RU2148838C1 - Seismic data processing technique - Google Patents

Abstract

FIELD: seismic prospecting, study of geological structure of media formed complexly. SUBSTANCE: reflected waves are enhanced by obtained data, time of their recording, angle of approach, amplitude and effective velocity of propagation are determined. Authenticity of enhanced waves is evaluated. Law of change of effective velocities, intervals with equal values of gradients of change of effective velocities, values of time (T_zw) of waves reflected once in crossing points of intervals with different gradients of effective velocities are determined. Changes of effective velocities in selected intervals are correlated, values of time (T_zw) of waves reflected once matching graphs of effective velocities on correlation diagram are correlated with values of time (T_zw) of waves reflected across section. Fields of effective velocities are defined. Obtained data are interpreted as one complex and geologic-geophysical model of medium matched with section is plotted. Kinematic characteristics of wave field of gradient medium are converted into characteristics of medium with average velocity. Averaged values of field of effective velocities of reflected waves on which isometric lines of equal values present form of reflecting horizons in time scale ( (T_zw/2, V_ef) ) are obtained for each reflecting horizon with due account of corrections. These fields are converted into structural map of depths along vertical line and distortions related to inclination of plane of rays under conditions of nonrigorous orientation of profiles across and along strike are excluded. EFFECT: increased efficiency and authenticity of proposed technique.

Description

 The invention relates to seismic exploration of minerals and is intended to study the geological structure of complex environments, for example, salt dome areas.

 A known method of seismic exploration, widely used to study environments with a diverse geological structure. The method is based on determining the propagation times of reflected waves excited by artificial sources and recorded by multichannel arrangements on extended profile intervals. The successive movement of the excitation and registration systems provides for tracking physical boundaries in the medium and obtaining the necessary amount of information for geological and geophysical interpretation (1).

 There is also a known method for processing seismic data, called "layer replacement". This method is intended to correct the shape of the hodographs of the OGT of reflected waves arising in the presence of inhomogeneities in the upper part of the medium by comparing the wave travel times along the rays traced in the real medium model and in the substitution model, taking into account the introduction of kinematic corrections into the initial data on the profiles (2 )

 The disadvantage of these methods is the lack of reliability of the results when conducting research in complex geological conditions.

 The closest technical solution to the claimed one is a method of processing seismic data of multiple overlays. The method is based on the joint processing of seismic records of several adjacent hodographs of the OGT, determining the gradient of the change in the recording time within the processed profile interval, the accumulation of total signals with one gradient value taking into account time corrections and determining the propagation velocity of oscillations in the studied medium (3).

 The disadvantage of this method is the lack of effectiveness, as well as the lack of criteria for assessing the reliability of the obtained research results.

 The objective of the invention is to increase the efficiency of the method and its reliability.

 The problem is solved as follows.

In a method for processing seismic data, including registration of seismic waves with multi-channel spacing according to profiles, extraction of reflected waves, selection of processed profile intervals, joint processing with CDP data, input of correction corrections to the initial data on profiles, the reflected waves are first extracted and the time of their registration is determined, and also the approach angle, amplitude and effective propagation velocity, evaluate the reliability of the selected waves, determine the pattern of change in effective velocities by means of oksimatsii their values and the time registration, as well as slots with equal values of the gradients of variation of the effective rate with time values the time of single reflection (T _op) at the points of intersection of intervals with different gradients effective rate correlated graphs of effective speeds along the profile to selected intervals with sustained or regularly changing gradients, they determine the values of interval velocities, determine the nature of the recorded waves and the position of the short-form grads then, within the selected intervals, the values of the times of once reflected waves (T _о ), which coincide with the graphs of effective velocities in the correlation scheme, are correlated with the values of the times of reflected waves (T _op ) in the OGT section, by approximating discrete values distributed in a given window along the profile, time sections of the common point of excitation and the common deep point are obtained, the effective velocity fields along the profile are determined and the pattern of their change depending on the geological structure, clearly interpret the obtained data and construct a geological and geophysical model (GGM) of the medium that is consistent with the standard section of the OGT, convert the kinematic characteristics of the observed wave field of the gradient medium into medium characteristics at an average speed, for this, correcting time corrections are determined as the difference between the kinematic characteristics determined by the geological the geophysical model and the calculated average velocity characteristics, determine the fields of corrective corrections as a function of time and impact dividing the path from a common point of excitation and a common deep point and lead the kinematics of the wave field to a medium velocity medium, using the system of seismic profiles, for each reflecting horizon, average values of the recording field (T _о / 2) and the field of effective velocities of reflected waves at which by isolines V _eff of equal values, the form is displayed reflecting horizon in the time scale (T _o / 2, V _eff) is converted into the field block depth map vertically and eliminate distortion due to tilt in the ray plane usl ditions are not strict orientation profiles transverse to and along the strike rocks.

Distinctive features in the claimed method are:
reflected waves are determined and the time of their registration, as well as the approach angle to the boundary, the amplitude and effective propagation speed are determined, the reliability of the selected parameters is estimated, the regularity of the change in effective velocities is determined by approximating their values and registration times, then the intervals with equal values of the gradients of the effective speed change are determined in time and values of times, once reflected waves (T _op ), at the points of intersection of intervals with different gradients of the effective speed. This makes it possible to obtain information on the patterns of changes in velocities in time and lateral, the nature of the recorded waves and the paths of their propagation, to identify and correlate in the section the same type of intervals with the same physical characteristics, determined by the equality of the gradients of the change in speed and, having obtained a thick-layer geological and geophysical model of the medium, define criteria for assessing the reliability of recorded parameters;
graphs of changes in effective velocities along the profile are correlated, in selected intervals, with sustained or regularly varying gradients, the values of interval velocities and the positions of multiple-forming boundaries are determined, then, within the selected intervals, the values of the times of once-reflected waves (T _о ), which coincide with the graphs of effective velocities at correlation scheme and with the values of the times of the reflected waves (T _og ) in the section of the OGT. The correlation schemes obtained in this way along the profiles reflect the structure of the same type of packs of deposits with sustained or regularly changing physical and geological characteristics on a time scale, and the shapes of isolines connecting points with equal velocity values characterize the pattern of change in the effective velocity along the lateral;
approximation of discrete values distributed in a given window along the profile is carried out to construct time sections of a common point of excitation and a common deep point, determine the fields of effective velocities along the profile and identify patterns of their change depending on the geological structure;
comprehensively interpret the obtained data and build a geological and geophysical model (GGM) of the environment that is consistent with the section of the OGT. As a result of such phased processing, an updated thin-layered geological and geophysical model (GGM) of the gradient medium and the necessary data for converting the kinematics of the seismic wave field of the reflected waves propagating in the gradient medium to the medium at an effective speed are obtained to eliminate distortions introduced by a complex geological environment;
transform the kinematic characteristics of the observed wave field of the gradient medium into medium characteristics at an average speed, for this, the fields of correcting corrections are determined as a function of time and distance of the path from the common point of excitation and the common deep point, and kinematic corrections are introduced into the observed seismic records. As a result, one obtains a set of seismic records with medium-velocity kinematics of the wave field, along which a time section is obtained, in which the slopes of the axes of the in-phase of the singly reflected waves in the time scale correspond to the slopes of the reflecting horizons identified with them;
using the system of seismic profiles for each reflected horizon, the averaged values of the field of recording times (T _о / 2) and the values of the field of effective velocities of reflected waves are obtained, on which isolines of equal values reflect the shape of the reflecting horizon in the time scale (T _о / 2, V _eff ), they transform this temporary field into a vertical structural map of depths and exclude distortions associated with the inclination of the ray plane under conditions of not strict orientation of the profiles into the cross and along the strike of the rocks.

 The sources of scientific and patent-technical information known by the authors do not describe a method for processing seismic information with the listed set of features aimed at solving the problem, this made it possible to conclude that the claimed technical solution has the invention criterion of "inventive step".

 The method is implemented as follows.

The sequence of operations is carried out in several stages:
1. At the first stage, they solve the problem of sequentially extracting all types of recorded reflected waves using controlled interference systems with high resolution separation of waves in interference zones, as well as determining the following parameters of the extracted waves: T _о - recording time, A - amplitude of the resulting signal, dT _a - angle of approach with respect to the observation surface waves, expressed in the time scale gradient values change dT _of the reflected wave profile along the centerline of the beam, the curvature of Fr. coagulant reflected wave estimated by the value of the effective speed (V _eff) to which the reflected wave distributed from the registered specific physical boundary. To determine the type of registered waves and evaluate the reliability and reliability criteria, additional physical parameters of the selected waves are determined: dV _eff is the accuracy of determining the effective speed, N is the number of registered common-mode signals that form an effective signal during processing, the registration time of which does not deviate from the value (T _о ) the resulting signal by a value of more than 1/3 of the oscillation period, the ratio of the number of common-mode signals N to the number of traces used in a given time interval % (%), the degree of suppression of signals of other types of waves S during the selection of the desired wave (noise / signal ratio).

The data obtained allow us to comprehensively analyze the wave field and determine which of the selected waves correspond to one reflecting boundary, using the values of T _о , dT _о , V _eff , A. as criteria for identifying the signals.

2. At the second stage, using statistical processing methods, graphs of changes in effective velocities are correlated and a correlation diagram is obtained along the profile. The correlation criterion is consistency: the gradient of the change in the effective speed dV _eff = F (T _о ), the time power of the interval and the values of the effective velocity V _eff along the profile, or the pattern of change of these criteria. The times (T _op ) of the once reflected waves are determined at the intersection points of the intervals of the effective velocity graphs with different values of dV _eff by approximating these values and the change graphs (T _op ) are obtained along the profile. Intervals with sustained gradients of change in velocity (V _eff ) correspond to the same type of thickness of sediments with mature or regularly changing lithological and physical characteristics. Each stratum may include several layers with reflective boundaries. The sustainability or regularity of the gradient change dV _{ef the} change in speed is a sign of the consistency of the geological conditions of their formation. The correlation scheme is a thick-layer geological and geophysical model (GGM) of the medium along the profile.

 3. At the third stage, the nature of the recorded waves and the position of the short-forming boundaries along the profile or at individual profile intervals are studied. This allows us to exclude repeatedly reflected waves from the subsequent analysis.

4. At the fourth stage, within each interval, with the sustained and regularly changing values of the gradients dV _{eff of} effective velocities, the values of the times of registration of singly reflected waves (T _oc ), which coincide with the graphs of effective velocities in the correlation scheme, are correlated. Correlation is performed only within intervals with sustained or regularly varying gradients dV _ef , limited by graphs of changes in values (T _oc ) along the profile. At the same time, in these intervals, the axes of the in-phase of the reflected waves are correlated over the time section of the CDP.

5. At the fifth stage, along each correlated horizon, discrete values of the times of registration of once-reflected waves (T _og ) obtained from the travel time curves of a common point of excitation and OGT are approximated and graphs of the times of registration of reflected waves along each reflecting horizon and time sections of a common point of excitation and total deepest point. According to the graphs (V _eff ) of the effective velocities of the common point of excitation used in the correlation scheme, a field of effective velocities is obtained along the profile, which characterizes the pattern of velocity changes in depth and lateral depending on the geological structure of the medium.

6. At the sixth stage, the interval velocities between the reflecting horizons (T _og ) of time sections of the common excitation point and the common reflection point are determined and graphs of the variation of the interval velocities along the profile are obtained. In this case, the interval velocity calculated for the interval with a sustained velocity gradient should correspond to the average value of the interval velocities determined between the reflecting horizons, which is a criterion for the reliability of the result.

 7. At the seventh stage, the obtained data are comprehensively interpreted and the materials of a common excitation point (OPV) and a common reflection point (OGT), a refined geological-geophysical model (GGM) of the medium, are constructed with materials.

 8. At the eighth stage, in the presence of refracting boundaries in the geological section, on the surface of which significant changes in velocity occur, the kinematic characteristics of the observed wave field of the gradient medium are transformed into medium characteristics with an average speed. The basis for such transformations is the geological and geophysical model of the medium and data on the patterns of change in the times of registration of reflected waves along reflecting horizons and interval velocities, on the basis of which corrective corrections are determined as the difference between the kinematic characteristics determined by the geological and geophysical model and calculated with medium-speed characteristics . Using these data, the fields of corrective corrections are determined as a function of time and distance of the path from a common point of excitation and a common deep point. Corrective corrections are introduced into the observed seismic records and the kinematics of the wave field of the gradient medium is reduced to a medium velocity medium. Monitoring the reliability of the results consists in the fact that when re-studying effective velocities using seismograms with corrective corrections introduced, velocity graphs corresponding to a given medium-velocity characteristic of the medium should be obtained.

9. At the ninth stage, according to the system of seismic profiles of areal survey, for each reflecting horizon, average values of the time field (T _о / 2) of the reflected waves are obtained, on which isolines of equal values reflect the shape of the reflecting boundary in time scale and the time field of seismic velocities, on which the isolines equal values of effective velocities characterize the pattern of their change along the reflecting horizon, transform this field into a structural map of depths vertically and exclude distortions associated with the inclination of the ray plane under conditions of not strict orientation of the profiles across and along the strike of the rocks.

 When developing the individual stages of the described method, work was carried out on their testing in various geological conditions of the Caspian basin. New geological results were obtained, the reliability of which is confirmed by drilling.

Literature
1. Gurvich I. I. Seismic exploration. Directory. - M .: Geological Publishing House, 1960 (analogue).

 2. Exploration geophysics. - M.: Nedra, 1986, no. 102, p. 23-25 (analog).

 3. USSR author's certificate N 327426 "Method for processing multiple seismic seismic data" ed. I.I. Kharaz et al. 12/26/72. - BI N 5 (prototype).

Claims (1)

A method of processing seismic data, including registration of seismic waves with multi-channel spacing according to profiles, extraction of reflected waves, selection of processed profile intervals, joint processing with CDP data, input of corrections to the initial data on profiles, characterized in that the reflected waves are distinguished and the time of their registration is determined , approach angle, amplitude and effective propagation velocity, evaluate the reliability of the selected waves, determine the pattern of change in effective velocities by pproksimatsii their values and the time registration, as well as slots with equal values of the gradients of variation of the effective rate with time, time values singly reflected waves (T _op), at the points of intersection of intervals with different gradients effective rate correlated effective velocity change graphics along the profile to selected intervals , with sustained or regularly varying gradients, determine the values of interval velocities, determine the nature of the recorded waves and the position of the short wave ranits, then within selected intervals correlated values times singly reflected waves (T _o) coincides with the graph of effective velocities for the correlation circuit to values times reflected waves (T _lim) for sectional GBS by approximation of discrete values distributed in a predetermined window along the profile , get time sections of a common point of excitation and a common deep point, determine the field of effective velocities along the profile and reveal the pattern of their change depending on the geological structure, set They clearly interpret the obtained data and construct a geological and geophysical model (GGM) of the medium that is consistent with the standard section of the OGT, convert the kinematic characteristics of the observed wave field of the gradient medium into medium characteristics at an average speed, for this, correcting time corrections are determined as the difference between the kinematic characteristics determined by geological -geophysical model and calculated average speed characteristics, determine the fields of corrective corrections as a function of time and beats Aligning the path from a common point of excitation and a common deep point, according to a system of seismic profiles, for each reflecting horizon, obtain the averaged values of the field of recording times (T _о / 2) and the values of the field of effective velocities of reflected waves, on which the shape of reflecting horizons is represented by isolines of equal values on the time scale (T _o / 2, V _eff) is converted into the field block depth map and the vertical distortion rule associated with the tilt plane of beams in a non-strict orientation and transverse to the profiles by direct erasure rocks.