SU1056111A1 - Vertical seismic profiling method - Google Patents

Abstract

A VERTICAL SEISMIC PROFILE METHOD, including the excitation of oscillations by a source located at an excitation point in the near-surface part of a geological section, a three-component reception of oscillations at reception points at two seismic receivers, the first of which is located in a well, reflected transposition correlation of reflected waves at seismic records, the first of which is located in a well, reflected transposition correlation of reflected waves at seismic records, the first of which is located in a well, and the transpositional correlation of reflected waves on seismic records, the first of which is located in a well, the transpositional correlation of the reflected waves on seismic receivers, and obtained in wells 1n and at the second placement of seismic receivers, the determination of three-component seismic records of the spatial position beam segments along which the waves propagate as they approach the points of reception in the well, which is so as to improve the reliability and accuracy of determining the spatial position of seismic boundaries located under the sharp refractive and reflecting boundaries, the second arrangement of seismic receivers located in the subsurface part of the geological section, on the orthogonally located profiles x intersecting at the point of excitation, and the length of each of the orthogonal profiles is chosen with measurable with the length of the recorded wave, while receiving oscillations in the second placement of the seismic detectors is carried out from additional excitation points that coincide with the receiving points located in the well above the studied boundary below with (О sharp reflective and refracting (L boundaries, after receiving oscillations of the first well, the arrangement of seismic receivers from the subsurface excitation point using transpositional correlation identify the reflected waves obtained at the first and second arrangements of seismic The detectors, determined by the gradient of the wave field, observed at the second O5 arrangement of seismic receivers, the spatial position of the seismic ray sections, which oscillate approach the intersection point of the second arrangement profiles, are determined according to the law of refraction the spatial position of the ray sections located above the boundary of interest and the position of the most closely located points of these areas in the vicinity of the boundary of interest are judged on the position of the reflection points.

Description

The invention relates to borehole seismic surveys and can be used to study the spatial position of deep seismic boundaries that are under inconsistently lying formations that differ sharply in their physical properties. Mo The method of vertical seismic profiling by reflected waves is known in which elastic oscillations are recorded by a probe located in the below upper sharp reflective boundaries, and excite oscillations by sources located at different distances from the points of reception in the borehole 1} .. A disadvantage of the known method is the impossibility of determining the spatial position of the beam connecting the excitation point and the reflection point at the boundary under study. Also known is a method of vertical seismic profiling, including the excitation of elastic oscillations at the excitation points located below the sharp refracting and reflecting boundaries located in the overburden sediment, and three-component recording of oscillations at reception points located above these boundaries Is the impossibility of accurately determining the spatial position of the sections of the rays approaching the observation points. The closest to the proposed technical solution is a method of vertical seismic profiling, including the excitation of oscillations by a source located at the point of excitation in the near-surface part of the geological section of the three component reception of oscillations at reception points at two locations of seismic receivers, the first of which is located in the well, transpositional correlation waves on seismic records obtained in the well and in the second alignment of seismic receivers, the definition of three mponentnym seismic records The space m. the actual position of the ray segments along which the waves propagate as they approach them at the reception points in the well C3J. The disadvantage of this method is the low accuracy of determining the spatial position of the beam connecting the extraction point and the reception point at the second array of seismic receivers located on the earth's surface, due to measurement errors associated with high variability of the characteristics of the low velocity zone. The aim of the invention is to improve the reliability and accuracy of determining the spatial position of seismic boundaries located under sharp refractive and reflecting boundaries. "PostE" is the objective that is achieved according to the method of vertical seismic profiling, including excitation of oscillations by a source located at the excitation point in the subsurface part of the geological section, a three-component reception of oscillations in reception points at two arrangements of seismic receivers, the first of which is laid down in the well, the transpositional correlation of reflected waves on seismic records obtained in the well and the second arrangement of seismic receivers, the determination of the spatial position of the beam segments by the three-component seismic records, which propagate along the waves to the receiving points in the well, the second arrangement of the seismic receivers is located, in the subsurface part of the geological section, on orthogonal profiles x intersected at the point of excitation, the extension to Each of the orthogonal profiles is chosen commensurate with the recorded wavelength, while receiving oscillations in the second arrangement of seismic receivers is carried out from additional excitation points coinciding with reception points located in the well above the investigated boundary under sharp reflective and refractive boundaries after receiving oscillations of the first the borehole placement of seismic receivers from the subsurface excitation point using transpositional correlation identify the waves obtained in the first and second The installations of seismic receivers, determined by the gradient of the wave field observed at the second assignment of seismic receivers, the spatial position of the seismic ray sections, which oscillate to the intersection point of the second alignment of the seismic receivers, is determined in accordance with the law of refraction of the spatial location of the ray sections located above the studied boundary, and according to the position of the most closely located points of these sections in the vicinity of the investigated boundary, the position of the reflection points . The drawing shows a scheme that implements the proposed method Scheme ccfftepiKHT drilling tower 1, well 2, wells, receiving points 3, on the first arrangement of seismic receivers located in the well, point of initiation, second arrangement of 5 seismic receivers consisting of orthogonal profiles, earth surface 6 , intermediate sharp reflecting and refracting boundaries 7 and. 8, and the following reflecting boundary E, points 10 in the borehole, from which elastic oscillations additionally excite, reflection point 11, beam segments 12-15 along which the once reflected waves propagate, beam segment 16 along which the multiple reflected wave propagates, seism . receivers 17. The method is carried out as follows. When oscillations near the surface are excited at the {W) excitation point and three-component oscillations in well 2, polarization analysis determines the angles of the seismic rays approach to the receiving points 10 located in the well and the azimuths of the 15-ray beams in the last parts of their path from the source oscillations to the receiver. Since the position of point 11 of the reflection on the boundary of E, which is of exploratory interest, is unknown (it is the desired one), then by applying the law of refraction, does MOXWO restore the spatial position of the seismic part of the seismic ray, which is enclosed by the mechanism {reception point, and the reflection point. The spatial position of the other part of the beam, which is between the excitation point and the reflection point, remains uncertain in the known methods of vertical seismic profiling (VSP). To determine it, a second arrangement of seismic receivers on orthogonal profiles 5 intersecting in the near surface part is necessary. geological section. Registration of elastic oscillations by seismic receivers 17 of the location 11. 4 placed on these orthogonal profiles x, with additional excitation of oscillations at several points 10 in the well, coinciding with the points of reception in the same well, makes it possible to determine the spatial position of the reflected wave beam in section 12 adjacent to the point of excitation. according to the components of the gradient of the wave field, calculated along each of the orthogonal profiles intersecting at the point of excitation "If F tt 5, c is the unit sector that coincides in direction with matrivaemym end segment of the beam; t is the time of registration of the reflected wave at the reception point located on each of the orthogonal profiles; V is the speed. (The reciprocal of the gradient); a, b, c are the direction cosines of the vector r Then the axis along each of the axes X and Y that are orthogonal to each other and coincide with the orthogonal profiles. Knowledge of the spatial position of the vector T allows, in accordance with the law of refraction, to determine the spatial position of the remaining segments 13 and It of the beam enclosed between the HPV and reflection point 11. The position of the reflection point 11 is determined by extrapolating both. the beam segments, one of which is .15, are between the point of reception in the well and the reflection point, and the other consisting of the segments 16, 13 and 12 is between the point of excitation and the point of reflection. Due to measuring and computational errors, both parts of the beam can intersect, therefore, the center of the segment connecting the most closely located points of the directly overlapping points, the direction of which is close to the direction of the segments, and 15 rays of the reflected wave belonging to both considered parts, is taken as the reflection point. of the beam and located in the vicinity of the desired point of my 11 "Refine the spatial position of the beam of the reflected wave using the method of successive approximations, using theoretically calculated The observed and observed arrival times of the wave, and as the initial approximation, the spatial position of the beam, determined using the techniques described above. When a joint is bored at a point 10 located between the sharp reflecting boundary 8 contained in the overburden and the reflecting boundary 9, which is the object of exploration, wave 16 propagates upward from point 10, which is a source of multiple reflected waves, reflecting reflections from day surface 6 and boundaries 7 and 8, as well as between boundaries 7 and 8 "If in seismic recording , obtained by means of seismic detectors 17, on profile x 5 when oscillations are excited in Kahadi from several points 10, marked by crosses, introduce time shifts that compensate for the difference in arrival times of the recurrently reflected wave from excitation points 10 located in the miHe at different depths and to sum up the obtained seismic recordings, t „to perform vertical summation, this will succeed in suppressing the multiple reflected waves of type 16, in which the initial segment of the beam is located above the source of oscillations, reinforcing at the same time reflected waves The scheme works as follows. From PV h, the entire borehole 2 is worked out by moving the three-component VSP probe along the borehole with a step of 10–20 m. The PV C is removed from well 1 for a distance not exceeding the depth of the reflecting boundary. From the VSP seismograms, sharp reflecting and refracting boundaries, under these boundaries, at several receiving points, the distance between which is a multiple of the observation step in VSP (20-40 m) additionally excite elastic oscillations by an explosive or non-explosive source. Oscillations on two orthogonal Profiles 5, point The intersections of which are compatible with the PV (“The length of each of profiles 5 is several times greater than the length of the reflected wave, which is of interest for exploration, the distance to the gateway by seismic receivers 17 is several times smaller than the wavelength of 16 s (10-25 m, during high-resolution seismic exploration, it is reduced to 5 mD. The reflected wave on the vertical profile and on the orthogonal profiles x is recovered by known methods based on the transpositional correlation of waves on the vertical and unearthly (horizontal) profiles x. For a single reflected wave of the same type, the time of wave propagation between the end points 10 and (and the spatial position of the beam will be the same as when oscillations are excited at point 10 and at point (Therefore, the transpositional correlation of the reflected wave in the absence or inessential influences such as interferences, such as multiples, are carried out unequivocally. If high interfering intensity makes it difficult to confidently determine the arrival times of reflected waves on the seismic record x recorded by the seismic Receivers 17, then apply the summation of seismic records obtained from different depths of the explosion after the corresponding time shifts are recorded in the recordings. The orthogonal components of the surface hodograph are calculated from the recording times of the reflected wave on profiles x 5. After determining the spatial position of the segments 12-15 the beam of the reflected wave, the coordinates of the points of intersection by the beam of the borders are used as an initial approximation for subsequent more accurate calculations by methods of numerical analysis. This convergence and high accuracy allowed us to obtain the Newton-Raphson method. The refined position of the seismic beam passing through the EF and those points of the vertical Profile where additional excitation of elastic oscillations was carried out is used as an initial approximation in calculations concerning the adjacent VSP reception points, of which, elastic oscillations were not additionally excited. The data for these neighboring points is used as the initial approximation for the subsequent neighboring points VSP and ToDr until all the reflection points 11 are constructed for the corresponding beams coming out of the PV C and appropriate after the reflections on the border 9 to the corresponding reception point 3 on the vertical profile. The geometrical location of the points of reflection allows judging the spatial position of the boundary 9 under investigation. Additional information about the spatial position of the 12-section beam of the reflected wave is obtained by using three-component recording of oscillations near P8 C when oscillations are excited in the borehole 2 at the 10. when immersing a three-component seismic receivers in specially drilled small wells under the sharp seismic lines contained in the upper suit of the section (as a rule, immersing seismic receivers to a depth of 20–40 m, deeper than the bottom of the ZMS), the three-component registration allows using the known methods of polarization analysis to determine the spatial (Position of the beam segment 12 directly by three components of the full vector; reflected wave torus. Combination of three The 1-component recording and observation of a; orthogonal profiles x 5 allows us to significantly increase the reliability of the results, for example. In a well at a depth of 2-2 m, oscillations are excited from two PVs. The origin of coordinates is chosen exactly E is found on schiys (12m Podust skvazhiny.Odin; The PF is on the X axis, its distance from the wellhead is 900 m. Another fJB is located on the Y axis and is 600 meters from the wellhead at a point located in the well at a depth of 250 m, the source of oscillations. The oscillations are recorded on pairs of orthogonal profiles of intersection in the first and second PVs. The source’s immersion depth is 12 m. The first arrangement of seismic receivers in the well contains six instruments with a pitch of 20 m. On each of the second orthogonal profiles of the second arrangement, there are 2 submersible depth gauges 12 m seismic sensors in increments. 10 m. Length of the recorded wave. In geological section, there are four boundaries, including the earth surface. The data on the boundaries and reservoir rates are given in Table 1. TABLETS 1 The arrival time of the wave reflected from the boundary IV is 0.930 and 0.8 h6. c for each of the two ROs respectively. Calculate the coordinates of the reflection point by the proposed method (exact solution) and on the basis of two-dimensional calculations for the {house of the PV). The calculation results are summarized in table. 2. Table2

The proposed method obtained more accurate results than the known, used in the two-dimensional version, and the discrepancies go beyond

framework of errors occurring during seismic exploration aimed at solving structural problems. This example demonstrates the feasibility of using the method for high-precision seismic exploration in areas with complex I post-war environments, J-. The proposed method can also be used for studying the spatial position of the refractive boundaries located both between the source and the receiver of the oscillations and on one side of them (in the latter case, head waves occurring on the refracting boundary are recorded). the spatial position of the sections of the beam along which the oscillations propagate, both to the receiving points located in the well, and to the receiving points located in the near-surface part of the geological ripeness "

Claims (1)

METHOD OF VERTICAL SEISMIC PROFILING, including excitation of oscillations by a source located in the excitation point in the surface part of the geological section, three-component reception of oscillations at the reception points at two geophysical locations, the first of which is located in the borehole, the transpositional correlation of reflected waves on seismic records obtained and at the second arrangement of seismic receivers, the determination of the segment by the three-component seismic records of the spatial position s rays along which the waves propagate at the approach to their receiving point in the well, with about tlichayuschy I that, to improve the reliability and accuracy of the determined spatial position ¹ fission seismic boundaries located under harsh refracting and reflecting, yuschimi boundaries second the arrangement of geophones is located in the surface part of the geological section, on orthogonally located profiles intersecting at the point of excitation, the length of each of the orthogonal profiles being chosen commensurate the wavelength of the recorded wave, and the reception of oscillations at the second arrangement of seismic receivers is carried out from additional excitation points that coincide with the reception points located in the well above the studied boundary under sharp reflecting and refracting boundaries, after receiving the oscillations of the first well, the arrangement of seismic receivers from a near-surface point excitations using transpositional correlation identify the reflected waves obtained at the first and second geophysical arrangements, determined by the spatial field of the seismic rays, according to which the vibrations approach the intersection point of the profiles of the second arrangement, is determined by the wave field observed at the second arrangement of seismic receivers, according to the law of refraction, the spatial position of the ray sections located above the studied boundary and the position of the closest points of these sites in the vicinity of the investigated border judge the position of the reflection points. SU, "1056111>