RU2411547C1 - Method of defining static correstions - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: there are performed seismic measurements, then the received data are interpreted and processed. Additionally there performed is electric exploration at combined profiles for examination of near-surface section (NSS) structure in low speed zone. During this process there registered are electromagnetic field changes and electromagnetic wave hodograph curve. There defined is longitudinal electric resistivity. According to the obtained data there defined are united stratigraphically connected geoelectric complexes. NSS geoelectric model is made. Then with the use of well survey data and microseismic velocity survey data there defined is interrelation between the times of electromagnetic and seismic field recording. In each point of electric exploration electromagnetic hodographs are calculated into pseudoseismic. According to the received hodographs there calculated are the values of prognostic interval velocities within each geoelectric complex. For the selected section interval there made are the schemes of prognostic values distribution of interval velocities and its thickness, there calculated are static corrections.

EFFECT: improvement of authenticity and informativity of static corrections defining ensured by recording of local inhomogeneities of low velocity zone structure.

Description

The invention relates to geophysical exploration by a complex method, including seismic exploration and shallow modification of electrical exploration by field formation sounding (MSSB), and can be used to take into account heterogeneities in the structure of the upper part of the section (VChR) during prospecting for subsequent accounting during processing of seismic data.

A known method of downhole seismic exploration, in which determine the speed characteristics of the upper part of the section - the zone of low speeds (ZMS). Essence: in the process of drilling, elastic vibrations are excited by the influence of the rock cutting tool of the mobile drilling rig on the medium under study. At the same time, elastic vibrations are recorded by a reference signal sensor consisting of four transducers uniformly distributed along the perimeter of the platform frame of the drilling rig and a ground receiving device. The ground receiving device is installed on the day surface at a distance from the wellhead of at least 5-10 m on the rods buried in the ground to a depth exceeding the thickness of the soil layer. A range of operating frequencies from 100 Hz to 350 Hz is selected, within which useful signals are extracted. Intercorrelation functions are formed and seismic velocities and the position of seismic boundaries are determined from them. EFFECT: increased accuracy and reliability of constructing the speed characteristics of the test medium (see RF patent for the invention No. 2292063, IPC G01V 1/40).

To carry out this method, it is necessary to have a deep hole.

Known methods for determining static corrections by registering a wave refracted on the sole of a low-speed zone (see UK patent No. 32090405, IPC G01V 1/28 and Sharif R., Gelgart L., Seismic exploration, t.1, M .: Mir, 1987) .

However, this method gives an average value of the physical characteristics of the upper part of the section (VChR) to the bottom of the low-velocity zone and does not take into account the presence of local inhomogeneities in it.

Closest to the proposed solution is a method for determining static corrections, including the excitation of elastic waves from two sources at a given distance from each other, the reception of elastic waves by a seismic receiver located away from the sources on the same line with it, measuring the travel times of the refracted wave to the receiver from both sources, measurements of altitude of points of reception and line of conduct (see USSR author's certificate No. 1536248, IPC G01V 1/26).

The disadvantage of this method is the a priori assumption of a horizontally layered, homogeneous structure of the ZMS.

The objective of the proposed solution is to develop a method that allows you to take into account the heterogeneity of the zone of low speeds (the upper part of the section) with a capacity of several tens of meters when determining static corrections. The proposed solution is aimed at increasing the reliability of structural structures during geological exploration.

The technical result of the proposed solution is to increase the reliability, informativeness and reliability of the method for determining static corrections by taking into account local heterogeneities of the structure of the ZMS.

The problem is solved in that in the method for determining statistical corrections, including seismic exploration, interpretation and processing of the obtained data, according to the solution, additionally, electrical reconnaissance is carried out on combined profiles to study the structure of the upper part of the section in the low-velocity zone, changes in the electromagnetic field and hodographs of the electromagnetic wave are recorded, they determine the longitudinal electrical resistance, according to the obtained data, single geo-electric stratigraphically linked to multiplexes, build a geoelectric model of the upper part of the section, then using the data of geophysical studies of wells or microseismic logs establish the relationship between the times of registration of electromagnetic and seismic fields, at each point of electrical exploration observations, electromagnetic hodographs are converted into pseudoseismic ones, according to them, within each geoelectric complex, predictive values are calculated interval velocities, for the selected cut interval, distribution patterns are built values of the predicted values of interval velocities and its thickness, the values of static corrections are calculated.

Static corrections are determined by the hodograph of an electromagnetic wave, which is not known from the prior art. By the hodograph of an electromagnetic wave is understood the dependence of the recording time on the penetration depth of the electromagnetic field (see Electrical Exploration: Handbook of Geophysics. - M .: Nedra, 1979). Known analogues do not use the characteristic of the electromagnetic field — the hodograph — to study the upper part of the section. An informative parameter for studying the upper part of the section in known solutions, including in decision SU No. 1448319, is the amplitude of the electromagnetic wave and its transformation into parameters such as longitudinal resistance, total longitudinal conductivity, etc. The amplitude of the electromagnetic wave and its transformation cannot be used to determine static corrections.

Static corrections in the proposed method are determined on the basis of a pseudo-seismic hodograph obtained on the basis of the relationship of the electromagnetic and seismic (MSC and VSP) hodographs. No solutions are known in which the interconnection of the electromagnetic and seismic hodographs for determining static corrections is established.

Electrical exploration is carried out in a shallow modification of the MZSB, the data are comprehensively interpreted. To do this, first, the electrical prospecting boundaries are correlated in the upper part of the section, the single stratigraphic geoelectric complexes are distinguished from the values of the longitudinal electrical resistance, a coordinated geoelectric model of the VChR is built, then using vertical seismic profiling (VSP) or microseismic logging (MSC), the relationship between at times of registration of electromagnetic and wave fields and at each point of electromagnetic soundings I recount t hodographs of an electromagnetic wave into pseudoseismic hodographs, according to them, within each geoelectric complex, the values of the predicted interval velocities are calculated, for a certain stratigraphic interval of the section, the distribution patterns of the predicted values of the interval velocities and its thickness are calculated, and the values of static corrections are calculated. Effect: increase the information content, reliability and reliability of geophysical works.

Significant differences of the proposed method in comparison with the known technical solutions are:

- in addition to seismic exploration on combined profiles, electrical exploration is carried out in a shallow modification of the MZSB, the data are comprehensively interpreted, the electrical exploration boundaries are correlated, single stratigraphically linked geoelectric complexes are distinguished from the values of the longitudinal electrical resistance, and a consistent geoelectric model is built. This allows you to use the entire set of geophysical information when building a consistent geoelectric model of the studied section;

- using VSP at the well point or MSC, the relationship is established between the times of registration of the electromagnetic and wave fields and at each point of electromagnetic soundings the measured travel time curves of the electromagnetic wave are converted into pseudoseismic travel time curves, according to which within each geoelectric complex the values of the predicted interval velocities are calculated. This allows you to study the lateral variability of VChR in the interwell space;

- for a certain stratigraphic interval of the section, the distribution schemes of the predicted values of the interval velocities and its thickness are constructed. This makes it possible to evaluate the degree of velocity heterogeneity of the upper part of the section and take it into account when calculating static corrections during digital processing of seismic material.

The method is implemented as follows.

Within the study area, simultaneously with seismic exploration, electrical exploration is carried out in shallow modification by sounding by field formation (MSSB) along the lines of seismic profiles. The changes in the electromagnetic field and the hodographs of the electromagnetic wave are recorded, and the longitudinal electrical resistance is determined.

Processing of electrical exploration data consists in calculating the geoelectric parameters of the section: the total longitudinal conductivity of the section, the longitudinal electrical resistance, the apparent depth of penetration of the electromagnetic field, and the time of its registration. Based on the obtained values of the longitudinal electrical resistance, single stratigraphically linked geoelectric complexes and local heterogeneities are distinguished, a consistent geoelectric model of the VChR (upper part of the section) is built. Using the data of well logging (geophysical research of wells) at the well point or MSC (microseismic logging), the relationship between the time of registration of electromagnetic and elastic fields is established, at each point of electromagnetic sounding, the travel time curves of the electromagnetic wave are converted to pseudoseismic travel time curves. According to them, within each geoelectric complex, the values of the predicted interval velocities are calculated.

For a certain stratigraphic interval, the VChR, the distribution patterns of the predicted values of the interval velocities are constructed, the values of the static corrections are calculated, which are then used in the processing of seismic information using a standard set of programs.

The inventive method was tested in various geological conditions. Positive experience in exploration was obtained within Western and Eastern Siberia, the outer part of the Caspian basin.

The obtained experimental data show its high efficiency and increase the reliability of structural structures during seismic surveys in areas with a complex structure of the upper part of the section.

Claims (1)

A method for determining static corrections, including seismic exploration, interpretation and processing of the obtained data, characterized in that electrical profiles are additionally conducted on the combined profiles to study the structure of the upper part of the section in the low-velocity zone, changes in the electromagnetic field and electromagnetic wave travel curves are recorded, and longitudinal electrical resistance is determined, according to the data obtained, single stratigraphically linked geoelectric complexes are distinguished, a geoelectric model is built l of the upper part of the section, then using the data of geophysical studies of wells or microseismic logging, the relationship between the time of registration of the electromagnetic and seismic fields is established, at each point of the electrical exploration observations, the electromagnetic travel time curves are converted to pseudoseismic, using them, within each geoelectric complex, the values of the predicted interval velocities are calculated, for of the selected cut interval, the distribution patterns of the predicted interval values are built scab and its thickness is calculated values of static corrections.