RU2761811C1 - Method for electrical tomography of a carbonaceous seam - Google Patents

Abstract

FIELD: mining industry.

SUBSTANCE: invention relates to the mining industry and, in particular, to methods for detecting geological disturbances in a carbonacious massif of potentially dangerous zones by dynamic phenomena, the forecast of emission-hazardous zones. The method includes placing the electrodes of a four-electrode installation in the workings outlining the studied area, exciting an electric field through current electrodes A and B, measuring its magnitude through measuring electrodes. Moreover, the electrodes of the feeding dipole AB are placed in one roadway entry, the electrodes of the receiving dipole MN in another roadway entry, while the electrodes A and M are placed in the roof of the formation, the electrodes B and N in the soil of the formation. The feeding and receiving dipoles are arranged in such a way that the conditional line drawn between their ends is at an angle to the direction of the roadway entry, which is the probing angle, the angle is set conditionally and retained when moving the dipoles within the extraction pillar, voltage drop on the feeding and receiving electrodes is determined in each position of the dipoles, according to which a Radon image is constructed for a given probing angle. Then these operations are repeated at different values of the probing angle to obtain other Radon images, according to which the absorption function of the electric field by the carbonaceous array is determined by the two-dimensional filtration method according to the formula

, where :

,

is the potential difference, μ is the absorption coefficient or linear attenuation coefficient, dt is the increment: the differential of the t coordinate in the ost coordinate system rotated by an angle, and using the obtained electric field absorption function, a tomographic model of the studied area is constructed, on which the areas of electric field absorption are determined, according to which the places of possible emission zones, geological disturbances are identified, the boundaries of zones and geological disturbances in the studied area are determined.

EFFECT: increase in the accuracy of determining the internal structure of the coal-bearing massif, the coal seam of the investigated area (block) in a two-dimensional coordinate system.

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Description

The invention relates to the mining industry and, in particular, to methods for detecting geological disturbances in a coal-rock massif, potentially hazardous in terms of dynamic phenomena of zones, forecasting outburst hazardous zones.

There is a known method of electrotomography of an unstable roof of coal seams (patent No. 2019698, class E 21C39 / 00, publ. 15.09.1994), in which current electrodes A and B and measuring electrodes M and N are grounded in two mine workings, an electric field is excited through the current electrodes A and B, measure its value through the measuring electrodes M and N, while all the electrodes are grounded to the low-resistance rocks of the roof, the measuring electrodes are grounded in different mine workings, the current electrode A is grounded next to the measuring electrode M, the current electrode B is grounded in the same working, in which the measuring electrode N is grounded at a distance several times greater than the distance between the measuring electrodes M and N, the electrodes are moved according to a predetermined pattern and the electric field is measured while simultaneously changing the distance between the electrodes M and N.

The disadvantage of this method is the low forecast accuracy due to large (more than 1.5 km) electrode spacing and the impossibility of determining violations and outburst zones of the coal seam, because all electrodes are grounded at the top of the coal seam.

The closest in technical essence is the method of dipole - dipole electrical profiling of a coal-bearing rock mass for predicting the heterogeneity of a coal seam (patent No. 2722172, class E 21C39 / 00, publ. 28.05.2020). According to this method, the electrodes of the four-electrode installation are placed in the workings that outline the study area, the electric field is excited through the current electrodes A and B, which is measured through the measuring electrodes, and the electrodes of the supplying dipole AB are placed in one mine, the electrodes of the receiving dipole MN are in another mine, the electrodes A and M are placed in the top of the seam, electrodes B and N are in the seam soil, the feeding and receiving dipoles are moved in the course of measurements according to a predetermined scheme, the measurement results are applied to the mining plan in the form of apparent resistivity profiles, which are used to judge the places of heterogeneity of the coal seam.

The disadvantage of this method, limiting its application, is the impossibility to determine with high accuracy the boundaries of geological disturbances or zones of non-uniformity along the vertical (Y-axis), since this method is based on obtaining a general profile of the distribution of apparent resistivity along the development, which is a vector, and the boundaries of the zones are revealed only horizontally (along the x-axis), and the vertical spread of the identified zones is simply projected. A simple projection is not enough to accurately define the boundaries of the zones vertically in the body of the extraction column.

The proposed method of electrotomography of the extraction pillar does not have the indicated drawback, and allows with high accuracy to determine the boundaries and parameters of zones of inhomogeneities, geological disturbances, potentially dangerous zones by dynamic phenomena, in a two-dimensional coordinate system.

The technical result of the proposed invention is to improve the accuracy of determining the internal structure of the coal massif, the coal seam of the investigated area (block) in a two-dimensional coordinate system.

A method is proposed for electrotomography of a coal-rock mass in order to identify geological disturbances that are potentially dangerous in terms of dynamic phenomena in the zones of a coal seam and predict outburst hazardous zones, including the placement of electrodes of a four-electrode installation in the mine workings outlining the study area, excitation of an electric field through current electrodes A and B, measurement of its value through measuring electrodes, and the electrodes of the supplying dipole AB are placed in one tunnel, the electrodes of the receiving dipole MN - in another tunnel, while the electrodes A and M are placed in the top of the seam, electrodes B and N - in the soil of the seam. To improve the accuracy of determining zones of geological disturbances, outburst zones of a coal seam and their boundaries, the supply and receiving dipoles are positioned in such a way that the conditional line drawn between their ends is at an angle to the direction of the mine, which is the angle of sounding (transmission), the angle is set conditionally and saved when the dipoles move within the extraction column, the voltage drop across the supply and receiving electrodes is determined at each position of the dipoles, according to which the Radon image is built for a given sounding (transmission) angle, then these operations are repeated at other values of the sounding (transmission) angle to obtain other images Radon, according to which the function of absorption of the electric field by a coal-rock mass is found by the method of two-dimensional filtration, using the obtained function of absorption of the electric field, a tomographic model of the investigated area is constructed, on which the areas of absorption of electric about the fields, by which the places of possible outburst zones, geological disturbances are identified, the boundaries of zones and geological disturbances in the investigated area are determined.

The essence of the invention is illustrated by the drawings Fig. 1, Fig. 2, Fig. 3. Where figure 1 shows: a diagram of the electrotomographic "transmission" of the coal mass, dotted and solid lines show the lines connecting the receiving and supplying dipoles (directions of "transmission"); 1 - coal seam; 2 - conveyor drift; 3 - supplying dipole AB; 4 - receiving dipole MN; 5 - ventilation drift; U _AB - potentials of the electric field on the supply electrodes; U _MN - potentials of the electric field at the receiving electrodes.

Figure 2 shows: the Radon image and its approximation by the Lagrange polynomial for tomographic transmission of the coal seam with rays at an angle of 45 °.

Figure 3 shows: a tomographic model of the absorption of an electric field by a coal-rock mass obtained from the absorption function μ (x, y) . With the electric transmission of a coal seam, the angle of the straight directions of transmission with the direction of the workings varied from 7.5 ° to 45 ° and from -7.5 ° to -45 °. The angle values were chosen from considerations in order to cover the entire study area. As a result, 21 Radon images r (s, φ) were obtained, from which the function μ (x, y) of the degree of absorption of the electric field was reconstructed by the method of two-dimensional filtration.

Based on the degree of signal absorption, the zone and boundaries of the geological disturbance zone were determined. The zone of intense absorption of the signal on the tomographic model, see Fig. 3, is displayed conventionally in red. According to the information provided by the geological service of the mine, where the geophysical research was carried out, during the ventilation and conveyor drifts, a disjunctive tectonic disturbance with a small amplitude of displacement was encountered, which was plotted on the mining plan. When conducting geophysical studies, the mining plan was combined with the calculated tomographic model of the electric field absorption in the coal-rock massif, where a geological disturbance was detected. The axis of displacement and the zone of influence of the geological disturbance, built up by the geological service of the mine, coincides with the region of intense absorption of the excited electric field.

Tomographic inversion is one of the ways to solve the inverse problems of electrical exploration. When examining the internal structure of the formation, it is shone through with radiation. By translucent formation from one direction, a flat (two-dimensional) shadow image of a three-dimensional body is obtained. By translucent formation from a different direction, another shadow image and additional information about its internal structure are obtained. By scanning the layer from one more direction, new information is obtained, etc. Having a large number of projection images from different directions, it is possible with a sufficient degree of accuracy to restore the internal structure of the coal seam, or rather the function of the degree of absorption of the electric field. Inside each slice, the degree of absorption μ (x, y) is considered a function of only two variables. When researching, the source-receiver system is arranged in such a way as to record only data on beams lying in the plane of the cut (in the plane of the coal seam).

Let a thin beam of radiation (in our case, an electric field) fall on a layer of matter of a coal-rock mass. It can be assumed that the absorption at a particular point does not depend on the direction of radiation. The physical law of absorption is that the increment in radiation intensity (field attenuation) Δu is proportional to the intensity of the field itself u (field potential) and the length of the segment Δt traversed by the radiation (see Fig. 1), i.e. Δu = −μ ⋅ u ⋅ Δt , where μ is the absorption coefficient of the field, which depends on the point (on the substance in the vicinity of the point) We also put a minus sign, since the field intensity decreases, i.e. the increment in intensity Δu must be negative. Passing to the limit Δ t → 0 , we obtain the absorption law in differential form:

du = -μ ⋅ u · dt. (one)

The parameter μ is called the absorption coefficient or linear attenuation coefficient. It depends on the point of the medium and does not depend on the direction of the beam; its dimension [μ] = m ^-1 . It is clear that with electrical sounding (transmission) of the seam, the attenuation coefficient is the higher, the lower the specific electrical resistivity of coal on the probe (transmission) beam and vice versa.

Let us choose the Cartesian coordinate system oxy with the center in the geometric center of the extraction column (Fig. 1) and the system ost rotated by an angle φ around the origin of coordinates. The relationship between these coordinates is determined from the expressions

x = s cos

-t sin

+ t cos

. (2) y = s sin

+ t cos

... (2)

Let the probing (transmission) be carried out along the ray s = const , while the coordinate t changes from the value t ₀ to the value t _to (Fig. 1). We divide the variables in equation (1) and integrate within these limits (we consider these limits to be infinite, since the absorption function can be considered equal to zero outside the indicated limits):

. (3)

... (3)

It is the measurement of the voltage drop across the electrodes that is a new and essential feature. Otherwise, one cannot vouch for the accuracy of determining the Radon image, and hence the boundaries of outburst hazardous zones,

where r (s, φ) is considered to be specified for directions 0≤φ <π , since when the angle changes by π, the transillumination (sounding) is carried out in the opposite direction. Integration is performed in the region where the function μ (x, y) is nonzero.

называется преобразованием или образом Радона. Решение обратной задачи, т.е. нахождение функции μ(х,y) по известным образам Радона называется обратным преобразованием Радона. Решение этой задачи возможно различными, в том числе численными методами.In practice, this means that the value of s is limited by the physical dimensions of the object. Function

is called the Radon transform or image. Solution of the inverse problem, i.e. finding the function μ (x, y) from the known Radon images is called the inverse Radon transform. The solution to this problem is possible by various methods, including numerical methods.

The essence of the invention is as follows:

1. In the investigated block containing a coal seam, in the outlining mine workings 2 and 5 (see Fig. 1), the points of placement of the feeding and receiving dipoles are outlined so that the directions of "transmission" of the seam, at a given angle between these directions and the direction of the workings, were parallel to each other (thereby ensuring the condition s = const, Fig. 1 when "translucent"). The number of such directions is determined by the need for a detailed study of the extraction column along its entire length. The indicated arrangement of the dipoles is a significant difference from the prototype.

2. The specified technical result is achieved by the fact that the electrodes A and M are grounded in the roof of the mine, the electrodes B and N are in the soil of the mine, while the dipoles of the installation move in parallel along the workings, providing the detail of the "transmission" of the coal mass.

3. According to the diagram of Fig. 1, with the help of the supply dipole AB, which is powered by the generator, an electric field is excited in the mineral layer (in our case, the coal seam) and the voltage drop (u _A - u _B ) is recorded across it, using the receiving dipole MN, to which the field receiver is connected, the potential difference of the field is measured (u _M - u _N ).

4. The Radon image is found and the obtained discrete values corresponding to the registration points are approximated by the Lagrange polynomial (see figure 2).

5. The angle between the directions of "transmission" and the direction of the workings changes; for this, the points of installation of the receiving and feeding dipoles in the workings are again marked, i.e. are established new directions of scanning (sounding) and sounding (scanning) of the coal seam with the required detail, while the second Radon image is found and approximated by the Lagrange polynomial. These operations are a significant difference between the proposed invention and the prototype.

6. Subsequently, the angle changes and everything is repeated with a new value of the angle of sounding (transmission). The accuracy of reconstructing the field absorption function depends on the number of images obtained. Thus, the accuracy of the study is increased.

7. Next, using the obtained Radon images, the absorption function of the electric field μ (x, y) by the coal-rock mass is reconstructed. By specifying the corodinates of the object under study (section) x and y for the function μ (x, y), a tomographic model of the absorption of the electric field μ (x, y) by the coal-rock mass is constructed.

8. Analyzing the tomographic model, according to the degree of absorption of the electric field, the place (places) of geological disturbances, potentially dangerous by the dynamic phenomena of the zones of the coal seam, or the outburst-hazardous zone of the coal seam in the investigated area are determined. FIG. 3 shows the location of the geological disturbance of the coal seam, found from 21 Radon images.

Claims (6)

The method of electrotomography of a coal-rock mass, including the placement of electrodes of a four-electrode installation in the mine workings outlining the study area, excitation of an electric field through current electrodes A and B, measurement of its magnitude through measuring electrodes, and the electrodes of the supplying dipole AB are placed in one mine, the electrodes of the receiving dipole MN - in another working, while electrodes A and M are placed in the top of the seam, electrodes B and N - in the soil of the seam, characterized in that the supply and receiving dipoles are positioned in such a way that the conditional line drawn between their ends is at an angle to the direction of the working, which is the sounding angle, the angle is set conditionally and is stored when the dipoles move within the extraction column, the voltage drop across the supply and receiving electrodes in each position of the dipoles is determined, along which the Radon image is constructed for a given sounding angle, then these operations are repeated at other values the sounding angle for obtaining other Radon images, according to which the function of absorption of the electric field by the coal-rock mass is determined by the method of two-dimensional filtration according to the formula

, where:

,

- potential difference, μ - absorption coefficient or linear attenuation coefficient, dt - increment - differential of the t coordinate in the ost coordinate system rotated by an angle, and, using the obtained electric field absorption function, a tomographic model of the investigated area is constructed, on which the areas of electric field absorption are determined, according to which the places of possible outburst hazardous zones, geological disturbances are identified, the boundaries of zones and geological disturbances in the investigated area are determined.

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