RU2030766C1 - Method of seismic prospecting - Google Patents

Abstract

FIELD: geophysical prospecting. SUBSTANCE: method of seismic prospecting provides for synchronous emission into geological medium of longitudinal waves P and waves SH lateral to horizontal polarization and for undestorting registration of each of medium by means of symmetric four-projection geophones which sensors are uniformly distributed in azimuth and are inclined at angle of 45 deg to horizontal line. Emission and reception of seismic waves conducted in this way create favorable conditions for use of procedure of subtraction of wave fields to divide observed superposition wave field into three linear-polarized (waves P, SV and SH) and summary nonlinear-polarized physical components. As a result there appears possibility to study geological section both with separate seismic waves of various types and with their combination on the whole. EFFECT: expanded prospecting capabilities of method. 5 dwg

Description

 The invention relates to applied geophysics and can be used in land seismic exploration.

 Currently, seismic exploration methods are characterized by low efficiency in obtaining information about the geological structure of the studied section.

The closest solution in terms of technical essence is a receiver system for seismic exploration consisting of geophones, each of which comprises three sensors, raspolo- conjugated at an angle ^of 45 ° to the horizontal plane. When processing recorded seismic signals from the total wave field as a result of multiple sequential application of the operations of directional summation and subtraction to the records of all three projections, the regular and irregular components of the initial field are calculated in their real form.

 The disadvantages of the known technical solution is the low efficiency in obtaining information about the geological structure of the studied section as a result of the fact that the obtained fields are not monotypic.

 The basis of the invention is the task of increasing the geological efficiency of seismic surveys on land based on the simultaneous study of the geological section by a combination of longitudinal and transverse elastic waves, subject to optimal conditions for a comprehensive interpretation.

The problem is solved by the fact that simultaneously excite elastic waves of P - and S-type. Registration is performed geophones, each of which comprises four sensors disposed at an angle of ⁴⁵ ° to the horizontal plane and evenly spaced in azimuth. Further, when processing the obtained records, the rectangular Cartesian coordinates of the total wave field vector at each receiving point are calculated according to known relations. By comparing the modules of the four projections recorded at each receiving point with the full vector module at this receiving point, three monotypic linearly polarized PP, SV, SH-type waves and a non-linearly polarized wave are used that are used as a useful signal.

 The invention consists in the following.

At the receiving point, a combination of the following geological significant reflected waves can be observed: three monotypic waves - PP, SV and SH - and two exchange waves - S _v P and PS _v . Use of geophones, each consisting of four sensors, inclined to the horizontal at an angle ^of 45 and distributed uniformly over the azimuth circle, i.e. through 90 ^° , it allows at the receiving stage to ensure the registration of the observed wave fields in their natural dynamic range, not distorted by any input transformations. It is known that such a symmetric tetro-projection installation has the absolute invariance of its reaction to vertical and horizontal displacements of the receiving point. The orientation of the sensor relative to the line ppofilya observation angle ^of 45 provides the maximum possible accuracy of the calculation of the Cartesian projections full wave motion vector.

The projections I, II, III, IV obtained by the sensors can be decomposed into the following physical components of the same type at the reception:
1) The field of waves recorded as longitudinal linear polarization, i.e. refracted (refracted) P, reflected PP and exchange reflected S _v P.

2) The field of waves recorded as transverse to vertical linear polarization, i.e., refracted (refracted), reflected S _v and exchange reflected PS _v .

3) The field of waves recorded as transverse to horizontal linear polarization, i.e. refracted (refracted), reflected S _n .

 4) The field of nonlinearly polarized waves, represented mainly by surface Rayleigh and Love waves.

The procedure for dividing the observed complex seismic field into physical components of the same type at the reception begins with calculating the rectangular Cartesian coordinates of the wave motion vector at the receiving point using the following system of algebraic formulas:
X = 0.50,000 (I-II-III + IV)
Y = 0.500000 (I + II-III-IV)
Z = 0.35355 (I + II + III + IV)
The resulting traditional projections are synchronous and spectrally identical. The projections X, Y, Z are already largely monotyped, i.e., they indicate the correspondence to certain types of linearly polarized waves. However, they contain other projections, therefore, at the next stage of application of the separation procedure, each of the projections X, Y, Z is cleaned of types of wave fields that are not characteristic of it. In practice, this boils down to the calculation of three seismograms of the prevailing projections, which can already be safely identified with certain wave fields, moreover, the more precisely, the stricter the accepted criterion of predominance.

Seismograms of the prevailing projections X _pr , Y _pr , Z _{pr are} found by sequentially comparing the modules of Cartesian projections with the full vector module and selecting those that are not less than 0.95 of the latter. The achieved degree of monotyping - 95% - is high enough for practical seismic exploration purposes, but the obtained prevailing projections contain separate samples belonging to a nonlinearly polarized component.

In order to get rid of them and thus obtain clean monotyped wave fields, the projections of the prevailing projections onto the directions of the sensors 1, 2, 3, 4 are determined. Then, the projections to these directions of the seismograms of the prevailing projections X are subtracted from the registered projections I, II, III, and IV _pr and Y _pr , as well as a seismogram of nonlinearly polarized waves. The obtained difference is calculated projected Cartesian coordinate Z that corresponds to the field of longitudinal elastic waves R. Similarly, after subtraction of the projections for the respective projections of Y and Z _{pr pr} determined by obtaining a difference Cartesian coordinates x, which corresponds to the field vertically polarized shear elastic waves S. And finally, after subtracting the nonlinearly polarized component and the corresponding projections Zpr and Xpr from the registered projections, they find the Cartesian coordinate Y, k Thoraya corresponds to the field of transverse elastic SH horizontal polarization waves. This completes the procedure for separating the recorded complex seismic field into monotypic physical terms.

 As follows from the above description, the receiving element of the proposed method is a seismic receiver, including four sensors, has at least two new properties that cannot be realized by any of the known analogs, namely, exactly the same reaction to different types of wave movements and the possibility of metrological control of amplitude identity sensors forming the geophones.

 In addition to the above-mentioned advantages of these seismic receivers, they have another very important property - the presence of a fourth sensor allows for countable metrological monitoring of the amplitude identity of the sensors of the tetraseismic receiver by comparing the modules of four partial vectors calculated over triples.

 The separation of the observed in reality wave fields into elementary (monotypic) physical components, which have predominantly linear polarization, and the total nonlinearly polarized component distinguishes the claimed method from seismic methods known today. Its advantages are due to the fact that if there are at least three seismic surveying projections at each of the receiving points, solving the problem of separation of the observed wave field reduces to iterative application of the wave field subtraction procedure, which is much less time-consuming than procedures of the type of controlled directional reception, if necessary, used with the same purposes in those cases when single seismic trajectory-projections are recorded at the points of reception. As is known, the maximum efficiency of applying the subtraction procedure in the time domain is ensured only in the case when the components of the shared field, the elementary waves are synchronous with each other, and upon reception they undergo the same spectral changes.

In the claimed method, both of the above conditions are met. Compliance with the first condition - synchronism - is ensured by the use of pulsed sources, simultaneously emitting the most geologically informative elastic waves, i.e. longitudinal and transverse horizontal polarization. Compliance with the second - the identity of the amplitude-frequency characteristics of reception paths - provided by the use of geophones, each consisting of four identical sensors inclined to the horizontal at an angle ^of 45 and distributed uniformly in azimuth.

 Figure 1 shows three orthogonal Cartesian projections of the full wave field, and figure 2 shows the corresponding seismograms of the prevailing projections; figure 3, 4 and 5 shows the results of the first two steps of the field separation procedure (or monotyping) for each of the Cartesian projections.

 Only those projections that exceeded the sum of the other two in absolute value were taken to these seismograms (in this case, the degree of polarization in this direction is at least 90%). Therefore, these seismograms are indicated by the corresponding types of elastic waves.

 The obvious difference between the seismograms in Figs. 1 and 2 indicates both the operability of the proposed field separation procedure and the presence of foreign projections in traditional seismograms. The latter fact suggests that putting an equal sign, for example, between the reaction of a vertical seismic receiver and longitudinal waves, as is done to date, is at least not justified. Neglect of this fact can lead to errors, especially in the results of energy transformations of seismic traces such as pseudo-acoustic logging.

 From Figs. 3, 4 and 5 it follows that since the nature of monotyped seismograms is determined mainly by the degree of complexity and features of the geological structure of the earth's interior, monotyped seismograms are an excellent material for geological and geophysical interpretation and study of the material composition of a geological section.

 In the industrial use of the method, when choosing the parameters of the observation scheme, it is necessary to take into account the obvious universality of the claimed system with respect to the types of elastic waves used.

 Synchronous radiation of the two most geologically informative elastic waves P and SN is carried out by vertically horizontal impact on a plate with spikes on the side in contact with the ground. To ensure an acceptable power of radiated elastic waves of P- and S-type and a sufficiently high signal / noise ratio, it is advisable to use group sources consisting of 4-5 elements with mandatory accumulation of effects.

 The distance between the points of reception is reduced by 2 times compared with those calculated on the use of only longitudinal waves. In this case, it is necessary to slightly increase the overlap rate along the profiles of the MOGT, since reception is preferably carried out with single tetraseismic receivers.

 The principal workability of the proposed seismic survey method was carried out under seismological conditions in the central part of the Caspian Depression, where rock salt with interlayers of terrigenous sediments lies in the depth range of 0.7-5.5 km, and reflections of longitudinal waves from subsalt horizons are recorded in the range of 3.1-4 , 1 sec

As a source of elastic vibrations, generators of sesmic vibrations of the GSK-6 type were used (pulsed action on the soil of the vertical force type). Reception was carried out using home-made three-projection symmetric installations with a tilt of the sensors at an angle of 45 ^about . The distance between the points of reception was 50 m, each physical observation consisted of 64 tracks. The range of removal points from the source was 0.1-3.3, 25 km, the recording time was 5 cm.

Claims (1)

METHOD OF SEISMIC EXPLORATION, including the excitation of elastic vibrations, their registration by geophones, each of which contains three sensors located at an angle of 45 ^o to the horizontal plane, and processing the obtained records with the selection of a useful signal, characterized in that the elastic waves P- and S are simultaneously excited -type, registration is carried out by geophones, each of which additionally contains a fourth sensor, while all sensors are evenly distributed in azimuth, when processing the received records, they are calculated the rectangular Cartesian coordinates of the total wave field vector at each receiving point by comparing the modules of the Cartesian projections calculated at each receiving point with the full vector module at this receiving point, three monotypic linearly polarized waves of PP-, SV-, SH- type and nonlinear polarized wave, which is used as a useful signal.

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