UA12789U - Method for producing oriented three-dimensional seismic records - Google Patents

Abstract

The proposed method for producing oriented three-dimensional seismic records consists in exciting seismic vibrations on the original ground, at different point along a specified profile passing through the well, determining the parameters of the seismic vibrations by three-dimensional detectors installed with arbitrary orientation in the well, processing the obtained data by using a method of vertical seismic profiling, determining the parameters that characterize the orientation of the detectors in the well, determining the coordinates of the points of the seismic vibration excitation along the profile and the depth at which the vibrations are recorded. In the investigation process, the parameters are recorded that characterize the seismic vibrations that are excited from two points located near the well. The seismic records are processed, and the processing results are used for determining the parameters that characterize the orientation of each seismic vibration detector. The obtained data are used for the final processing the investigation results by the method of vertical seismic profiling.

Description

Description of the invention

The proposed method refers to geophysical methods of research in the well, in particular, 2 vertical seismic profiling by the polarization method or dipole three-component sounding and can be used to study the near-well environment during the search and exploration of oil and gas fields in complex seismogeological conditions.

There is a known method of obtaining three-component oriented seismic recordings, based on the registration of the wave field by an orthogonal X-, Y-, 7-system of seismic receivers, in which, in order to increase the accuracy of orientation, at the starting point of the well, a container with X-, y-, 7-seismic receivers around its vertical axis to the source of vibration excitation (direct longitudinal wave beam) until obtaining the minimum entry record of the direct longitudinal wave on the MU-component and the maximum - on the X-component, which coincides with the determined entry sign on the 7-component (11. According to the method, the value and sign of the angle of rotation of the probe at each subsequent point are determined in proportion to the value and sign of 12 of the entry of the direct longitudinal wave on the horizontal components at the previous (starting) point, from where the beginning of the countdown is transferred to the next points by the gyro stabilizer, and the electrical signals from oriented at each observation point orthogonally placed X- . of this wave, which will coincide with the specified sign of introductions on the 2-component, placed at 902 from the component with the minimum amplitude of the record.

The disadvantage of the method is the complexity of its implementation due to the lack of seismographs with the same sensitivity at an orthogonal orientation, which causes the receipt of obviously erroneous output data for the calculation of probe deflection, and uncertainty with the placement of the source of excitation of oscillations relative to the 8 well. The latter can lead to the use at different depths of signals belonging to different types of waves, as a result of which erroneous results will also be obtained.

A well-known method of conducting seismic research in individual wells is the dipole sounding model, which is focused on the study of the near-well space in the conditions of complex salt dome Ф 30 tectonics (21. The method does not provide for three-component registration of signals, which limits its possibilities and reduces its effectiveness in the geological conditions indicated above.

The method of three-component registration of seismic waves is the closest to the proposed method, which consists in recording vibrations with a three-component probe, determining the orientation of the probe in at least one receiving point, and obtaining records of the components of the wave field of the required orientation through mathematical processing

From registered data. In order to increase the accuracy and productivity of obtaining three-component records - the required orientation in curved wells, the spatial trajectory of the wellbore is determined, the probe is moved from one receiving point to another in a state pressed against the wall of the well on the cable provided by the free rotation device, and the components of the seismic records of the given orientation are determined, " using the spatial orientation of the wellbore and records at the reception point with the known orientation of the З7З probe |З). c The disadvantage of the method is determining the orientation of the probe in a limited number of well points and moving the probe between these points using an elastic clamp followed by mathematical transformation of the obtained data, which can cause significant errors, especially in the case of conducting research in unlined wells. useful model, the task of improving the method of determining the parameters of the orientation of a three-component probe in a well by calculating and optimizing the mutual placement of the excitation points on the day surface and the points of registration of oscillations in the well and connecting the data at the conjugate points of observations, which will ensure the reliability of the parameter determination, is set. can be performed both during research by the polarization method of vertical (ee) 20 seismic profiling (PM VSP) and during dipole three-component probing of wells, the research technology of which is just being developed. the proposed method of obtaining oriented three-component seismic records, which includes the excitation of oscillations on the day surface along the profile given through the well, their registration by three-component probes of arbitrary orientation, data processing in the 22nd system of the polarization method of vertical seismic profiling (PM VSP) with the current determination of probe orientation parameters in well, according to the useful model, for each interval of observations in the well, the location of the excitation point on the profile is determined under the condition xX,- H.1iidi/7 where H; - the depth of the upper boundary of the layer being studied, and - the critical angle, and the depth of the interval of registration of oscillations from each point of excitation is set within the limits of crydia2 and more! wells are drilled from two adjacent excitation points, data processing is carried out and probe orientation parameters are determined at each observation point, and to increase the reliability of the data obtained, the results of the determinations are tied at conjugate points, after which they are used for final data processing of PM VSP or dipole three-component materials because well sounding.

In comparison with the closest analogue, the method is characterized by the presence of the following distinguishing features:

- point-interval drilling of the well allows you to withstand known angles of incidence of waves on a seismic or dipole probe within the limits (from 1/2 to 1/4), which ensures a reliable determination of the orientation of the probe along a straight wave; - determination of the oscillation registration interval from each excitation point according to the expression x/Ltsi/25Н 2 /shchi/4 , where X is the coordinates of the excitation picket on the day surface, optimally aligns the placement of excitation points and vibration registration points in the well; - working out at least one setup (position) of the probe from two adjacent excitation points makes it possible to link the data of adjacent observation intervals; - determination of probe orientation parameters at each observation point and connecting them at conjugate points increases the reliability of the received data.

A set of the above-mentioned features in interaction with known features provide a technical result.

The essence of the method is explained by the drawing, where the following symbols are adopted: 1 - structure of the tower; 2 - well; C - hole punch; 4 - day surface; 5 - the first, 6 - the second, 7 - the third excitation pickets; 8 - distance of the first, 9 - second and 10 - third pickets of excitation from the well; 11 - geological environment; 12 - upper border of the first, 13 - second, 14 - third and 15 - fourth investigated layers; 16 - probe placement points in the well; 17 - conjugate observation points; 18 - an angle equal to half of the critical angle and; 19 - an angle equal to the fourth part of the critical; 20 - seismic rays.

The experience of conducting work based on the polarization method of vertical seismic profiling indicates the presence of serious problems in determining the orientation of the probe by the amplitude of the direct wave based on the data of the three-component registration of seismic oscillations. When using data from the excitation point close to the well, it is practically impossible to establish the orientation of the probe along a direct wave. When engaging distant pickets of excitation, the angle of incidence of rays within the borehole varies in a wide range of values, which is also a significant obstacle in solving a similar problem. As a result of the change in the angle of incidence of the rays, the time of registration of the direct wave and its amplitude and polarization parameters depend to a much greater extent on the physical properties of the rocks, which also leads to errors in determining the orientation of the probe.

To eliminate these shortcomings, the proposed method of obtaining oriented three-component seismic records involves the use of several drawing excitation points to determine probe orientation parameters. As can be seen from the drawing, the excitation points are placed on the profile in such a way that the angles of incidence of the rays on the well within the known registration interval are within vid/2. so (i - the value of the critical angle) to i/4. This makes it possible to determine the orientation parameters of the probe in the well with relatively small changes in the physical properties of the rocks. -

The coordinates of the excitation point on the profile are found according to the formula: p

Why -nN.shshiy? 0 -- where H; - the depth of the upper boundary of the investigated layer; i - critical angle (i - агсвипМ/Л/, here M is the speed of propagation of waves in the medium). "20 The depth of the registration interval from each excitation point is determined according to the expression: ш-в с Криаи2 жна хи ди;"

An essential point of well research is the determination of the required number of excitation points.

This is especially important for dipole seismic soundings, when studies to determine the orientation of the probe are auxiliary.

As can be seen from the drawing, to conduct research in a well with a depth of about 4 km, it is enough to set points Z and excitation. In this case, the upper-I part of the section (VCR) with a thickness of 400-500 m will remain beyond the limits of a reliable determination of the parameters of the probe's orientation. In most cases, this satisfies the solution of geological and geophysical problems in oil and gas geology. In the case of research in deeper wells, or when solving geological and geophysical problems in the upper part of the section, the number of excitation points increases according to (Che) analogy with the method described above.

Taking into account the structural factor is important when laying the direction of the excitation line. The profile should be placed along the extension of the sediments in order to minimize the influence of velocity anisotropy on the results of studies on the determination of probe orientation parameters.

The method is carried out by the following sequence of operations. c Build an average formation velocity model of the geological section along the drilled well and determine the interval within which it is necessary to conduct a study by the polarization method or by the method of dipole three-component probing. Calculate the critical angles and incidence of rays 18 on the seismic boundaries 12-15 and according to formulas (1, 2) determine the coordinates of the excitation pickets on the profile and the depth intervals examined from each excitation point, as well as the conjugate points of registration of oscillations 17.

They study the structural plan along the main seismic horizons and determine the azimuth of the profile on the diagram, provided that it must coincide with the prevailing direction of the rocks. Excitation pickets are placed on the profile according to the above calculations, after which the pickets are transferred to the area. 65 PM VSP observations are carried out from each point of excitation, and the drilling of the well starts from the far (first) picket of excitation 5. The seismic probe is moved from the hole C of the well to the upper border of the 14th deepest layer. At the same time, this interval is worked out from the rest of the designed excitation points (with the same probe positions). This makes it possible to use the data for determining the probe orientation parameters for all excitation pickets.

Work-out of the next excitation picket 6 begins with the registration of oscillations at the last point of the probe 17 station during observations at the previous excitation point. In subsequent data processing, this point (or points in the case of a multi-instrument probe) will be conjugate to excitation points 5 and 6 and will be used to correlate the data obtained from these pickets. According to a similar scheme, the design interval of the well is worked out up to the excitation picket 7 closest to the well 2. 70 Work-out of the excitation pickets not related to the determination of the parameters of the probe orientation in the well for each interval of research is carried out according to the same scheme as it was described for the deepest layer .

In the case of conducting research using the dipole three-component sounding method, appropriate excitation pickets are also used to determine the probe orientation parameters for each interval of the well.

Data processing is carried out using PM VSP technology, the orientation parameters of the probe in the well are determined at each point of its parking 16 on each excitation picket. Data connection is carried out based on the results of determinations at conjugate points.

With dipole three-component sounding of the well, the need for such a connection may not arise due to the limitation of the research interval.

In the future, the determined probe orientation parameters are used to process PM VSP data or dipole three-component probing.

An example of the implementation of the method.

The geological and geophysical efficiency of the method can be determined after conducting experimental studies on wells. Therefore, the calculations of the observation system for a well with a depth of Зб5ОМ are given here.

Output data: - wellbore depth - 365Ω; number of layers - 5; power of layers: 17th layer - 400m, 27th layer - b0Ohm, 37th layer - 1000m, 4th layer - 1600m, 57th layer - opened to 5Ohm; b research interval - 400m-ZbOOm; average formation velocity: 1st layer - 2000m/s, 27th layer - 260Ω/s, 3rd layer - 30Ω/s, 4th layer - 3500m/s, 5th layer - 400Ω/s; і - observation method - PM VSP. ch 1. Calculate the critical angles of incidence of seismic rays on the boundary that separates the layers at different speeds according to the formula: i-agswip MLM /-1 - boundary 1st layer - 2nd layer - 502; border 27 layer - ZY layer - 602; border of the 3rd layer - 4th layer - 599; « 20 border 4th layer - 5th layer - 615. from c 2. Determine the distances of the excitation points from the well according to formula (1): and Khpzz-400m.1950/2-400.0,466-186,4m 7 200m. "» Khpz"-600m-19602/2-186.4-600m.0.5774-186m-346.2-186.4m-532.6 7 550m.

Khpzi-1000m 49592/2-532.6m-1000m .0.4565-565.0-532.6-1097.61 7 100m.

Thus, the distances of the excitation points from the well are 110Ω, 55Ω and 200m. In this example, three points are enough to determine the orientation parameters of the probe within the designed interval

GF research. 3. Calculate the intervals of recording oscillations from each point of excitation according to expression (2): -I со 50 for Khpzz NI-200/0.466 g 400m;

No-200/0.221 t: 900M;

Me, for Khpzo NI-550/0.577 g 9bΩ;

No-5BO0O/0.268 t 205OM; for Khpzia Ni-1100/0.565 t 195Ω;

No-1100/0.263 from: 4180 m. with

Based on the performed calculations and taking into account the features of the layering of the environment, the following oscillation registration intervals can be established for each excitation picket: 60 Hz НИ-400m /Но-100Ω;

Khpzo No-1000m No-2000m;

Khpzi Ni - 2000 m. No-3bOOm. 4. The connecting points between the first and second intervals of registration of oscillations will have a depth of 200 Ohms, and between the second and third intervals - 100 Ohms.

The use of the calculated parameters in the process of conducting PM VSP research will allow to calculate the probe orientation parameters in the well with increased accuracy.

The obtained data can be used both independently when solving relatively simple geological and geophysical tasks, and in combination with data from other (area) excitation pickets in the case of solving more complex tasks. Especially important importance is attached to this technology during dipole three-component probing, in the process of which there is no possibility to establish the orientation of the probe.

Thus, the proposed method of obtaining oriented three-component seismic records is more advanced in comparison with existing technologies, which allows to increase the geological and geophysical efficiency of deep-hole seismic exploration in the search and exploration of oil and gas deposits in complex geological environments.

Sources of information: 1. Author. certificate of the USSR Mo824098, 501М1/40, publ. 1981 Bul. Mo15. 2. US patent Mo5537364, MKL (301M1/40, published on 16.07.1996. 3. USSR patent Mo1575744, (301M1/40, published on 30.12.1993, Bull. Mo47-48 (prototype).

Claims (1)

The formula of the invention is the method of obtaining oriented three-component seismic records, which includes the excitation of oscillations on the day surface along the profile given through the well, their registration with three-component probes of arbitrary orientation, data processing in the system of the polarization method of vertical seismic profiling (PM VSP) with the determination of the probe orientation parameters in the well , which differs in that for each observation interval in the well, the location of the excitation point on the profile is determined under the condition X, - H; ovo" 9 i/2, where Н is the depth of the upper boundary of the studied layer, and is the critical angle, and the depth of the oscillation registration interval from each point of excitation is set within X,/Ldi/2 5 Н : X, Lo and/ 4, later in the process of interval observations, at least one probe installation in the well is worked out from two adjacent excitation points, processing of seismic records is carried out and the probe orientation parameters are determined at each observation point, the results of the determinations are tied to conjugate points, after which they are used for Gezo for the final processing of PM VSP data or for the processing of materials of dipole three-component sounding of the well. with . and? - ime) -I (ee) 3e) c 60 b5