RU2021507C1 - Method for geoelectric prospecting for prognosis of state of sections of inhomogeneous roof of coal seams - Google Patents

Abstract

FIELD: geoelectric prospecting. SUBSTANCE: grounded in two mine workings are current-carrying electrodes A and B and measuring electrodes M and N. Electrodes M and N are located in one working. Electric field is excited through current-carrying electrodes A and B, and its value is measured with the aid of electrodes M and N. In so doing, electrodes are moved in compliance with preset scheme. Electrode A is grounded in one mine working, and electrode B in some other, and electric field is measured by varying distance between electrodes A and B by their displacement. All current-carrying electrodes B are grounded in low resistance rocks of roof. EFFECT: higher efficiency. 13 dwg

Description

 The invention relates to methods for predicting the mining and geological conditions of coal mining and can be used if there are opportunities for grounding the electrodes on different sides of the investigated object.

 A known method for predicting the strength of carbon-bearing rocks, based on measuring the apparent electrical resistance of the rock and determining subsequent calculations based on measurements of the strength parameters of the roof [1]. The disadvantages of this method are its low reliability associated with the complexity of measurements and calculations, as well as low reliability.

 A known method for determining the state of a rock massif is that electromagnetic pulses are sent from a special transceiver to the rock massif and receive pulses reflected by the interface between layers of rocks with different electrical properties. After processing the pulses, information is obtained on the location of the rock-forming layers [2]. The disadvantages of this method are the low reliability and accuracy in determining the specific location of the heterogeneity.

 The closest in technical essence is a method for identifying areas of unstable roof (represented, for example, clay slate) by electrometric method [3]. In this method, an electric current is supplied to the rock mass by a generator through current electrodes A and B, and using the electrodes M and N, potential differences are measured. In this case, electrodes A and B are grounded with a distance of 300-500 m between them (electrode spacing) in one mine, and electrodes M and N in another mine. With a constant distance between the dipoles AB and MN, the entire installation moves with a certain step along the object of study. Earthing of all electrodes is made into the coal seam. The disadvantages of this method are the low accuracy and reliability of forecasting, since there is no detailed description of the distribution of rock properties in the zones of unstable roofing of coal seams.

 The reasons for these shortcomings are as follows.

 1. Based on the analysis of an incomplete data bank in the known method, it is argued that the intensity of the anomalous curves (Fig. 1C) obtained at various spacings, it is possible to judge the depth of inclusion.

 This statement is not true, which is convincingly proved by physical modeling in an electrolytic bath [4], the results of which have been repeatedly tested in practice and taken as a basis [5,6]. Several methods were simulated, including the method of symmetric electrical profiling (hereinafter SES, analogue sensing in the last mentioned method, Fig. 1b), as well as four-electrode sequential electrical illumination (hereinafter, “ChEP-P”, Fig. 1a). So, when changing the value of P / AB, where P is the size of the inclusion, and AB is the distance between the electrodes A and B, the intensity on the BEC graphs increases only to P / AB = 1 (Fig. 2), then for all P / AB> 1 remaining constant. In FIG. 2-7 are summary graphs of physical modeling [4]. The intensity of the curves is much stronger depending on the distance to the measurement profile Z, the distance from the measurement profile vertically up and down Y, and the angle between the boundary of the inhomogeneity and the measurement profile b.

 When P / AB changes in the CHEP-P method (Fig. 3), the intensity of the curves changes in very small limits. Much stronger - when changing Z and Y (which was changed in the ratio of them with the distances AB and MN, as well as with the distance between the models of mine workings Lб).

 The greatest influence on the intensity of the curves is exerted by the ratio of electrical resistances of the sought-after local inclusions (zones of unstable roofing of coal seams) and rock mass [4]. But this known existing method does not take into account.

 2. In the known method, it is argued that the distance between the maxima of L on the curve can determine the depth of the heterogeneity.

 The simulation results show that the parameter L / P at P = AB on the curves of the ChEP-P method (Fig. 4) varies only from 0 to P / AB = 1, while at P / AB> 1 it remains constant. For the SES curves (Fig. 5), the L / P parameter changes at P = (0 ... 0.25) AB, while at P / AB> 0.25 it remains constant.

 The L / P parameter for the BOT plots, like the BEP-P, is most affected by the Z, Y, and b parameters, which are not taken into account in the known method.

 3. It is known that the regularity of the sedimentation cycle during the period of coal formation is almost always maintained [7]. The coal seam 1 (Fig. 6) most often lies among clay shales 2 (sand-clay shales), then sand and sandstone shales follow the section. The electrical resistance Rk of coals is greater than that of shales and of the same order as sandstones. Therefore, when grounding the electrodes in a coal seam, information is obtained not only from the roof of the coal seam, but also from its soil inversely to the ratio of their electrical resistances.

 In FIG. Figure 7 shows the distribution of lines of equal information (obtained from the results of physical modeling) around the mine workings 1 when exploring the space using the BEP and ChEP-P methods under the conditions of the same electrical resistance of the roof and soil rocks of the coal seam when the electrodes are grounded in the coal seam 2. If the BEP method isolates are grouped around a mine working, then at CHEP-P - between the mining, in either case, bringing information far from the soil and the roof of the coal seam. Therefore, to study an unstable roof, electrodes should be grounded only in the roof rocks, which, due to their lower electrical resistance, will localize the electric field. When grounding all the electrodes in the clay shale 2 of the roof (Fig. 8), the presence of sandstone 3 and the coal seam 1 with high electrical resistance creates favorable conditions for the necessary measurements. About 90% of the information comes only from this space, which is well traced along the lines of equal information.

 4. In the known method, the appearance of the theoretical profile curve of even a clean (ananomalous) field (for example, a roof without zones of rock weakening) is rather complicated [5], since it is the result of a superposition of the fields of the grounded electrodes A and B (Fig. 9), where G is generator, And - meter). In this case, the interpretation of the research materials is carried out without taking into account the theoretical field distribution curves (as the example shows), which immediately casts doubt on the possible effectiveness of the studies in a known manner, since in FIG. Figure 9 shows that the values of electrical resistance vary widely, generally expressed in a complex graph: the maximum values are against the middle of AB, the smallest are against the parking place of electrodes A and B. The rest of the field is also not linear.

 5. In the known method, the boundary lines of the zones of the unstable roof are drawn without using the mathematical apparatus, almost intuitively (a priori), as evidenced by the smooth forms of the borders (Fig. 10 and 11, copied from [3]).

 The aim of the invention is to improve the accuracy and reliability of forecasting by providing a detailed description of the distribution of rock properties in areas of an inhomogeneous roof of coal seams.

 This is achieved by the fact that in the method of geoelectrotomography of the inhomogeneities of the roof of coal seams in one mine, the current electrodes A and B are grounded, in the other mine the measuring electrodes M and N are grounded, the electric field is excited through the current electrodes A and B, it is measured through the measuring electrodes M and N, moving all the electrodes according to a given scheme, while all the electrodes are grounded not in the coal seam, but in the low-impedance rocks of the roof. The first current electrode A is earthed in one mine, the second current electrode B is in the second mine, along which it is moved while maintaining a constant grounding location of electrode A, i.e., the electric field is measured while changing the distances between electrodes A and B at help movements of the electrode B.

 When conducting a patent search, no technical solutions were found in which the combination of essential features would coincide with the combination of features of the proposed method, which indicates the compliance of the latter with the criterion of "novelty."

 In the study of patent and scientific and technical literature, no technical solutions were found that would contain signs corresponding to the distinguishing features of the proposed method with the manifestation of the same properties to achieve the purpose of the invention. This allows us to conclude that the invention meets the criterion of "significant differences".

 In FIG. 12 shows an example implementation of the proposed method; in FIG. 13 is an illustration of the result.

 To create a uniformly distributed electric field in the object of research, the current electrode A is located at point 1 on one mine, and the other current electrode B is located at another mine at point 2. There are no measuring electrodes M and N, since the meter is connected to current electrodes. The potential difference between the electrodes A and B is measured at many points by transferring the electrodes to different points in space (unstable roof). The distance between the electrodes A and B varies.

In the proposed method, current flows between the electrodes A and B through an unstable roof, which is a volume conductor. The Maxwell equation for a constant field with intensity E (8) looks like this
rotE = Φ. (1) Then
E = -gradU, (2) where U is the electric potential.

Taking into account that Ohm's law in differential form relates the current density j and electrical conductivity r to the dependence j = rE, we can write
j = -r gradU (3) After integration, equations (3) get
U = U = ∫ S dl Sdl, (4) where U is the potential difference at the electrodes A and B;
S - electrical parameter, equivalent to apparent electrical conductivity, equal to S = j / r;
l is the distance between the electrodes A and B.

 The solution of equation (4) gives a detailed description of the distribution of the informative electric parameter S.

 As the most effective method for mapping large areas with a high degree of detail and high productivity on unstable rock mass sections, the proposed method is practically implemented when mapping a false (unstable) roof on the excavation panel 19 of the western lava at mine 7/8 Khrustalskaya of the Production Association coal mining Donbassantratsit.

 The geological service of the mine has the task: to determine the geological disturbance of the coal seam, including its tectonic disturbance.

 The direct roof of the coal seam is a sand shale rock with a thickness of 0.6 m, sometimes up to 1.5 - 2 mm or more. The electrical resistance of the roof rocks is slightly less than the resistance of the coal seam. In places of tectonic disturbances, the direct roof, like the coal seam, manifests itself as zones of increased fracture, in which the electrical resistance is significantly increased.

 For conducting studies on the contours of the investigated array of opposite mine workings, the grounding areas of the electrodes were prepared. In this case, electrode A is grounded at the 17th western conveyor drift, and measuring electrode B is grounded at the 19th western drift (Fig. 12). On the 17th drift, electrode A is fixed, and with the help of electrode B, measurements are made for 19 app. drift. When performing a certain number of measurements, electrode A moves to the next point and measurements with electrode B are repeated.

 All electrodes are grounded to the roof.

 After processing the computer research materials, the result shown in FIG. 13. It can be seen that several tectonic zones stand out on the plan of the entire extraction panel. So, in the upper part of the panel, attenuation of a large fold is visible. An anomaly in the left side is caused by minor disturbances. All these violations are especially well visible on the axonometry of the studied object. It should be noted that the constant map of the electrical resistance of the immediate roof is reasonably well linked with the data along the mine workings, which indicates the high quality of the work performed.

 Known methods do not provide mapping of tectonic disturbance of the roof of the coal seam over the entire area of the extraction column with such a degree of detail. Therefore, it is recommended that the proposed method be used as widely as possible for solving the problems of forecasting the heterogeneity of the roof of coal seams.

Claims (1)

 METHOD OF GEOELECTRIC EXPLORATION FOR FORECASTING OF PLANTS OF HETEROGENEOUS BLOOD OF COAL PLASES, in which the current electrodes A and B and the measuring electrodes M and N are located in two mine workings, while the measuring electrodes M and N are located in the same mine working, they excite the electric field A and B, measure its value through the measuring electrodes M and N, while the electrodes are moved in accordance with a predetermined circuit, characterized in that, in order to improve the accuracy and reliability of forecasting heterogeneity these roofs by providing a detailed description of the distribution of the electrical properties of the rocks, all electrodes are grounded in low-resistance rock of the roof, and current electrode A is grounded in one mine, current electrode B is grounded in another mine, and the electric field is measured by changing the distance between current electrodes A and B by moving the current electrode B.

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