RU2300126C1 - Mode of geophysical exploration for exposure of small amplitude tectonic abnormalities of oil-gas productive rocks in three-dimensional space - Google Patents

Abstract

FIELD: the invention refers to oil geology and may be used for optimization of location of exploratory and production wells at an investigated object.

SUBSTANCE: the essence in conducting seismic exploratory works 3D, drilling of wells and fulfilling electrical, radioactive, acoustic and seismic logging in them. According to the all data about drilling and seismic exploration 3D small altitude tectonic abnormalities are exposed in any point of the three-dimensional space.

EFFECT: increases reliability of detection of small amplitude tectonic abnormalities.

Description

The invention relates to petroleum geology and can be used to build three-dimensional geological models and optimize the location of exploratory and production wells at the test object using a combination of 3D seismic data, electrical, radioactive, acoustic and seismic logs, core studies and well tests.

The geological basis of the proposed technical solution is the fact that narrow disintegration zones of rocks are formed along disjunctive dislocations, in which secondary processes such as plastic (inelastic) deformations, carbonatization, ozokeritization, and flowing of plastic rocks are substantially developed. All these secondary processes significantly change the physical properties of rocks, depending on which, these disintegration zones can be both lateral fluid supports and channels of vertical fluid migration.

Known methods for detecting tectonic irregularities according to ground seismic, drilling and geophysical surveys of wells (GIS), based on a sharp change in the time of registration of reflected waves, anomalous attenuation of their amplitudes, registration of diffracted waves, or waves reflected from the plane of the ejector [I. Berson, A.M. Epinatieva, G.N. Paria, S.P. Starodubrovskaya. Dynamic characteristics of seismic waves in real environments. M .: publishing house of the USSR Academy of Sciences. - 1962. Puzyrev N.N. Interpretation of seismic data using the reflected wave method. M .: Gostoptekhizdat, 1959, p.164-165].

The disadvantage of these methods is their unsuitability for detecting low-amplitude tectonic disturbances, which are of great importance in the formation of oil and gas deposits. The maximum resolution in this case is on average> 20 m or more than the period of the seismic pulse (T).

There is a method of isolating tectonic disturbances of oil and gas productive rocks from one-dimensional spectra and correlograms of seismic traces obtained on a laser unit [Potapov OA, Shalnov BV, Kopilevich EA Isolation of tectonic disturbances by one-dimensional spectra and correlograms of seismic surveys. Exploration Geophysics. No. 58. - M .: Nedra, 1973, p.30-35].

In places of occurrence of explosive violations of rocks, incl. and low-amplitude (<20 m) clearly observed increase, and then a decrease in the prevailing frequency of the spectrum.

The disadvantages of this method are:

- obtaining and analyzing only the frequency amplitude spectrum of seismic vibrations, without a similar spectrum along the time axis, along which the seismic mapping of the tectonic disturbance occurs;

- limited dynamic range of spectral frequency analysis on a laser installation, due to the properties of the information carrier - film;

- a qualitative analysis of amplitude frequency spectra, which, especially in conditions of low-amplitude or amplitude-free tectonic disturbances, is characterized by the inevitable subjectivity of the visual description of the spectral frequency characteristics of seismic recordings;

- lack of model control according to drilling and well logging data, which can lead to unreasonable identification of the spectral features of seismic records and tectonic disturbances.

Closest to the proposed method is a method of geophysical exploration for detecting low-amplitude tectonic disturbances of oil and gas rocks (Patent for the invention No. 2191414). In this method, low-amplitude tectonic disturbances are detected on the basis of spectral-temporal analysis (SWAN) of seismic records and quantitative characteristics of the SWAN results by spectral-temporal parameters (SVP), determined by 2D seismic profiles. Anomalous in their magnitude SVPs, traced in accordance with the a priori geological model, are the spectral-temporal image (SVO) of tectonic disturbances regardless of their amplitude, including low-amplitude ones. These abnormal values of the SVP are standardized in the area of the wells where tectonic disturbances are possible due to geological reasons.

The disadvantage closest to the proposed method are:

- identification and tracking of low-amplitude tectonic disturbances along 2D seismic profiles, with the construction of structural-tectonic maps, i.e. on the plane, and not in the space of the studied geological body;

- insufficient detail, reliability of detected low-amplitude tectonic disturbances due to the relatively large distances between the profiles and the need for interpolation of the SVP;

- the use of individual SVPs without their integration, which reduces the reliability of the results.

Due to the indicated drawbacks of all the analogue methods for detecting low-amplitude tectonic disturbances, errors can be made in constructing geological models of oil and gas facilities and, as a result, non-optimal well placement, and an increase in the cost of developing the facilities.

The technical problem, which this technical solution is aimed at, is to increase the reliability and accuracy of the geological model of oil and gas facilities, which means a more reasonable laying of new exploration and production wells.

The results that are achieved by the proposed method are the isolation and tracing of low-amplitude tectonic disturbances in three-dimensional interwell space.

The method of geophysical exploration for detecting low-amplitude tectonic disturbances in three-dimensional interwell space includes seismic exploration of MOGT 3D, drilling of wells, electrical, radioactive acoustic and seismic logging, well testing, and core testing. According to drilling, well logging, well testing, laboratory core tests, water-oil (VNES), gas-water (GOC), gas-oil (GOC) contacts, the presence and possibility of the development of tectonic disturbances, including low-amplitude ones, substantiate their role in the formation of oil and gas objects and the need to determine the spatial position in the study area, as well as the possible position between the wells. According to acoustic, seismic and radioactive logging data, laboratory core tests, rigidity models are established in the wells, synthetic seismic traces are calculated along which spectral-temporal analysis (SWAN) is performed, and model reference certified spectral-temporal attributes (CBA) characterizing synthetic seismic recording are determined in areas of possible low-amplitude tectonic disturbances and beyond.

According to the MOGT 3D seismic data based on the SWAN, the experimental volumetric spectral-temporal seismic attributes (OSSA) are determined for all tracks of temporary cubes in the well area. Model and experimental reference SWAN and OSSA of the target seismic recording interval should be similar with a cross-correlation coefficient of KVK ≥0.75, which indicates a reasonable choice of reference OSA according to seismic data, drilling and geophysical surveys in wells (GIS), i.e. OSSA certification.

OSSA and CBA are the ratio of the energy of high and low frequencies, large and small times, as well as the product of the specific spectral density and weighted average and maximum frequencies and times.

Below is the mathematical theoretical justification of OSSA and IAS in integrated form and, accordingly, calculation algorithms in frequency and time scans for three-dimensional interwell space (formulas 1-8).

where - A is the current amplitude;

- A ² - the square of the current amplitude of the energy frequency spectrum of the SWAN column;

- OSSA - volumetric spectral-temporal seismic attribute;

где τ - шаг дискретизации сейсмической записи;- T ₁ and T ₂ - the initial and final time of the analyzed seismic records, i.e. cube height ΔT = T ₂ -T ₁ with the number n of current values of the amplitudes A _i equal to:

where τ is the sampling step of the seismic record;

- t _beg. and t _con. - the initial and final time interval of the spectral-time analysis Δt = t _con. -t _beginning ≥26-30 ms;

- f _beg. and f _con. - the initial and final frequencies of the energy frequency spectrum of the SWAN column at the level of 0.1 from the maximum;

- средневзвешенная частота

- Δf = f _con. -f _start ;

- weighted average frequency

f _max - the maximum frequency of the energy frequency spectrum of the SWAN column at the level of 0.7 from the maximum.

where - A ² is the square of the current amplitude of the energy time spectrum of the SWAN column;

- средневзвешенное время

-

- weighted average time

- t _max - the maximum time of the energy time spectrum of the SWAN column at the level of 0.7 from the maximum.

The selection of the CBA and OSSA described above for the detection of low-amplitude tectonic disturbances is due to the fact that within their distribution abnormal zones of physical properties of rocks are formed: densities, propagation velocities of elastic vibrations, reflection coefficients, amplitudes of reflected waves, and spectral composition of seismic pulses. Moreover, the advantage of CBA and OSSA is that if the waveform does not change, and in our case this means the absence of tectonic disturbances and related anomalous zones of physical parameters, then the expression for the complex spectrum of the time function, i.e. seismic momentum, which differs from the initial delay by a time τ, i.e. for example, the presence of flexure is exactly the same as the original.

Changing t ₁ = t-τ, we obtain S _τ (ω) = e ^-jωτ S (ω).

If we go to the modules, then we get | S _τ (ω) | = Ф _τ (ω) = Ф (ω).

In case of delay or in general when the function is shifted along the time scale, its spectrum remains unchanged. In other words, the spectrum does not depend on the choice of the initial moment for counting the times [A. Kharkevich Spectra and analysis. - M .: State. publishing house physical. literature, 1962, p.235].

It follows that, in the absence of anomalous zones of physical parameters associated with tectonic disturbances, CBA and OSSA do not depend on the time of registration of reflected waves. And when tectonic disturbances occur, NEA and OSSA do not depend on the amplitude of tectonic disturbances, which we denote by ΔH of the occurrence of the reflecting horizon and, accordingly, Δt of it on the section of the temporary cube, SVP ≠ f (ΔH, Δt).

Thus, with the help of CBA and OSSA, tectonic disturbances of any amplitude can be detected, including and low-amplitude, because with the time of registration of reflections CBA and OSSA are not related. The set of certified OSSA along the frequency and time axis quantitatively determines the anomalous zones of change in the physical properties of the medium under study, including and those that are standardized in the well area according to model and experimental data as representing tectonic disturbances.

Certified OSSA are interpreted comprehensively, which increases the reliability of identifying abnormal NWOs corresponding to low-amplitude tectonic disturbances.

Complex OSSA are obtained using modern mathematical tools - artificial neural networks (ANNs) and statistical spectral-speed algorithms. Thus, a temporary seismic cube (initial seismic information) is subjected to SWAN, according to the results of which certified OSSA are determined, their optimized complex interpretation is carried out, revealing anomalous changes in the complex attribute, i.e. spectral-temporal images of tectonic disturbances, including low-amplitude ones in three-dimensional interwell space.

This proposal allows us to identify and trace low-amplitude tectonic disturbances in the three-dimensional space of geological bodies using quantitative attributes of seismic three-dimensional information, which significantly increases the reliability and accuracy of geological models of complex oil and gas objects, the main distinguishing feature of which is the development of lateral screens - fluid supports in the form of low-amplitude tectonic violations.

New geological models provide a sharp reduction in the cost of drilling subsequent wells and, thus, increasing the efficiency of geological exploration for oil and gas.

Claims (1)

A geophysical exploration method for detecting low-amplitude tectonic disturbances in oil and gas productive rocks in a three-dimensional interwell space, including 3D seismic exploration, drilling wells and performing electric, radioactive, acoustic and seismic logging in them, testing wells and judging by the data on the presence and possibility of developing low-amplitude tectonic disturbances, characterized in that according to the combination of 3D drilling and seismic data in the area of wells They determine the definition of certified certified spectral-temporal attributes based on the spectral-temporal analysis of the target interval of seismic recording and quantitative assessment of its results in frequency and time scans in the form of the product of specific values of the spectral density of the energy frequency and time spectra by the maximum and weighted average frequencies and time, as well as the ratio of the seismic energy of high frequencies and large times to the energy of low frequencies and small times, then along all seismic paths spectral-time analysis and its quantitative parametrization along the frequency and time axis with the determination of certified volumetric spectral-temporal seismic attributes and their complex interpretation based on artificial neural networks and statistical spectral-correlation algorithms in comparison with the reference drilling data, according to the anomalous values of a three-dimensional complex attribute reveal low-amplitude tectonic disturbances at any point in three-dimensional space.