SU1601374A1 - Method of determining locations of seismic receivers in mine rock mass - Google Patents

Abstract

The invention relates to the mining industry and can be used to develop coal seams. The goal is to improve the accuracy of determining the place of installation of seismic receivers in the developed mountain massif by taking into account the refraction in it and the refraction of acoustic waves. Seismic receivers are installed in the mountain range and artificial acoustic signals are generated in it. The parameters of the acoustic oscillations of the sections of the rock mass are measured along the normal to the plane of the reservoir under development. The installation locations of the seismic receivers are determined by the corresponding normal coordinates, where the intensity level of acoustic oscillations of the rock mass sections takes on maximum values. The placement of seismic receivers in the zone of the maximum intensity level of each structural element of the rock mass provides the highest level of informativeness of the measured parameters of acoustic vibrations about the properties of these rock mass elements. 1 il.

Description

The invention relates to the mining industry and can be used in the development of coal seams prone to coal and gas emissions.

The purpose of the invention is to increase the accuracy of determining the installation location of seismic receivers in the mountain range being developed and thereby increase the reliability of identifying the properties of the structural elements of the mountain range being developed.

The drawing shows a scheme for determining the installation setup of seismic receivers.

The scheme contains a seismic receiver 1, bore holes 2, direct roofing 3 of the reservoir, reservoir 4, direct soil of reservoir 5, size of discharge zone 6 from generation, graph 7 of the change in the level of intensity of acoustic oscillations normal to the plane of the bedding.

The method is carried out as follows.

For each mine cluster within the framework of the guaranteed: range, industrial seismic receiver, ZUA and mine workings in the mine

The batypay massif is not closer to the discharge zone from the development of a drill and a series of silo-ipoB 2 into the reservoir, roof 3 and soil of the soil | Ta 5. The bore holes 2 are oriented in the mountain with the massif so that their slaughter sites are at one the normals to the plane are developed by iWoro reservoir 4. In all boreholes, seismic receivers 1 are installed with the same Q iBbiMH characteristics. No intensity level acoustic count (Each element of the mountain massif in the direction of rock stratification. Includes; a source of generation of an artificial acoustic signal, for example, an excavation mechanism, a jackhammer or a drilling rig. During the generation of an artificial acoustic signal) all 25 seismic detectors 1 measure the level of the intensity of acoustic oscillations. Based on the obtained values of the level of the intensity of the acoustic oscillations in each structural element of the SO, the rock mass is determined t the coordinate of the normal, at which the level of intensity of the acoustic oscillations has a maximum value. In these coordinates, the normals are established by seismic jc receivers dp, followed by a differentiated identification of the properties of the corresponding structural element of the rock mass.

Placement of seismic receivers in zone 40 of maximum intensity level

each structural element of the rock mass provides an increase in the accuracy of determining the location of the set-.

geophones in the development 45

mountain range, because in the indicated zones of the installation of seismic receivers, the highest level of informativity of the measured parameters, acoustic oscillations about

these elements of the mountain range.

Example. The reservoir M is of complex structure, consists of two packs, separated by a layer of strong sandstone with a thickness of 0.05-0.08 m. The thickness of the top is 0.03-0.10 m, the bottom is 1.35-1, 46 m. In the roof of the reservoir, shale, thin-layer, odin, dense, of medium strength lies.

fissured, with a total mobility of 11.0 m Non-uniform, roof 3.0–3.5 m thick due to shifts of thickness and the presence of sliding mirrors is unstable, prone to collapse in domes. The soil of the reservoir is sandy slate, light gray, 1.8 m thick.

To determine the location of the seismic receivers, to identify the properties of the immediate roof of the reservoir, the lower reservoir pack and the soil of the reservoir from the side walker of the reservoir Mz, three holes of 80 mm diameter were drilled into the lower reservoir pack for the production discharge area, the immediate roof. The boreholes are oriented in the mountain massif so that their faces are located beyond the discharge zone of the processing on one normal to the plane of the reservoir, which is 2.0 m away from the production. The size of the discharge zone from the generation is determined 1.5 m in advance. 40 m from the lava 10 of the eastern pillar (no closer than the zone of influence of the lava of 5 m and no further than the range of the SB-10, that is, not further than 70 m). In all the boreholes, seismic receivers are installed that are identical in their characteristics and wedge them with wooden rings. During the operation of the excavation combine in all seismic receivers, the level of the intensity of the acoustic oscillations is determined with the help of the SCT equipment. The data is tabulated.

FIG. Figure 1 shows a graph of the change in the intensity level of acoustic oscillations along the normal to the bedding layer. From the data obtained, it is determined that the frequency of the acoustic intensity is maximum at the immediate worse formation at a distance of 0.3 m from the soil of the reservoir, where m is the thickness of the reservoir, m; in the lower bundle of coal at a distance of 0.4 m from the soil of the reservoir and in the immediate top of the reservoir at a distance of 1.2 m from the soil of the reservoir np at a distance of 1.2 m from the soil of the reservoir. Therefore, in further testing of the properties of the immediate formation, the seismic detector was always placed in the immediate roof at a distance of 1.2 m from the formation soil. Further identification of the properties of the coal seam is carried out using this

the receptacle installed at the distance of 1 °, .4 m from the reservoir soil, and the identification of the properties of the direct reservoir soil - using a seismic receiver installed in the direct soil at a distance of -0.3 m from the reservoir soil.

The indicated installation sites of the seismic areas allow, throughout the mining of lava 10 of the eastern column along the seam M, to provide reliable identification of structural ones. elements of the developed mountain range. The reliability of identifying the properties of structural elements of a mountain massif was made possible by taking into account the effects of refraction and the refraction of acoustic waves in the mountain massif under development.

Claims (1)

Invention Formula The method for determining the place of installation of seismic receivers in the development O013474 mountain range, including the installation of seismic detectors in the mountain range, the generation of artificial acoustic signals into it, the measurement of acoustic oscillation parameters of the sections of the mountain array and the identification of seismic receiver locations for them to identify the properties of the developed mountain massif next to that, in order to increase the accuracy of determining the place of installation of seismic receivers in the developed mountain  5, by taking into account the refraction and refraction of acoustic waves, the parameters of acoustic oscillations of parts of the mountain massif are measured normal to the plane of the developed reservoir, and the installation sites of seismic receivers are determined by the corresponding coordinates of the normal, where the intensity level of acoustic oscillations mountain areas 25 takes on maximum values. 15 30 58 13 28 17 40 thirty 15