RU2542635C2 - Seismic prospecting method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: detonation cord blasting is used to act on the investigated geologic structure. The length of the detonation cord is set equal to the wavelength reflected from the investigated layers of the earth's crust, while blowing the cord based on the best value of dynamic resolution of observation system.

EFFECT: high information value of separating rocks with similar physical properties, having a small formation thickness and minimal differences in density values by increasing the detected useful signal.

3 cl, 3 dwg

Description

The invention relates to seismic methods of mineral exploration and can be used for a detailed study of the structure of the geological environment, for example, in the conditions of glacial fields, mainly in Antarctica.

A known method of high-resolution seismic exploration by the method of common deep point (OGT) using the explosion of charges according to the patent of the Russian Federation No. 2107310 (MKL G01V 1/00, G01V 1/13, prior. 02/06/1997), in which before the start of profile observations on the studied area determine bedding conditions of rocks of the low-velocity zone (ZMS). Then, preliminary seismic surveys are carried out to select the optimal conditions for the excitation and reception of seismic vibrations. Under the selected conditions, the main seismic surveys are carried out using the OGT method. The minimum charge mass with a high detonation speed is determined, which ensures the formation of an informational seismic signal with the minimum possible useful wavelength with an explosion sufficient to isolate useful waves against irregular interference waves by detonating single charges in wells with increasing TNT equivalent from 1 to 1000 d at the initial depth under the ZMS, equal to ⅛-¼ of the prevailing value of the apparent length of the useful wave. The seismic signal is recorded by the positional arrangement of the seismic receivers and / or accelerometers, the obtained seismograms are analyzed and the depth of the charge below the ZMS is determined, which ensures the shape stability of the informational seismic signal with the smallest possible useful wavelength and its separation against the background of irregular interference waves. The charge of a preselected mass is blown up at distances of 0.5-3.0 m from the initial depth of charge immersion in at least one well, an informational seismic signal is recorded using the positional arrangement of geophones and / or accelerometers and analyzed.

The disadvantages of this method are that it does not allow to separate rocks with similar physical properties, having low reservoir thickness and minimal differences in density values. In addition, it involves large labor costs for drilling and the use of a large number of explosive materials, and powerful explosions lead to disruption of the ecological environment.

The task is to develop a method of seismic measurements that allows you to separate rocks with similar physical properties, having low reservoir thickness and minimal differences in density values, not involving drilling operations and minimally affecting the ecology of the studied region.

The problem is solved due to the fact that in the method of seismic exploration, which includes determining the conditions of occurrence of rocks in the studied area according to the available geological and geophysical data before the start of profile observations, conducting preliminary work to select the optimal conditions for the excitation and reception of seismic vibrations and carrying out basic seismic exploration under the selected conditions works, moreover, at the stage of preliminary works, the mass of the charge is determined, which ensures the formation of an informational seismic signal during the explosion with a useful wavelength and with an intensity sufficient to isolate a useful signal against irregular noise, a detonating cord is detonated to act on the rock under study, a flank linear charge is initiated from the detonating cord, and the cord length is set equal to the wavelength reflected from the studied layers of the earth's crust , known from the available geological and geophysical data, and clarified by the best value of the dynamic resolution of the observation system.

In this case, the incident and reflected waves fall into resonance and the amplitude of the useful signal increases significantly.

It is known that the main problem affecting the resolution of the system in the case of a thin layer is that the wavelength of the signal should be comparable with the vertical size (power) of the studied layer. If the wavelength is larger than the size of the investigated object, then interference processes are observed and a phase shift occurs. If the wavelength is less than the size of the investigated object, then there are difficulties with determining the wavelength of such a wave pulse.

For best results, detonating cord is detonated in the direction of the receiving spit. The receiving spit is placed on the continuation of the direction of the cord.

If the useful signal is insufficient, the cord length, the length of which is determined as described above, is added with so many additional detonating cord segments of the same length having the same parameters (material, critical diameter, detonation velocity) at which the useful signal amplitude goes over the threshold confident detection. All segments are laid linearly on one profile. During processing, the sum of signals from all involved cords is taken as the value of the exciting signal.

Figure 1 shows the seismograms obtained at two different points (A and B). 1 - horizontal component, 2 - vertical component.

Figure 2 shows the seismogram obtained using the detonation of several cords located on the same line segment.

To implement the method, it is necessary to perform the following operations.

1. Conduct preliminary seismic surveys to select the optimal conditions for the excitation and reception of seismic vibrations. In the course of work, the length of the detonating cord is determined at which resonance arises in the rock under study. For this, the cord length should be equal to the wavelength reflected from the studied layers of the earth's crust.

In the first version of the method, the wavelength can be determined by the formula:

L = (V _eff / f),

where L is the length of the reflected wave;

V _eff is the effective propagation velocity of seismic waves in the rock under study. This speed is calculated from the traveltime curves of the reflected waves under the assumption that the medium is homogeneous and the boundary is flat;

f is the phase frequency of the useful signal obtained as a result of preliminary work using a detonating cord.

At the stage of preliminary work, the cord length at the beginning is set equal to the wavelength reflected from the studied layers of the earth's crust, known from the reference data, and then clarified by the best value of the dynamic resolution of the observation system. In all cases, the length of the cord is laid out in a straight line.

2. In the main seismic exploration, the detonating cord length is set as defined in paragraph 1. If the resolution of the system is insufficient, then choose a cord with a different critical diameter and a different detonation speed. Cord parameters can be considered defined when the resolution of the system reaches the required dynamic value.

The critical diameter of the cord remains constant throughout the measurement.

3. Select the distance between the geophones (step on the streamer). Experience shows that the best results are obtained if this distance is also set equal to the length of the reflected wave. This ensures phase correlation of the recorded waves.

4. Initiate a flank linear charge from the detonating cord.

5. Register informational seismic signals and analyze them.

For best results, detonating cord should be detonated in the direction of the receiving seismic streamer. The receiving spit should be on the continuation of the direction of the cord with an accuracy of ± 3 °. The position of the receiving spit during measurements on the studied profile should remain unchanged, while the position of the initiated lines of the detonating cord can change along the line of the worked profile. If such a mutual arrangement of the detonating cord and the receiving spit is impossible due to severe snow conditions, it is possible to arrange the cord in a direction perpendicular to the location of the spit.

If the useful signal is insufficient, add so many additional segments of the detonating cord of the same length and having the same parameters (material, critical diameter, detonation velocity) at which the amplitude of the useful signal passes the detection threshold. All cord segments are laid linearly on one profile.

During processing, the sum of signals from all involved cord lines is taken as the value of the exciting signal.

The time interval between the initiation of the detonating cord lines must be such that the background noise completely disappears.

A seismic streamer during the sequential initiation of charges from a different number of segments of a detonating cord always remains in the same place.

The thickness of the ice and the depths of the shelf part of the Weddell Sea in Antarctica were measured. For this, a two-component arrangement of geophones (Y, Z) was used. To determine the water layer under the glacier, S-waves were used, which are an indicator of the water layer under the ice.

It was known that the wavelength of transverse reflected waves in the ice shelves of Antarctica is 25-28 m depending on the salinity of the water. In our studies, by selection, the length of the detonating cord was determined to be 25 m. The charge from the detonating cord was flank, overhead. The best results were obtained when a charge detonation was initiated from the far end of the linear detonating cord with respect to the profile arrangement of seismic sensors parallel to the line of arrangement of geophones. When the cord was blown from the other end of the charge, the signal amplitude decreased by about a factor of two, which led to a distortion of the obtained material. The magnitude of the charge from the detonating cord during these works was 250 g according to the TNT equivalent. When using a detonating cord, the length of which is equal to the length of the reflected wave, in all cases a solid seismic material was obtained, while when working with explosives in shallow wells up to 2 m deep, the signal was unstable and poorly emitted at the interference level. To obtain a more stable signal, it was necessary to use wells with a depth of 5-10 m or to group small charges from wells.

The results obtained by detonating a detonating cord, the length of which is determined by selection, are presented in figure 1. It is seen that seismic signals from shear waves are clearly manifested. The speed of propagation of seismic waves on ice shelves is 3600-3650 m / s. At these speeds, all seismic waves are completely formed in the thickness of the ice shelves: refracted from the snow-ice boundary, reflected from the lower edge of the glacier, reflected from the bottom of the reservoir, reflected from sedimentary rocks. The thickness of snow on ice shelves is 25-30 m or more. The seismogram reads waves refracted at the snow-ice interface P, reflected P ₁ , exchange PS or SP, transverse S. Next, reflected bottom waves P ₂ and weak reflected waves from sedimentary formations P _OS are visible.

The seismogram of figure 2 presents seismic material for the study of glaciers in eastern Antarctica, in the region of the Russian wintering station Vostok. In the area of Art. East is a subglacial lake of the same name. The charge was composed of six lines of a detonating cord. In the time interval of 2.1-2.2 sec, a wave is observed reflected from the lower edge of the glacier. In the range of 2.9-3.0 sec, a wave is observed reflected from the bottom surface of the lake. Around a value of 3.1 sec, a weakly pronounced wave from sedimentary bottom formations is observed. In this case, the charge is sufficient to obtain a solid seismic material.

Measurements of the proposed method make it possible to obtain rock density values accurate to the third decimal place.

Such accuracy makes it possible to determine the interface between the oil and water layers both in mountainous regions under glaciers and in open spaces of ice-free shelf regions.

The propagation velocity of seismic waves in the water layer, depending on the water temperature and salinity, is 1.43-0.59 km / s (Handbook of Geophysics. M: Nedra. 1966. V.4. Page 184). Under the glaciers in Antarctica in lakes of the Vostok type, on ice and continental glaciers, the temperature on the lower edge of the glaciers can have a value in the range 0- ± 2 ° C. The seismic velocity in the water layer according to geophysical stations is 1.43 km / s. Seismic speeds in oil fields vary depending on the grade, density and temperature of each oil layer within: 1.4-1.9 km / s (ibid., P. 185). According to drilling in oil fields, the sectional water layer is always below the oil layer. In this case, it is possible by the proposed method to obtain sufficiently accurate data on the velocities in the water and oil layers. And then it is possible to determine both the depths of productive geological horizons and conduct direct searches for hydrocarbons in the sedimentary cover without drilling. In this case, charges with a mass significantly less than when exposed to the studied geological structure by conducting explosions in the wells are used, i.e., the effect of seismic work on the ecosystem of the studied region is significantly reduced.

Claims (3)

1. A method of seismic exploration, including determining the conditions of occurrence of rocks on the study area according to the available geological and geophysical data before the start of profile observations, conducting preliminary work to select the optimal conditions for the excitation and reception of seismic vibrations and carrying out basic seismic exploration under the selected conditions, and at the preliminary stage seismic surveys determine the mass of the charge, which ensures the formation of an information seismic signal with an intensity during an explosion it is sufficient to isolate the useful signal against the background of irregular interference, the registration and analysis of informational seismic signals, characterized in that detonating cord is used to influence the studied geological structure, at the stage of preliminary work, the cord length is set equal to the wavelength reflected from the studied layers of the earth crust, known from the available geological and geophysical data, and refine the best value of the dynamic resolution of the observing system. 2. The method according to claim 1, characterized in that the detonating cord is detonated in the direction of the receiving spit, the scythe is laid out to continue the direction of the cord. 3. The method according to claims 1 and 2, characterized in that to the length of the detonating cord of a specified length add so many additional segments of the cord of the same length and having the same parameters at which the amplitude of the useful signal passes the detection threshold, and the cords are laid linearly on one profile, and when processing the amount of signals from all involved segments of cords is taken as the value of the exciting signal.

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