RU2722172C1 - Method of dipole-dipole electroprofiling of coal-bearing rock mass for prediction of sections of coal bed inhomogeneity - Google Patents

Abstract

FIELD: soil or rock drilling; mining.SUBSTANCE: invention relates to the mining industry and, in particular, to methods for forecasting mining and geological conditions of coal mining. Method of dipole-dipole electro-profiling of coal-bearing massif of rocks for prediction of areas of inhomogeneity of coal bed includes arrangement of electrodes of four-electrode installation in minings outlining section under study, excitation of electric field through current electrodes A and B, measurement of its value through measuring electrodes. At that electrodes of feeding dipole AB are arranged in one working, electrodes of receiving dipole MN - in another working, wherein electrodes A and M are placed in the formation roof, electrodes B and N - in the formation soil, feeding and receiving dipoles in the process of measurements are moved according to the specified scheme, and results of measurements are applied to mine works plan in the form of curves of apparent electrical resistance, from which points of inhomogeneity of coal bed are determined.EFFECT: technical result is determination of electrical inhomogeneities and high accuracy of prediction of areas of inhomogeneity of coal bed.1 cl, 3 dwg

Description

The invention relates to the mining industry and, in particular, to methods for predicting mining and geological conditions for coal mining.

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 measurement results, information is obtained on the location of the rock-forming layers (French Patent No. 2587408, class E21C 39/00, E21D 9/06, publ. 1987.). The disadvantages of this method are its low reliability associated with the complexity of the measurements and calculations, as well as the inability to determine the heterogeneity of the coal seam, because sounding of roof or soil rocks is carried out.

Closest to the claimed technical solution is a method of geoelectrical exploration for predicting sections of the heterogeneous roof of coal seams (Patent No. 2021506 of Russia, class E21C 39/00 (1990.01), which consists in the fact that two current electrodes A and B and measuring electrodes, excite an electric field through current electrodes A and B, measure its value through measuring electrodes while the electrodes are moved according to a predetermined pattern, current electrode A is grounded in one mine, the first measuring electrode M is grounded next to it, at a distance of 1.5-2 km the second current electrode B is grounded from them, and the second and third measuring electrodes N1 and N2 are grounded in the second mine, while all the electrodes are grounded in the low-resistance rocks of the roof, and measurements are made by changing the distances between the electrodes M, N1 and N2.

The disadvantages of this method are the low accuracy of the forecast due to the large (more than 1.5 km) spacing of the electrodes and the inability to determine the heterogeneity of the coal seam, because all electrodes are grounded in the roof of the formation.

The technical result of the invention is the determination of electrical heterogeneities and improving the accuracy of prediction of areas of heterogeneity of the coal seam.

The indicated technical result is achieved by the fact that the supplying AB and receiving MN dipoles are located in the contouring workings of the investigated section of the coal seam, the electrodes A and M are grounded in the roof of the mine, and the electrodes B and N are in the soil of the mine, while the installation dipoles move along the workings, providing a narrow zone of sounding the formation, and processing the measurement results allows us to accurately predict the position of the heterogeneity zone in the coal seam.

A method is proposed for dipole-dipole electric profiling of a coal-bearing rock mass for predicting sections of a heterogeneity of a coal seam, including placing electrodes of a four-electrode installation in decks delineating a studied area, exciting an electric field through current electrodes A and B, and measuring its magnitude through measuring electrodes while moving the electrodes at a predetermined scheme.

The difference is that the electrodes of the supply dipole AB are placed in one working area, the electrodes of the receiving dipole MN are in the other working area, while the electrodes A and M are placed in the roof of the formation, the electrodes B and N are in the soil of the formation, the supply and receiving dipoles during measurements move according to a predetermined scheme, and the measurement results are applied to the mining plan in the form of apparent electrical resistance curves, which are used to judge the places of heterogeneity of the coal seam.

The inventive method is illustrated by drawings, where in FIG. 1 shows the placement of the electrodes of the installation, FIG. 2 shows a possible measurement scheme for the studied area, the signal excitation points and the signal observation points are plotted, FIG. 3 - measurement results in the form of profiles of apparent electrical resistivity (resistivity).

In FIG. 1 shows: 1 - contouring mine workings; 2 - rocks of the roof of the coal seam; 3 - soil rocks of a coal seam; 4 - coal seam; 5 - electric current generator (G1), the supply electrodes are shown A and B; 6 - electric current receiver, microvoltmeter (R1), receiving electrodes are shown M and N. The investigated area of the coal seam is limited by mine workings 1.

In FIG. 2 shows: 1, 2 - contouring, the investigated area of the coal seam, mine workings; 3 - the investigated, contoured by the mine workings section of the coal seam; 4 - points of excitation of the electric field, marked B (1-9); 5 - points of observation of the electric field, marked H (1-12)

In FIG. 3 shows the obtained distribution profiles of apparent resistivity (Pn), constructed from the measurement results performed according to the scheme shown in FIG. 2

The invention consists in the following.

In the investigated block containing a coal seam, in the contouring mine workings 1,2, points of electric current excitation (B) and observation points (H) (measuring points of the electric current passed through the seam) are marked. The points of excitation (B) and observation (H) are selected for reasons of ensuring the path of electric current through the studied section of the reservoir. A possible measurement scheme is shown in FIG. 2. The arrangement of the electrodes of the dipole-dipole electroprofiling installation (DCEC) is shown in FIG. 1. According to the DSEC scheme, an electric current generator 4 with stabilization of the electric current is installed at the excitation point, Igen = Const. Using dipole AB (feeding electrodes), which is powered by a generator, an electric field is excited in the mineral layer, in particular in the coal seam, for this, the supply electrode A is grounded to the roof rocks, and the supply electrode B to the soil rocks of the mine formation. At the observation point, using a receiver (microvoltmeter) 5 to which a dipole MN (receiving electrodes) is connected, the voltage ΔUmn is measured, for this, the receiving electrode M is grounded in the roof rocks, and the receiving electrode N in the soil rocks of the formation. The indicated placement of the electrodes is a significant difference from the prototype, it allows you to focus the path of the electric current from the generator to the receiver, through the coal seam and the near zone along the rocks of the roof and soil, into a narrow zone, which allows with high accuracy to determine the heterogeneity of the coal seam, as well as roof disturbances and coal seam soil.

The indicated technical result is achieved in that the supplying AB and receiving MN dipoles are located in the contouring workings (1, 2) of the investigated section of the coal seam (3) of FIG. 2. According to the diagram of the dipole-dipole setup shown in FIG. 1. Electrodes A and M are grounded in the roof of the mine, and electrodes B and N in the mine soil, while the dipoles of the installation move along the mine, providing a narrow zone for sensing the formation. For each excitation point Bn (4) of FIG. 2, n measurements are taken at the observation points Hn (5) of FIG. 2. The number of measurements for each point of excitation, is selected for reasons of detail study of the studied area. It is necessary to perform repeated measurements at the observation points during excitation of the electric field from adjacent excitation points, the measurements are schematically shown in FIG. 2. Next, the apparent resistivity ρ _{k is} calculated for each position of the generator and receiving dipoles according to formula (1). The values obtained are profiles of the apparent electrical resistivity (resistivity) of the area of the coal seam under study. To obtain the overall profile of the apparent resistivity of the reservoir, the obtained profiles of the reservoir region are plotted on a common graph, an example is presented in Fig-3. Mentally, graphically or using specialized software, they form a common contour, which is obtained from superimposing individual profiles on a common graph in a single coordinate system. Thus, the resulting contour is a common distribution profile of apparent resistivity in the studied coal seam. By analyzing the obtained profile of the resistivity distribution, zones with increased or decreased resistivity values are distinguished. These zones in the coal seam are anomalies, and are confined to structural or geological disturbances. In Fig. 3., a zone of reduced resistivity (15-30 pickets P) is highlighted, this zone is confined to two explosive low-amplitude geological disturbances and was confirmed by the geological service of the mine. Also, zones of reduced resistivity at pickets 47-48 and 57-58 were identified; in these areas, during mining of the extraction block, erosion of the coal seam with partial replacement by sedimentary rocks was revealed.

where: ρ _to - specific apparent electrical resistance; ΔU is the potential difference measured at the observation point; I is the excitation current; To _p - correction factor for the applied measurement scheme To _p = 1,03; To _g is the geometric coefficient of installation.

where L _AM , L _BM , L _AN , L _BN is the distance between the electrodes of the installation.

Claims (1)

A method of dipole-dipole electroprofiling of a coal-bearing rock mass for predicting sections of a heterogeneity of a coal seam, including placing electrodes of a four-electrode installation in decks delineating a studied area, exciting an electric field through current electrodes A and B, measuring its magnitude through measuring electrodes, while the electrodes are moved at a predetermined a circuit, characterized in that the electrodes of the supply dipole AB are placed in one development, the electrodes of the receiving dipole MN in the other generation, 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 supply and receiving dipoles in the process measurements are moved according to a given scheme, and the measurement results are applied to the mining plan in the form of apparent electrical resistance curves, which are used to judge the places of heterogeneity of the coal seam.

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