RU2219349C2 - Method to prevent gas-dynamic phenomena - Google Patents

Abstract

FIELD: mining industry, provision for safe labor conditions in coal mines. SUBSTANCE: technical result of invention lies in prevention of gas eruption due to use of deep outgassing of rock mass. With this in mind holes are drilled and dynamics of change of gas concentration in air current coming from dead face are determined. Duration of excess of measurement limit of gas concentration in air current is established in each cycle of advance of face in working. Then volume of gas eruption is found and measures to prevent next manifestations of the latter are taken. Volume of gas eruption is established by air flow rate, duration of eruption and concentration of gas which is determined in cross point of extrapolated logarithmic lines in time limits of start and finish of eruption. In this case concentration of gas exceeding 100% is taken as 100%. Measures to prevent gas eruptions are carried out by intensification of outgassing process in coal mass fore of face in working. To achieve this coal mass is subjected to active action through underground holes. Adoption of invention makes it possible to provide for safe labor conditions for miners in preparation face and in mine workings bordering on it by implementation of measures for intensification of outgassing process in coal mass by means of underground holes. EFFECT: prevented gas eruptions thanks to deep outgassing of rock mass. 4 cl, 3 dwg

Description

The invention relates to the mining industry, in particular to the coal industry, and can be used to provide safe working conditions by preventing gas-dynamic phenomena, mainly sudden gas and coal emissions in preparatory mine workings, mainly carried out using drilling and blasting operations, and also for increase the reliability of the forecast gas production workings.

The number of preparatory workings conducted using blasting in Russia is 120 - 130 per year.

Their conduct on gas-bearing and outburst-hazardous formations, both with and without undermining of lateral rocks, is accompanied at certain periods by an instant burst of gas evolution (methane, carbon dioxide and other gases), and in many cases the gas concentration in the production significantly exceeds the limit of its measurement by sensors installed in the outgoing air stream of the conducted production (for example, DMT of the "Methane" system - 2.5% of CH ₄ ). When abnormal zones meet, an excess of gas concentration can be observed in the outgoing extraction section, and even the wing. The volume of the gas surge can be 25-50% of the daily gas release, and in the zones of geological disturbances or gas-dynamic phenomena - up to 90%. The maximum concentration, for example, methane in such cases is 5-50% or more. Naturally, with the available sensors, it is not possible to directly measure the maximum concentration of methane and the released amount of it under ordinary conditions.

There is a method of preventing gas-dynamic phenomena when conducting preparatory workings, including exposure to an array from a generation by a source of pulses and current emission control, moreover, when an array is exposed to the frequency of the spectral maximum of a single source pulse, it is set equal to the resonant frequency of the natural oscillations of the array, while the acoustic signal is continuously recorded and analyzed from the operation of the source and but to a change in the amplitude-frequency characteristics of the signal give a forecast of dew hazard (RF patent for the invention No. 2131517, Е 21 F 5/00, BI No. 16, 1999).

The disadvantages of this method are that it does not allow to establish the concentration of gas in the gas surge in the mine and its volume, as well as to establish the resonant frequency of the natural oscillations of the array, since both the work and the downtime of the mountain affect the change in the frequency of natural oscillations of the array equipment, in particular combines and conveyors, as well as blasting equipment in other workings.

The closest in technical essence is a way to prevent gas-dynamic phenomena in preparatory mine workings, the sinking of which is carried out mainly with the use of blasting, including conducting wells and determining the dynamics of changes in gas concentration in the outgoing airflow from a dead end (Tomilin P.I., Ivanov B. M., Krupenya VG, et al. Study of the effectiveness of vibro-impulse treatment of bottomhole outburst coal-massif. - Industrial safety, 2000, No. 2, pp. 50-52).

The disadvantages of this method, as well as the previous one, are that it does not allow to establish the actual concentration of gas in the production during the period of the gas surge and its volume. Moreover, the radius of the effective impulse effect is small (6-11 m), for only 2-4 cycles of face movement.

The objective of the invention is to ensure safe working conditions through measures to prevent gas spikes by applying deep degassing of the array.

According to the invention, this problem is solved by the fact that in the method of preventing gas-dynamic phenomena in preparatory mine workings, predominantly carried out using blasting operations, including conducting wells and determining the dynamics of gas concentration in the air flow coming from a dead end, a duration is set in each cycle of moving the working face exceeding the permissible measurement limit by the sensor of gas concentration in the air flow, then determine the volume of the gas surge and take measures to prevent the next manifestations of the latter, the volume of the gas surge is determined by the air flow, duration of the surge and gas concentration, the actual value of which is determined at the intersection of the extrapolated logarithmic lines at the time boundaries of the beginning and end of the burst, while the concentration determined by extrapolating the intersecting logarithmic lines gas in excess of 100% is taken as 100%, and measures to prevent gas bursts are carried out by and Process intensification degassing the coal front face of the array due to generation of active impact on it through the subterranean well.

The proposed method is illustrated by drawings, in which Fig. 1 shows a diagram of changes in methane concentration in the outgoing air stream during one production cycle (for example, from 11 ⁰⁰ to 17 ⁰⁰ hours), Fig. 2 is a diagram for determining methane concentration, in Fig. 3 is a diagram of the degassing of a formation by wells.

The method is as follows.

In the process of blasting (point A in figure 1, the time is 11 ⁰⁵ hours), the methane concentration increases sharply and exceeds the limit of measuring the methane concentration by the sensor (2.5%; point B). For some time (in the particular case of 53 min - from point B to point C), there is no record of the concentration of methane burst in the diagram. At point C, the concentration record is resumed and continues until the background methane concentration is 0.2% (point D). The volume of methane within the ABCD area in this case amounted to 5925 m ³ , the volume of "background" methane - 1403 m ³ per cycle.

Methane concentration measurements were recorded using methane control equipment (AKM) and a recorder at the reception desk for telemetric information (SPTI).

The concentration of methane (methane burst above the BC line), significantly exceeding 2.5%, is determined by the lines AB and CD. Prologarithm the data on the lines AB and CD, get the experimental points lying on straight lines A'B 'and C'D' (figure 2). Approximating the dependences, they find the intersection point of the lines and their equations: for the case under consideration

lgC = 1.956 lgt-0.699 (1)

and

lgC = 3,911-2,053 lgt, (2)

where C is the concentration of methane,%;

t is the time counted from the moment of rock blasting in the face of the preparatory mine (from point A), min.

The coordinate of the point of intersection along the ordinate axis is the concentration of methane during the methane burst. In the case under consideration, the methane concentration is C = 35.48%. The actual concentration of methane in this cycle of preparatory work using blasting amounted to

C _max = C + C _f = 35.48 + 0.2 = 5.68%,

where C _f is the background concentration of methane,%.

Allow a mathematical or graphical solution to the problem.

Knowing the air flow rate, determined, for example, using a speed meter and air flow direction (WIS), the duration of the methane burst taken from the graph (see Fig. 1, the time interval between points A and D), and the concentration of methane, set the volume ( the total amount) of methane released during a given mining cycle or during, for example, a day, as well as absolute gas mobility (methane mobility) of production. In this production cycle, the volume of methane beyond 2.5% was 14,340 m ³ and the total volume was 21,668 m ³ .

The situation in the face is considered emergency if the concentration of methane in the air flow on the outgoing stream of the conducted production is more than 2.5%, i.e. the prerequisite for an accident should be considered an accident.

Measures to prevent dangerous gas phenomena in the ongoing production are carried out by intensifying the process of degassing a coal mass ahead of the face. For this purpose, either a vibroimpulse effect is applied to the coal mass through a well drilled in the soil of the seam or layer, with intensification of the gas recovery of the coal seam into the production, or wells are conducted along the axis of the conducted production both in its sides and in the direction of its face movement (see Fig. .3) for degassing the formation. Wells are carried out in sequence 1, 2 and 3 (see figure 3). On formations with high gas content through the bottomhole well 1 before drilling wells 2 and 3, a hydroimpulse effect is made on the coal mass, which allows to increase the gas yield of the formation and have cracks communicating well 1 with wells 2 and 3, which are connected to the degassing pipeline 4. Length (length) of wells is set based on the capabilities of drilling equipment (from 100 to 1000 m or more). Then, niches are formed again and wells 1 ', 2' and 3 'are drawn in the same sequence as wells 1, 2 and 3 (see Fig. 3).

The application of the method allows to prevent the manifestation of gas-dynamic phenomena, including sudden emissions of coal and gas, to increase the productivity and safety of tunneling works on the gas factor.

Claims (5)

1. A method of preventing gas-dynamic phenomena in preparatory mine workings, predominantly carried out using blasting operations, including conducting wells and determining the dynamics of changes in gas concentration in the air flow coming from a dead-end face, characterized in that, in each cycle of moving the working face, the duration of exceeding the measurement limit is established gas concentration in the air flow, then determine the volume of the gas surge and take measures to prevent the next the latest manifestation. 2. The method according to claim 1, characterized in that the volume of the gas burst is determined by the air flow rate, the duration of the burst and the gas concentration, which is determined at the intersection of the extrapolated logarithmic lines at the time boundaries of the beginning and end of the burst. 3. The method according to claim 2, characterized in that the gas concentration determined by extrapolating the intersecting logarithmic lines in excess of 100% is taken as 100%. 4. The method according to claim 1 or 2, characterized in that the measures to prevent gas bursts are carried out by intensifying the process of degassing the coal mass ahead of the bottom of the mine. 5. The method according to claim 4, characterized in that the intensification of the process of degassing the coal mass is carried out by actively acting on it through underground wells.

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