RU98107567A - METHOD OF REGISTRATION AND PROCESSING OF REFLECTED SEISMIC SIGNALS, AND DEVICE FOR CARRYING OUT EXPLORATION WORKS IN MEDIA WITH COMPLEX TECTONICS - Google Patents

Claims (22)

1. A method of processing reflected seismic signals to study a medium with complex tectonics by using at least one source of elastic waves and wave receivers reflected by at least one reflecting element of the medium, while the reflected waves are recorded in the form of seismic traces, characterized in that: a) a sufficiently large number of seismic traces are generated along a predetermined first direction to obtain in this first direction a first dense distribution of midpoints (ST) of source pairs -receiver that produce the aforementioned seismic traces, and for each of the midpoints (CT) distributed along the first direction, form an assembly of seismic traces of common midpoints (OCT), grouping all seismic traces produced by source-receiver pairs, which are essentially lined up along the first direction, with the midpoint of each pair coinciding with the common midpoints (OST) of the installation of seismic traces; b) form a second dense distribution of midpoints (CT) along a second direction perpendicular to the aforementioned first direction, and seismic traces of common midpoints (OCT) are formed for each of the midpoints (CT) distributed along the second direction, grouping all the tracks produced source-receiver pairs, which are essentially lined up along the second direction, with the midpoint of each pair coinciding with the common midpoints (OCT) of the seismic trail mounting to get a series of lines of common of their midpoints (OCT) parallel to the first and second directions that form the analytical grid and its crosshairs — analytical nodes, the number of seismic traces in each installation of seismic traces of common midpoints (OCT) is sufficient to analyze the travel time curves of seismic waves.  2. The method according to claim 1, characterized in that they generate a third dense distribution of midpoints (CT) along the third direction and for each of the midpoints (CT) distributed along the third direction, form an assembly of seismic traces of common midpoints (OCT), grouping all seismic traces produced by source-receiver pairs, which are essentially lined up along the third direction, with the midpoint of each pair coinciding with the common installation midpoints (OST) of the seismic traces, and the number of seismic traces in each mounting the seismic traces common midpoint (CMP) is sufficient for analyzing the time curves of seismic waves.  3. The method according to p. 1, characterized in that they generate a fourth dense distribution of midpoints (CT) along the fourth direction and for each of the midpoints (CT) distributed along the fourth direction, form an assembly of seismic traces of common midpoints (OCT), grouping all seismic traces produced by source-receiver pairs, which are essentially lined up along the fourth direction, with the midpoint of each pair coinciding with the common midpoint (EST) of the installation of seismic traces, and the number of seismic traces in each installation of seismic traces, the main midpoints are enough to analyze the travel time curves of seismic waves. 4. The method according to claim 2 or 3, characterized in that each of the third and fourth directions (7, 12) is at an angle of about 45 ^o to each of the first and second directions (1, 2).  5. The method according to any one of claims 1 to 4, characterized in that the analytical grid (5, 6, 10) forms the basis for the devices for recording reflected seismic signals.  6. The method according to any one of claims 1 to 5, characterized in that the 3D coverage of the dense surface distribution is performed simultaneously with the construction of the analytical grid (5, 6, 10), and the midpoints (ST) distributed along each of the mentioned directions, separated from midpoints (CT) obtained for 3D coverage.  7. The method according to any one of claims 1 to 5, characterized in that the analytical grid (5, 6, 10) is used with pre-implemented 3D coverage. 8. The method according to any one of claims 1 to 7, characterized in that for each OCT corresponding to the analytical node, the curvature of the travel time curve of the seismic waves is determined in each direction, and the values obtained in this way are used to determine the components of the velocity field at a time t ₀ associated with the above common midpoints (OCT), and for a given reflective element of the medium t ₀ is the time of the vertical path with reflection in the absence of bias between the source and the receiver. 9. The method according to claim 8, characterized in that such parameters as θ, τ, t _p ^min , t _p ^max characterizing the geometry of the reflecting element are determined from the components of the velocity field associated with the above reflecting element, θ is the angle between the first and some basic directions, t _p ^min and t _p ^max respectively denote a lower and higher incidence value of the reflecting element, and τ denotes the travel time.  10. The method according to any one of claims 1 to 7, characterized in that the cells of the analytical grid are correct.  11. The method according to claim 10, characterized in that the cells of the analytical grid are square.  12. The method according to p. 10, characterized in that the cells of the analytical grid have the shape of a parallelogram.  13. A device for implementing the method according to claims 1 to 12, characterized in that it contains at least two rows of receivers (55, 57) located on the analytical grid (51) and at least one emitting source ( 57), while the receivers activate according to the type of coverage obtained, the above source (57) is located on or near one of the aforementioned rows of receivers (55 or 55 ') with each shot.  14. The device according to item 13, wherein the source (57) with each shot is located either above the receiver (55, 55 '), or very close to it.  15. The device according to item 13, wherein the source (57) with each shot is located at a midpoint between two respective receivers (55 or 55 ').  16. The device according to any one of paragraphs.13 to 15, characterized in that the two rows of receivers are perpendicular to each other.  17. The device according to any one of paragraphs.13 to 16, characterized in that each receiver line includes a sequence of elementary receiver lines (54), each elementary receiver line is located on one side of the cell of the analytical grid and includes a given number of receivers (55 , 55``), while the line (I) of each elementary line of the receivers is less than the side length of the above cell.  18. The device according to 17, characterized in that the ends of each elementary line of receivers are remote from the ends of the side of the cell on which these lines of receivers are located.  19. The device according to PP.15 and 18, characterized in that the shots are performed between the respective receivers of the elementary line and at the intersections of the directions of the elementary lines of the receivers.  20. The device according to PP.14 and 18, characterized in that the shots are performed in the positions of the receivers of each elementary line of receivers.  21. The device according to PP.19 and 20, characterized in that the shots are fired sequentially at the positions of the receivers of each elementary line of receivers, at the midpoint between two consecutive receivers of each elementary line of receivers and at the intersections of the directions of the elementary lines of the receivers.  22. The device according to claims 13-19, characterized in that the set of elementary lines of the receivers constitutes a group of lines (52) that moves over the analytical grid (51).