SU811163A1 - Seismic survey method - Google Patents

Description

The invention relates to seismic exploration for oil and gas and can be used to study the structure of three-dimensional geological environments in areas with difficult ground conditions. The known method of seismic exploration, in which geometrically ordered observing systems are used, and the sources and receivers are located on parallel and orthogonal lines with a fixed repetition of their mutual arrangement, such as, for example, a wide profile system. The rigid fixing of the geometry of sources and receivers, in connection with which it cannot be used or its application is associated with large difficulties and costs in areas with difficult ground conditions (not the liveliness of passages, the complex relief of gardens, crops, etc.). A seismic survey method is also known, which provides for such a relationship between the seismic receivers and the source so that, upon registration, a two-dimensional grid of reflection points is formed. The processing of the information obtained is carried out by summing it in various systems and directions according to the method of a common depth point Tzj. The disadvantage of this method is that its use is impossible or difficult to cope with in difficult conditions, besides It limits the freedom to choose the directions for obtaining time sections in the study area. The position of the lines of the belt cuts is controlled by the nodes of a rigid two-dimensional grid of points from, and hygienic, on the plan and distances between sources and receivers along selected lines. The purpose of the invention is to provide the possibility of a three-dimensional study of the structure of geological environments in areas with difficult ground conditions. The goal is achieved by the fact that in the seismic survey method, including field observations and data processing, the excitation and recording of oscillations are performed on the ground at access points without any restrictions on orientation, distance, and geometry, and for each fixed source position at one or several receivers, and for each fixed receiver, observations are made at one or several sources; areas are selected; s forming composition seismic traces relating the position of point symmetry of the source-receiver to selected hydrochloric areal basis, each of the compositions was subjected to three-dimensional adjustable directional summation, wherein moveout calculated taking into account the varying azimuth lines of source-receiver. The essence of the method is illustrated in the drawing, which shows field profiles of an arbitrary shape, the position of which is chosen according to local conditions. Flags indicate the position of sources 2 and triangles — the position of receivers 3. Line 4, connecting sources and receivers, shows cases where a single arrangement of geophones is being processed from several sources located on different profiles and at certain points outside the profiles. Line 5 shows one of the possible directions for building a time section, along which rectangles b indicate the elementary processing bases, within which seismic traces compositions are formed for adjustable directional summation. The seismic trace is related to this element base if the corresponding source-of-symmetry point is located inside the rectangle. To obtain the spectra from the angle and the second one, the base can be used in the form of a circle, square, etc. The large circle 7 is limited by the area within which the sources and receivers are located, which provide the receiving routes related to the processing base with a small circle 8. The method is implemented as follows. Perform field observations according to the chosen scheme, select the elemental areal bases of processing in predetermined directions, compose the seismic traces belonging to these bases / perform an adjustable directional summation of the obtained compositions, and the kinematic corrections are introduced in accordance with the formula f, ((2V PjCOSfot-K-) il p. 005 (06-4)) {i-2cos (-V) -V & t, the coordinates of the source-receiver symmetry point in the local polar coordinate system, the beginning of which is aligned with centro.h base- (rectangle, circle, etc.); psellar radius; the angle between the polar radius and the axis of coordinates aligned with the line A-A of the time section; source-receiver distance; the angle between the source and the axis of the local coordinate system; running time on a normal beam in the center of the base; increment to in the direction of the fall of the reflecting horizon on a segment of fixed length, for example, equal to the diameter of the circle T) describing the rectangle. The value of T) determines the size of the bases, it is chosen equal to the maximum distance at which the locus to under the local conditions can be approximated by a straight line; the angle between the axis of the local coordinate system (the profile line of the time section) and the direction of the subject, in the course of directional summation (enumeration) of the total gradient tgj, is the kinematic parameter of the search. Introduced to set the surface hodograph of the reflected waves within the base. where cnc; - the travel time of the reflected wave for installation with a midpoint at the center of the base, oriented at an angle to the direction of the test full gradient; the maximum source-receiver distance for the selected observation scheme. For each seismic trace, the values of 6 i g and oi are in the th coordinate system, the origin is aligned with the center of the base, and the nat axis is aligned with the profile line. positions of seismic traces (adjustable direction by scanning t /, Ato / Ebora). For implementation, the ranges of possible l / o, T, Ato, VJ, and the steps of their tization (scanning) are redefined. By specifying the value of 1Г, dyo and h, for example, -fco, H, the kinematic guide is entered by the formula and, by summing up the seismic traces, a semi-oracle section, to which the index / 4 is kept unchanged and the reserves obtained with indices tj K / s, etc. The resulting group / time reserves are assigned the parameter & to. Then j, not changing the value of SH, but only changing ito (L ± 02 f, etc.), produces a set of time sections, which is assigned the constant 4V. Changing the value of H and performing for each value of one-, walkie-talkie, discussed above, get the Editing of temporary cuts, consisting of sets of temporary cuts with fixed values of H% 2, etc .; On the obtained time sections, the reflections are selected, correlate them along the profile and determine for them the fco and approximate values of t, and 4J. Summing up the partial time sections or parts of them with the best reflections, obtain a baseline time section. Depending on the specific situation, the baseline timeline is obtained in another way, for which generalized laws for entering kinematic corrections are determined from partial timelines and, summing up the seismic tracks of the tracks, the tracks of the time section are obtained directly. In this case, for the same time, more than one kinematic correction can be made (by the number of waves, taking into account t, At, H). In order to rationally use computer time for a single composition of seismic traces, the entire volume of searches for t, ut and P is performed. , as a result, reduce the number of calls to external memory. The resulting time section traces are memorized and / or visualized in the order of scanning. As a result, for this picket, the time section lines get the sum of which the waves will be resolved according to four parameters o and M. By sampling the total amplitudes of b o const, three o two and one dimensional spectra are obtained. Three-dimensional spectra are obtained for enumeration combinations of t, ut-o and H. Two-dimensional spectrum velocity and on C (j-const is obtained at 4 cons fC and & to - variables). The two-dimensional range of angles and azimuths of falls on to const, is obtained with frconst (Ato and are variables). One-dimensional spectra at to const are obtained by sampling total amplitudes at two fixed parameters and one time variable, for example, one-dimensional speed spectrum — at fixed values ut, H and t variable. Velocity spectra are also obtained from correlated over time cuts, by directly summing the track composions on tysconsfc with H.-constv, the value of which is determined with the accuracy of the scanning step using this parameter at the stage of obtaining partial time cuts and / or by sum tapes. On a two-dimensional spectrum, the t and to to values are determined by the position of the center of the amplitude anomaly, and then the velocity and angle of incidence of the reflecting horizon are calculated, for which a system of two equations is solved: lJ (l- | e.nV;. determining, according to the speed spectrum, the values of Al / o, 1, receive a one-dimensional azimuth spectrum at tff consttC const, ikt const, where the exact value of H is determined from the position of the maximum amplitude. For the study area, cuts are made for other Ø: 1 lines. cuts for procorrelated prschtsadi taking into account the obtained data on the LL and V, isochron maps are constructed, which are then based on the calculated values of the scalar velocities, & t and H / recalculated into the depth maps. To optimize the processing, use the combined procedures for obtaining time sections , two and one-dimensional spectra, vary by the magnitude of the scanning steps t, utj,, H. For example, before obtaining time cuts in separate points of the profile, we obtain summations, spectral velocities, angles and azimuths of falls in order to estimate and narrow the digits strumming azone by parameters 1; V, Initial processing, with the same purpose, is carried out using large scanning steps, and reduced scanning steps, Ato, are used to obtain spectra in order to determine the exact values of V, V V, etc. The use of this method provides a reliable solution to the geological problem, which is due to an arbitrary (free) observation system and the proposed processing technique, which allows to obtain time sections through a network of profiles of any configuration and density. By the pro-correlated reflection m put & m adjustable directional skipping it is possible to obtain three and / or two and / or one-dimensional spectra of speeds, angles and azimuths of the reflections of the reflecting horizons to determine the kinematic parameters of the waves. The method allows to increase the resolution and noise immunity.

Claims (1)

Claim A method of seismic exploration, including field observations and data processing, characterized in that, in order to enable three-dimensional study of the structure of geological media in areas with difficult terrestrial conditions, the excitation and registration of vibrations is carried out on the ground in accessible places without restrictions on orientation, distance and geometry, moreover, for each fixed position of the source, observations are made on one or more receiver arrangements, and for each fixed arrangement of receivers make observations at one or several sources, select areal processing bases, compose a composition of seismic traces for each base that are related by the position of the point of symmetry of the source to the selected areal base, each composition is subjected to three-dimensional controlled directional “summation, and kinematic corrections are calculated taking into account the changing azimuth lines of source-receiver lines.