UA69205A - Method for degassing the coal beds tending to gas-dynamical effects - Google Patents

Abstract

Method for degassing coal beds tending to gas-dynamical effects is in pumping in working fluid in the mode of hydro-separation to the wells drilled according to the "cross" layout to the layer from the surface and placed in directions of the main and the supplementary crack systems; extraction of fluid from the layer and development of the well. Pumping in of the working fluid to the well is performed in sequence through one or more wells, after that the wells are closed, pumping in is performed through the central well; at the mouths of the closed wells one controls the pressure, and at increase of the pressure in one of the wells up to 0.5 - 0.7 MPa it is opened with liberation of the working fluid with coal fines, quantity of the coal fines is determined and through its volume one makes a decision about the volume of the cracks formed in the bed.

Description

Description of the invention

The invention belongs to the mining industry and can be used for early degassing, reducing the emission hazard of coal seams prone to gas dynamic phenomena, creating safe working conditions in underground conditions and for extracting methane from coal deposits.

There is a known method of regional hydraulic processing of hazardous coal seams, which consists in the preliminary determination of the length of the cleaning hole, the angle between the line of the cleaning hole and the direction of the system of natural cracks, the width of the lateral zone of the bearing pressure of the formation after its hydrodismemberment, and the value of the deviation of the axis of the wells from the design value by 70 in the process of their boring. These parameters determine the distance between the rows of wells along the design position of the bench of preparatory workings that outline the outcrop from the end sections of the bench and the distance between the wells in the row. Then they drill wells and hydrofracturing the reservoir. The magnitude of the decrease in the gas carrying capacity of formations is determined depending on their natural gas carrying capacity, the release of volatile substances and the depth of the formation (see author's certificate Mo1566045, USSR, E21E5/00, 12. E?21ET/00, publ. 05/23/90, Bull. Mo19).

The specified method allows for partial degassing and reducing the emission hazard of the marginal parts of the coal seam of the mining area. The central part of the bed remains unprocessed due to the lack of hydraulic communication between the rows of wells, and with the increase in the length of the bed and the angle between the line of the cleaning hole and the direction of the main fracture system, the unprocessed peripheral zone of the formation increases, which is the main drawback of the known technical solution.

There is a known method of cascading fluid injection into the formation, which consists of the following. From the day surface, wells are drilled into the formation, which are located according to the "cross" pattern. Then a working fluid is pumped into the well: either water or water with various additives (acids, nitrogen gas, etc.). Due to the simultaneous injection of liquid through the wells, the interaction of countercurrents is carried out, which ensures the creation of zones 29 of high pressure in the reservoir, comparable to the pressure at the wellhead, and, therefore, the saturation of poorly permeable areas (see "

Yu.S. Gurevich. Technology of extraction and use of methane in the early preparation of mine fields. - M. Moscow State University. 1988 - p. 25-29).

The specified method allows creating hydraulic failures between wells, enhancing the processing of their peripheral zones. The geometry of the filtration flow can be controlled by taking into account the natural anisotropy of 30 properties of the coal seam and the correct choice of technological influence schemes. Ha")

The main disadvantages of the known method, defined as a prototype, include: high costs due to the simultaneous operation of injection units (up to 35 pcs. 4AN-700); increased wetting of the formation and blocking of methane in the formation due to swelling of coal, roof rocks and soil of the formation; the absence of the ability to manage the movement of working fluid between wells; parameters of formation of cracks in the formation are not predicted 395 | managed; the complexity of the well development process. at

The basis of the invention is the task of creating a method of degassing coal seams prone to gas-dynamic phenomena, in which injection modes and parameters allow to activate the process of hydraulic influence for the development of a hydraulic network of cracks due to the creation of calculated parameters of crack formation in the formation "according to the main and secondary systems of cracks in any which direction between the wells, which provides Z 40 the possibility of increasing the area of surface exposure of the formation, and, as a result, intensification of degassing, reducing the terms of development of wells during methane production and reducing the stress state of the coal massif.

From" The task is solved due to the fact that in the method of degassing coal seams prone to gas-dynamic phenomena, which consists in injecting the working fluid in the mode of hydrofracturing into wells drilled according to the "cross" scheme to the seam from the surface and located in the directions of the main and secondary systems of 45 cracks, extraction of fluid from the formation and development of wells, according to the invention, injection of working fluid into the b formation is carried out alternately through one or more wells, then the wells are closed, injection (Te) is carried out through the central well, at the mouths of closed wells the pressure is monitored and when the pressure in one of the wells increases to 0.5-0.7 MPa, it is opened and the working fluid with coal fines is released, the amount of coal fines is determined and the volume of cracks formed in the formation is judged by its volume. o 20 The drawing shows the arrangement of wells for hydraulic influence on the coal seam according to the proposed method. sl The drawing shows wells MoMo 1-11, located according to the scheme "cross with respect to the main and secondary fracture systems; the grid of the main and secondary fracture systems, as well as the indicated treated zones, which have the form of an ellipse with a large radius K, located along the main fracture system and with a small radius r, located along the secondary system of cracks. c. The method is carried out as follows.

Using geological exploration data, determine the direction of the coal seam crack systems: primary and secondary. Then, on the surface, the location of the grid of wells is determined in relation to the location of the main and secondary fracture systems, and drilling is carried out according to the "cross" pattern. The mouth of each well is equipped with 60 manometers.

Based on the work experience, the distance between the wells in relation to the main system of cracks can reach ZOOm, and in relation to the secondary one - 1.4-1.5 times less.

Then the width of the crack is set and the mass of the removed coal is determined from the ratio:

Metu tok so, 0.8; bo where M is the mass of coal removed from the wells (excluding moisture), t;

And - the distance between the working and passive wells (length of the crack), m;

Y - the design amount of erosion (opening) of cracks in the formation, m; layer thickness, m; 7- density of coal, t/m3.

The coefficient (0.7-0.8) takes into account erosion of the coal seam in the near-well area.

Hydraulic pressure is carried out at the initial working pressure at the wellhead of 0.015N MPa and is gradually increased to the maximum, which can reach 0.03N MPa, where Н is the depth of the reservoir. The injection rate of the working fluid ranges from 10-15.10 m/sec in the first cycle and up to 50-70.10ZmZ/sec in the last cycle. And in each subsequent cycle, the pace increases by 10-15.10ZmZ/sec. The number of cycles and the mode of injection depends on the mining and geological conditions of the deposits, as well as the volume of the injected working fluid and can reach 4-5.

First, the wells, for example, Mo1 and Mo4, are processed. When the design indicators of hydraulic influence are reached, the wells are closed, and their mouths are equipped with manometers. Then the working fluid is pumped into the Mo2 12 |Mo3 wells, and the pressure in the Mo1 and Mo4 wells is monitored, which is recorded by manometers installed at their mouths.

The process of crack opening during hydraulic fracturing is determined by a sharp drop in the operating pressure at the wellhead, and then by its growth and gradual stabilization with an increase in the rate of injection of the working fluid.

When the set parameters of hydraulic fracturing are reached (rate, volume of pumped working fluid) or when a hydraulic connection appears between the wells in the Mo1-Mo4 group, they are closed and the reservoir is processed through the Mob well.

Injection of the working fluid into the formation through the Mob well is carried out in the mode of hydrofracturing with a gradual increase in the rate and pressure of the working fluid to a pressure of 0.3-0.5MPa at the mouth of one or more MoMo1-4 wells. After that, the well, in which the pressure has reached the specified value, is opened and the working fluid and coal fines are discharged into the sedimentation tanks. After separating the liquid from the coal fines, its mass is determined and the actual size of the cracks formed in the formation is judged by the latter.

Observations were made after hydraulic influence on the formation. It is shown that the gaping of cracks does not exceed 1 mm, and after the end of the hydraulic influence process, some cracks close, which has a negative effect on the formation gas release. Based on this, the design width of the cracks is laid from 5 to 10 cm to exclude their complete closure after removing the hydraulic load created by the working fluid. at

For the development of a network of cracks in different directions, the working fluid is re-injected, for example, into the Mo1 or Mo4 well and the increase in pressure at the mouths of the MoMoe2, 3, 5 wells is observed. When the pressure increases at the mouths of the mentioned wells, they are opened and the working fluid is released and a coal trifle. This F allows creating a network of cracks in any direction in the group of wells MoMo1-5, as well as between groups of wells MoMo1-5 and MoMob-11. After the end of hydraulic influence, the edges of the cracks under the influence of rock pressure are partially destroyed and the formation of cracks in the massif continues for a long time, during which secondary cracks parallel to the main system appear, thereby increasing the gas yield of the formation and reducing the stress state of the coal massif. "

The use of the proposed method of degassing of gas-bearing coal seams prone to gas-dynamic phenomena allows to increase the efficiency of the degassing process by controlling the modes and parameters of the working fluid injection for the development of the hydraulic system of cracks, which contribute to the increase in the area of surface exposure of the formation, to the reduction of well development terms during methane production and reducing the stress state of the coal massif. (22) se) ime) o 50 sl

R

60 b5

Primary fracture system Secondary fracture system of a coal seam of a coal seam

KK

KO

OK, here's something - and why, and what's wrong with me

Sh u i id oh Ka te ooo o fall sh i o v es: ef still ud ih '

Oh m: me

Fig 1 "

Claims (1)

The formula of the invention Io) The method of degassing of coal seams prone to gas-dynamic phenomena, which consists in injecting the working fluid in the mode of hydraulic fracturing into wells drilled according to the scheme "cross to the formation from the surface and located along the directions of the main and secondary fracture systems, extracting the fluid from the formation and development of wells, which differs in that the injection of the working fluid into the formation is carried out in turn through one or more wells, then the wells are closed, the injection is carried out through the central well, the pressure is monitored at the mouths of the closed wells, and when the pressure in one of the wells increases to 0.5-0.7 MPa, it (Se) is opened and the working fluid with coal fines is released, the amount of coal fines is determined and the volume of cracks formed in the formation is judged by its volume. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2004, M 8, 15.08.2004. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. ;" (22) se) ime) o 50 sl 60 b5