RU2616635C1 - Method of improved combustible gas recovery using underground two-phase gas-liquid variable based on phases of unworked coal fracturing in coal mine - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: fracturable well bore and water dispensing bore are constructed in a coal seam or in a permeable layer and both bores are sealed to withstand high pressure. Fracture equipment is attached and water is forced under pressure of not more than 3 MPa into the fracturable bore of 1 well, wherein water pump is turned off after 10 minutes of fracturable well bore hydraulic fracturing, thus stopping the hydraulic fracturing. Compressed air compressor for gas-phase fracturing of fracturable well bore is turned on and when the pressure reaches 3 MPa, the compressed air compressor is turned off, thus stopping the gas-phase fracturing. These operations are repeated many times, wherein when water flows from water dispensing well bore spaced from the side wall of fracturable well bore, the hydraulic fracturing is stopped, but the gas-phase fracturing is continued. When water stops flowing from the water dispensing bore or when gas blows through the water dispensing bore, the gas-phase fracturing is stopped. Then a gas discharge pipeline network is connected to the fracturable well bore and to the water dispensing bore for combustible gas recovery.

EFFECT: increased efficiency of combustible gas recovery method.

1 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a method for improving gas recovery by an underground two-phase gas-liquid variable based on phase breaking of the coal mass, and it relates to the field of controlling gas generation in underground areas in a coal mine, and mainly can be used to relieve pressure and increase permeability underground coal seam with high gas concentration and low breathability in a coal mine.

BACKGROUND

Gaseous coal seams in China are characterized, inter alia, by microporosity, low permeability and high absorption capacity, with 80% or more coal seams in China being coal seams with a high gas concentration and low air permeability. The exploitation of coal seams with a high gas concentration and low air permeability is often accompanied by the release of a large amount of gas. In particular, as the efficiency and intensity of coal mining increases and the depth of development increases, the amount of gas emitted becomes more and more, while the risk of gas explosion and sudden gas evolution becomes more and more. The main measure to solve the problem of gas emission during the development of a coal seam with a high gas concentration and low air permeability is the preliminary extraction of gas from the coal seam. Conventional gas recovery methods usually have a small effective coverage area, a high amount of bottom hole drilling, low extraction efficiency and do not allow to achieve an excellent result for a coal seam with a high gas concentration and low air permeability. In order to meet the standards for gas production and eliminate emergency situations with gas in the coal seam, it is necessary to take measures to improve permeability, in addition, it is necessary to increase the effective coverage area on each wellbore to improve the gas recovery result. Currently, widely used pressure relief and measures to increase the permeability of a coal seam with a high gas concentration and low air permeability provide artificial preliminary weakening of the initial coal mass to increase the air permeability of the coal seam, mainly by using the method of explosive loosening in deep wells, the method of waterjet cutting, the method hydraulic flushing and method of underground hydraulic fracturing of a coal seam, etc. The method of exploding in deep wells, the method of waterjet cutting and the method of hydraulic washing have their drawbacks, including a small effective coverage area of the wellbore, a large amount of work, complicated construction process, as well as low extraction efficiency, etc.

As one of the main measures to increase oil production in the modern oil industry, a method of hydraulic fracturing is widely used, and certain results have been achieved with its underground use in a coal mine. As the field of application expands, the conditions of occurrence of a coal seam become more complicated and the air permeability of a coal seam decreases, and the following main limitations of the hydraulic fracturing method appear: after water under high pressure enters a loose coal seam, it is difficult to remove water due to capillary forces in the coal mass In this connection, the gas emission channels become blocked, and the result of improved gas recovery by improving the permeability of the coal mass Willow weakens due to hydraulic fracturing.

Currently, the main attention in the study and application of underground gas fracturing in a coal mine is paid to fracturing using high-energy gas (CO ₂ , N ₂ , etc.), leading to certain results in improving the permeability for body coal. However, there are difficulties in preparing and transferring high-energy gas and in managing fracturing, holding back the widespread use of fracturing using high-energy gas.

As a result of borrowing the idea of fracturing a high-energy gas, using compressed air supplied by an underground compressed air supply system and using compressed air in combination with a hydraulic fracturing method, the present invention provides a method for improving gas recovery by an underground two-phase gas-liquid variable based on phases, rupture of the coal mass in the coal mine.

SUMMARY OF THE INVENTION

Technical problem

Due to the disadvantages of the prior art hydraulic fracturing method used for a loose coal seam with a high gas concentration and low breathability, the present invention provides a method for improving gas recovery by means of an underground two-phase gas-liquid variable based on phases, breaking the coal mass in a coal mine, which employs a method of two-phase gas-liquid variable based on phases, breaking the coal mass to improve air permeability formation, and thus, to improve the effect of gas extraction.

Technical solution

A method for improving gas recovery by means of an underground two-phase gas-liquid variable based on phases of breaking a coal mass in a coal mine, proposed in the present invention, includes the following steps:

a) construction of a wellbore as a fractured wellbore in an existing coal seam or permeable layer, construction of another wellbore having the same parameters as a water-guiding wellbore, at a distance L = 2-4 m from the wall of the fractured wellbore, installation of a fracture pipeline using conventional methods and sealing both wellbores so as to withstand high pressure,

b) connecting the fracture equipment to the mouth of the fractured wellbore, said fracturing equipment comprising a water supply device including an automatically controlled water tank and a water pump, and a compressed air compressor, the water outlet of the water supply device being connected to the air outlet of the compressed compressor air by means of a Y-shaped tee connector, wherein the outlet of the Y-shaped tee connector is connected to the burst pipe by means of a high pressure zine hose, the water outlet of the water supply device, the compressed air compressor exhaust pipe and the burst pipe inlet pipe are equipped with a non-return valve, respectively, and the high pressure rubber hose is equipped with a drain valve,

c) regulating the drain valve discharge, starting the water pump and pumping water under a pressure of not more than 3 MPa into the fractured wellbore through the fracturing pipeline to provide hydraulic fracturing of the fractured wellbore, and turning off the water pump after 10 minutes of hydraulic fracturing of the fractured wellbore with a stop in this way hydraulic fracture

d) turning on the compressed air compressor for gas-phase fracturing of the fractured wellbore and turning off the compressed air compressor when the pressure reaches 3 MPa, thus stopping the gas-phase fracture,

e) repeatedly repeating steps c) and d) and increasing each time the water pressure and air pressure by 2-3 MPa, stopping the hydraulic fracture when water flows out of the water guide barrel located at a distance from the wall of the fractured wellbore, with continued gas-phase fracture, and stopping the gas-phase rupture when the flow of water from the water guide barrel stops, or when gas breaks out of the water guide barrel,

f) closing the valve on the fracture pipeline, removing the fracture equipment, and connecting the fractured wellbore and the water-guide barrel to the gas exhaust pipe network to extract gas.

Benefits

The method proposed in the present invention uses an underground two-phase gas-liquid variable based on phases, breaking the coal mass to stimulate the development, expansion and interconnection of cracks in the coal mass, using a hydraulic gap to displace gas, and then using a gas-phase gap to displace water . Thus, in the aforementioned method, the problem of difficult gas release and analysis due to the presence of residual water using exclusively hydraulic fracture is effectively solved, thereby improving gas recovery. In addition, the method of an underground two-phase gas-liquid phase-based variable burst takes full advantage of the advantages of the two phases, while the burst pressure is gradually increased. In this regard, cracks in the coal mass develop to a fuller extent, and the effect of increasing the permeability of the coal mass is significantly enhanced. The proposed method is easy to operate and very practical in the field of its application.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 is a diagram of a method for improving gas recovery of an underground two-phase gas-liquid variable based on phases of breaking a coal mass in a coal mine by the present invention.

The drawing shows: 1 - a fractured wellbore, 2 - a water-guiding well, 3 - a tank for water with automatic control, 4 - a water pump, 5 - a compressed air compressor, 6-1 - check valve I, 6-2 - check valve II 6-3 - check valve III, 7 - Y-shaped tee connector, 8 - high-pressure rubber hose, 9 - drain valve, 10 - burst pipe, 11 - valve.

DETAILED DESCRIPTION OF THE INVENTION

An embodiment of the present invention is described in detail below with reference to the accompanying drawings.

A method for improving gas recovery by means of an underground two-phase gas-liquid variable based on phases of breaking a coal mass in a coal mine, proposed in the present invention, is as follows:

a) construct the wellbore as a fractured wellbore 1 in an existing coal seam or permeable layer, construct another wellbore having the same parameters as a water guide 2, at a distance L = 2-4 m from the wall of the fractured wellbore 1, install the fracture pipeline 10 using conventional methods and seal both boreholes so as to withstand high pressure,

b) attach the fracture equipment to the mouth of the fractured wellbore 1 and check and test the quality of the hydraulic fracture equipment and gas fracture equipment, the fracture equipment comprising a water supply device including an automatically controlled water tank 3 and a water pump 4, and a compressor 5 of compressed air, and the water outlet of the water supply device is connected to the air outlet of the compressor 5 of compressed air using a Y-shaped tee connector 7, while the outlet of the Y-shaped tee connector 7 is connected to the fracture pipe 10 by means of a high-pressure rubber hose 8, the water outlet of the water supply device is provided with a check valve I 6-1, the air outlet of the compressor 5 is equipped with a check valve II 6-2, the inlet pipe the fracture pipe 10 is provided with a check valve III 6-3 and the high pressure rubber hose 8 connected through a Y-shaped tee connector 7 to the fracture pipe 10 is provided with a drain valve 9,

c) regulate the drain valve 9 discharge, start the water pump 4 and pump water under a pressure of not more than 3 MPa into the fractured wellbore 1 in series through the check valve 6-1, Y-shaped tee connector 7, high-pressure rubber hose 8 and fracture pipe 10 for hydraulic fracturing, and after 10 minutes of hydraulic fracturing of the fractured wellbore 1, the water pump 4 is turned off, thereby stopping the hydraulic fracturing,

d) turn on the compressed air compressor 5 for the gas-phase rupture of the fractured wellbore 1, regulate the pressure with the drain valve 9 and turn off the compressed air compressor 5 when the pressure reaches 3 MPa, thus stopping the gas-phase rupture,

e) repeatedly repeat steps c) and d) and each time increase the water pressure and air pressure by 2-3 MPa, and the hydraulic fracturing is stopped when the water flows out of the water guide 2 located at a distance from the wall of the fractured wellbore 1, but the gas-phase rupture is continued, while the gas-phase rupture is stopped when the flow of water from the water guide barrel 2 stops or when gas breaks out from the water guide barrel. For example, after 10 minutes of hydraulic fracturing of a fractured wellbore at a low pressure of 3 MPa, the fracture is switched to a gas-phase fracture. When the pressure in the gas phase reaches the maximum hydraulic fracture pressure, the fracture is switched to hydraulic fracture and the water pressure is increased to 6 MPa. After 10 minutes of hydraulic fracturing, the fracture is switched to gas-phase fracture. When the pressure in the gas phase reaches the maximum hydraulic fracture pressure, the fracture is switched to hydraulic fracture and the water pressure is increased to 9 MPa. After 10 minutes of hydraulic fracturing, the fracture is switched to gas-phase fracture, and when the pressure in the gas phase reaches the maximum hydraulic fracture pressure, the fracture is switched to hydraulic fracture. The hydraulic fracture is stopped when water flows out of the water guide barrel 2, and the fracture is switched to a gas-phase fracture. The rupture work is stopped when the flow of water from the water guide stem stops,

f) close the valve 11 on the fracture pipe 10, remove the fracture equipment, and connect the fractured wellbore 1 and the water guide barrel 2 to the gas exhaust pipe network to extract gas.

Claims (7)

A method for improving gas recovery by means of an underground two-phase gas-liquid variable based on phases, breaking a coal mass in a coal mine, comprising the following steps: a) construct the wellbore as a fractured wellbore (1) in an existing coal seam or permeable layer, construct another wellbore having the same parameters as a water-guiding wellbore (2), at a distance L = 2-4 m from the fractured wall the wellbore (1), install the fracture pipe (10) using conventional methods and seal both wellbores so as to withstand high pressure; b) attach the fracture equipment to the mouth of the fractured wellbore (1), the fracture equipment comprising a water supply device including an automatically controlled water tank (3) and a water pump (4) and a compressed air compressor (5), wherein the water outlet of the water supply device is connected to the air outlet of the compressed air compressor (5) using a Y-shaped tee connector (7) and the outlet of the Y-shaped tee connector (7) is connected to the fracture pipe (10) by cutting a new high-pressure hose (8), while the water outlet of the water supply device, the air outlet of the compressed air compressor (5) and the inlet pipe of the burst pipe (10) are equipped with a non-return valve, respectively, and the rubber hose (8) of the high pressure is equipped with a drain valve (9 ); c) adjust the drain valve drain (9), start the water pump (4) and pump water under a pressure of not more than 3 MPa into the fractured wellbore (1) through the fracture pipe (10) to effect hydraulic fracturing, and turn off the water pump (4) after 10 minutes of hydraulic fracturing of the fractured wellbore (1) of the well, thus stopping the hydraulic fracturing; d) turn on the compressed air compressor (5) for gas-phase fracturing of the fractured wellbore (1) and turn off the compressed air compressor (5) when the pressure reaches 3 MPa, thus stopping the gas-phase fracture; e) repeatedly repeat steps c) and d) and each time increase the water pressure and air pressure by 2-3 MPa; hydraulic fracturing is stopped when water flows out of the water guide barrel (2) located at a distance from the wall of the fractured barrel (1) of the well, and gas-phase fracture is continued, and gas-phase fracture is stopped when the flow of water from the water guide barrel (2) stops or when gas breaks out; f) close the valve (11) on the fracture pipe (10), remove the fracture equipment, and connect the fractured wellbore (1) and the water guide barrel (2) to the gas exhaust pipe network to extract gas.

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