RU2251717C1 - Rocks seismic prospecting method - Google Patents

Abstract

FIELD: seismic prospecting.

SUBSTANCE: method can be used for searching non-uniformities. While conducting seismic prospecting the radiated wave receivers and transmitters are located outside inspected rock mass at two adjacent faces of tested volume of rock at the squares having radius equal or 5 times longer than wavelength in tested volume of rocks. Tested mass is a divided to cubic unit having heights of faces no longer than Ѕ wavelength of radiated wave specified by depth of testing. Rock mass is subject to radiographic test at two orthogonal directions. Radiated waves are focused into center of any cubic unit and waves at receivers are subject to co-phase summation from center of any cubic unit for any radiation of seismic waves. Energy of waves from any center is measured. Volumetric image of local diffracting object in rock mass is achieved from maximal values of energy from any center. When getting local volumetric image of object the calculations are repeated for speed values increasing subsequently depending on speed achieved during seismic well logging. Speed values at which centers of image of object coincide are assumed to be truthful and position of object received at that speed is assumed to be truthful as well. Image of object is put to coincidence from two directions for separate cross-sections. That image is assumed as truthful. Units are put together from which units the energy has maximal value at two images.

EFFECT: improved precision of determination and shape of diffracting object.

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Description

The invention relates to seismic exploration and may find application in the search for heterogeneities in the geological environment.

A known method of seismic exploration of rocks, which consists in the initiation of seismic vibrations on linear bases of grouping with the introduction of time delays, registration of seismic oscillations on linear bases of reception with the introduction of delays, time-varying, with subsequent processing and obtaining time sections (USSR copyright certificate No. 1444689, C. G 01 V 1/00, publ. 1989).

The disadvantage of this method is the need for accurate information about the deep position of the investigated object.

A known method of seismic exploration of rocks, which consists in placing sources and receivers on the Earth's surface, focused radiation and receiving seismic waves with their help and subsequent processing of the obtained data (USSR author's certificate No. 1449957, class G 01 V 1/00, publ. 1988 g.).

This method is not informative enough and does not allow to obtain a three-dimensional image of a local diffracting object in the rock mass.

Closest to the invention in technical essence is a method of seismic exploration of rocks, including the placement of sources and receivers of the emitted wave outside the studied rock mass, the division of the studied mass into cubic blocks with a face height of not more than ^1/2 _of the emitted wavelength, specified by the depth of study, focusing the emitted waves to the center of each cubic block with the in-phase summation of the waves at the receivers from the center of each cubic block for each seismic radiation waves, the determination of wave energy from each center and obtaining a three-dimensional image of a local diffracting object in the rock mass according to the maximum values of wave energy from each center (RF patent No. 2008697, CL G 01 V 1/100, publ. 04/28/94 - prototype )

The known method does not allow with sufficient accuracy to determine the location and shape of the diffracting object.

The invention solves the problem of increasing the accuracy of determining the location and shape of a diffracting object.

The problem is solved in that in the method of seismic exploration of rocks, including the placement of sources and receivers of the emitted wave outside the studied rock mass, separation of the studied mass into cubic blocks with a face height of not more than ^1/2 _of the emitted wavelength, specified by the depth of study, focusing the emitted waves to the center of each cubic block with in-phase summation of waves at the receivers from the center of each cubic block for each radiation of seismic waves, determination of wave energy t of each center and obtaining a volumetric image of a local diffracting object in the rock mass according to the maximum values of the wave energy from each center, according to the invention, the sources and receivers are located on the side of two adjacent faces of the studied rock volume in areas with a radius of 5 wavelengths; rocks are performed in two directions, when obtaining a three-dimensional image of a local diffracting object, the calculations for determining the wave energy for velocity values, successively increasing from a known underestimated value determined by seismic logging to a velocity value at which the centers of a local diffracting object coincide in two directions of transmission, this velocity value is taken for reliable, the image of the object is combined from two directions in separate sections, this image is taken for true, at the same time, blocks are left behind the object, the energy from which has a maximum value in two images.

The features of the invention are:

1. placement of sources and receivers of the emitted wave outside the studied rock mass;

2. division of the studied array into cubic blocks with a height of the faces not more than ^1/2 _{of the} length of the emitted wave, specified by the depth of the study;

3. focusing the emitted waves into the center of each cubic block with the in-phase summation of the waves at the receivers from the center of each cubic block with each radiation of seismic waves;

4. determination of wave energy from each center and obtaining a volumetric image of a local diffracting object in a rock mass from the maximum values of wave energy from each center;

5. the location of sources and receivers from the two adjacent faces of the studied volume of rocks at sites whose radius corresponds to 5 wavelengths;

6. transillumination of the volume of rocks in two directions;

7. upon receipt of a volumetric image of a local diffracting object, the calculation is repeated to determine the wave energy for velocity values that sequentially increase from a known underestimated value determined by seismic logging to a velocity value at which the centers of the local object coincide in two transmission directions;

8. Acceptance for the value of speed corresponding to reality at which the centers of the local object coincide in two directions of transmission;

9. Acceptance for the reliable position of the object obtained at this speed;

10. combining the image of the object from two directions in separate sections;

11. accepting this image as true;

12. leaving blocks behind the object, the energy from which has a maximum value in two images.

Signs 1-4 are common with the prototype, signs 5-12 are the salient features of the invention.

SUMMARY OF THE INVENTION

During seismic exploration of rocks during transillumination of the volume on one side, the location of the diffracting object cannot be determined with sufficient accuracy due to differences in the true and accepted speed of seismic wave propagation. In this case, the shape of the diffracting object is also distorted due to the small curvature of the hodograph of the scattered wave, over which summation occurs in the direction perpendicular to the direction of transmission. When the sizes of the areas of radiation and reception of seismic waves are less than a certain critical value, the radiated and received fields will not correspond to the coherent (average) field, and in this case, the results of the determination will be distorted by the inhomogeneities inside the studied rock volume. Placement of receivers and emitters in some other spatial system such as a square, rectangle, etc. leads to the appearance of directional increased sensitivity, which has a distorting effect on determining the energy of scattered waves in these directions and distorting the shape of the diffracting object.

All this reduces the accuracy of determining the location and shape of the diffracting object.

The invention solves the problem of increasing the accuracy of determining the location and shape of a diffracting object.

The method is implemented as follows.

Groups of emitters and receivers of the emitted wave are placed on the day surface outside the studied rock mass from the side of two adjacent faces of the rock volume under study at sites whose radius is not less than 5 times the wavelength, which ensures radiation and reception of a coherent (average) field . The massif under study is divided into cubic blocks with a face height of no more than ^1/2 _of the emitted wavelength specified by the depth of the study. With increasing depth of research, the wavelength is increased to compensate for the effect of rock absorption, which remains constant on the wavelength. Examination of the volume of rocks is performed in two orthogonal directions. The emitted waves are focused in the center of each cubic block with the in-phase summation of the waves at the receivers from each cubic block with each emission of seismic waves. In-phase summation is understood as summation at the time of wave entry to various receivers. The wave energy is determined by squaring the amplitude obtained after focusing and in-phase summation from each cubic block, and assign this value to the block. The area of blocks with maximum energy values forms a three-dimensional image of a local object. Enumerating the calculated values of the velocity of seismic waves during focusing and in-phase summation determines the true value of the velocity in the rock mass. The true value of speed is taken at which the centers of the image of the local object coincide in two directions of transmission. The location of the object also depends on speed. With increasing speed, the object moves away from the line “radiation-reception”, with a decrease in speed, it approaches in the opposite direction. Therefore, the true location of the object is taken to be that obtained with the true speed of seismic waves.

The images obtained with the true speed of seismic waves are compared for two transillumination directions and the shape of the object is determined. The true form is the one in which the maximum energy values are stored in both cases.

This establishes the fact of the presence of local heterogeneity, its position in the studied array and the volume occupied by it. This allows us to solve the problem of searching and contouring heterogeneity, which can be an ore body, a zone of increased fracturing in oil and gas reservoirs, etc.

Concrete example

Seismic exploration of rocks is carried out in the region of the Romashkinskoye oil field to detect and outline the zone of increased fracture in the basement rocks in order to search for possible sites of hydrocarbon accumulation. Figure 1 presents a diagram of seismic exploration. 100 sources 1 and 100 receivers 2 of the emitted wave are placed outside the studied rock mass 3 from the side of two adjacent faces 4 and 5 of the studied rock volume at sites with a radius of 650 m. The average velocity of longitudinal waves according to seismic logging data is 5200 m / s , the wavelength at a radiation frequency of 40 Hz is 130 m. The radius of the sites corresponds to 5 wavelengths. Sources 1 and receivers 2 are placed on the sites randomly without creating any correct geometric shape. Translucence volume of rocks is carried out in two orthogonal directions 6 and 7. Separate analyzed rock mass 3 into cubic blocks 8 with faces 65 m in height, which corresponds to _^1/2 wavelength of the emitted frequency of 40 Hz. The excitation of seismic waves is carried out by source 1 with a frequency of 40 Hz, which allows studies to a depth of 4 km. The emitted waves are focused in the center of each cubic block with the in-phase summation of the waves at the receivers 2 from the center of each cubic block for each seismic wave emission for a speed of 5200 m / s, obtained from seismic logging data, and which is always less than the velocity value for oblique wave propagation. The wave energy is determined by squaring the amplitude obtained after summing from each cubic block, and blocks with the maximum energy level, which are attributed to local diffracting objects, are isolated. Calculations are repeated to determine the wave energy for speeds of 5250 m / s, 5300 m / s, 5325 m / s for two directions of transmission. Figure 2 shows a vertical section in the YZ plane obtained for a speed of 5200 m / s when scanned in direction 6 and passing through the middle of the object, which shows the image of the object, constructed from the maximum values of wave energy 10. The same figure shows the contour 11 corresponding to wave energy, 15% less than the maximum value. Figure 3 shows the image of the object 10 in the same plane for a speed of 5325 m / s and the above contour. As can be seen from figure 2 and figure 3, with increasing speed, the image of the object went away in the direction of transmission 6 by 130 m. Figure 4 shows the image of object 12 in the vertical plane XZ passing through the middle of the object, when viewed in direction 7 for speed 5200 m / s. In the same figure 4 shows the contour 13, corresponding to the wave energy 15% less than the maximum value. Figure 5 shows the image of the object in the same plane for a speed of 5325 m / s and the above contour 13. As can be seen from figure 4 and figure 5, at a speed of 5325 m / s the image of the object is shifted in the direction of transmission 7 relative to the position of the object at a speed of 5200 m / s per 130 m. At a speed of 5325 m / s, the centers of the local object coincided when scanned from two directions 6 and 7. This speed value is taken as true, and the position of the object obtained for this speed is taken as reliable. Combine the images of the object obtained for this speed from two directions 6 and 7 in a horizontal section through the middle of the image of the object in the XY plane (Fig. 6, images of the object 10 and 12), and leave behind the image those blocks whose energy is maximum in two images 14. This image is taken as true.

Thus, the enumeration of velocities in calculating the energy of scattered waves made it possible to clarify the location of the local diffracting object, which turned out to be shifted in the direction of transmission 6 by 130 m (Fig. 3 and Fig. 4) and 130 m in the direction of transmission 7 (Fig. 4 and Fig. .5).

Comparison of the images of the local diffracting object for two orthogonal transmission directions in the horizontal XY plane made it possible to reduce the image length of the object along the X axis by 90 m and along the Y axis by 120 m.

Thus, more accurate guidelines for drilling an exploratory well were obtained.

Application of the proposed method will increase the accuracy of determining the location and shape of the diffracting object.

Claims (1)

A method of seismic exploration of rocks, including placing sources and receivers of the emitted wave outside the studied rock mass, dividing the studied mass into cubic blocks with a face height of no more than 1/2 of the emitted wavelength, specified by the depth of the study, focusing the emitted waves to the center of each cubic block with in-phase summation of the waves at the receivers from the center of each cubic block for each emission of seismic waves, the determination of the wave energy from each center and obtaining volumetric image of a local diffracting object in the rock mass according to the maximum values of the wave energy from each center, characterized in that the sources and receivers are located on the side of two adjacent faces of the studied volume of rocks in areas whose radius corresponds to 5 wavelengths; in two directions, upon receiving a three-dimensional image of a local diffracting object, the calculations are repeated to determine the wave energy for the velocity values, followed by To increase the speed of seismic logging, the value of the speed at which the centers of the image of the object from the two directions of transmission coincide is taken to be true, and the position of the object obtained at this speed is taken to be reliable, combine the image of the object from two directions in separate sections , this image is taken for true, while blocks are left behind the object, the energy from which has a maximum value in two images.

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