image of a fictitious source Оо(хо: Уо) is formed in a given area in the middle of the image by summarizing seismic recordings in the process of reverse extension of the wave field with a given effective speed and focusing direct waves in the fictitious source. Find the coordinates of Ho. According to the fictitious source Sho. The problem is indicated! velocities M., M»2, f and its spatial position. They find the preferred orientation of rhythmic thin layering and ordered fracture of rocks by determining the direction of wave propagation along the layering of rocks, which corresponds to the maximum value of the radial velocity, and the direction of wave propagation perpendicular to the layering of rocks.

Example of implementation of the method.

The capabilities of the proposed method of seismic exploration are demonstrated on the example of studying a two-dimensional model of a transversely symmetric anisotropic medium. The elliptical indicator of radial speeds has the following parameters: Mi - 3.00 km/s; Mo is 1.35 km/s, the angle of inclination of the major axis of the ellipse to the 027 axis is 45".

The parameters of the installation were observed: - an oscillating source was placed in a well in which a vertical profile was located, at a depth of 7 - 0.6 km: - seismographs were placed on the ground profile, aligned with the axis of the axis, with a step equal to 25 m in the surrounding area of the wells, the size of which equal to 1200 m.

The registration time of the first incoming direct waves! bring it! in the table.

The effective speed, determined by the direct wave hodograph, is equal to the Uzf value - 1.75 km/s.

The coordinates of the fictitious source POo (Hozuso), found in the process of inverse extension of the observed wave field and focusing of direct waves into the source are equal! Ho - 0.4 km, 20 - 0.45 km.

Accepted for calculations the values of the coordinates of the reception points and the length of the radiation rays! in table 1. At the same time, the origin of the coordinates is combined with the mouth of the observation wells!.

The interpretation of the observed data gives the following values of the elements indicated! radial velocities:

Mi - 3,013 km/s, Mo - 1,342 km/s, r-457. Measurement errors are less than 0.5 95.

The proposed method can be effectively applied in seismic exploration of thin-layered and fractured isotropic geological environments and, above all, in the study of the structure of the inter-reference space in sedimentary basins.

The proposed method should be considered as a new, effective tool for studying the structure, properties, and state of the geological environment using the model of an elastic, homogeneous, anisotropic space.

The wide implementation of the new method in geophysical production will contribute to a significant increase in the geological efficiency of oil seismic exploration in conditions where the known method of seismic exploration, based on the used model of an elastic, homogeneous, isotropic medium, does not provide solutions to geological exploration problems of a detailed melt. and Abecys- | | ! and sassi | | and (ikmu. "04 0 0 p pa About her o8 her

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